METHODS AND COMPOSITIONS FOR WEED CONTROL

FIELD

The methods and compositions generally relate to the field of weed management. More specifically, related to phytoene desaturase (PDS) genes in plants and compositions containing polynucleotide molecules for modulating their expression. Further provided are methods and compositions useful for weed control.

BACKGROUND

Weeds are plants that compete with cultivated plants in an agronomic environment and cost farmers billions of dollars annually in crop losses and the expense of efforts to keep weeds under control. Weeds also serve as hosts for crop diseases and insect pests. The losses caused by weeds in agricultural production environments include decreases in crop yield, reduced crop quality, increased irrigation costs, increased harvesting costs, reduced land value, injury to livestock, and crop damage from insects and diseases harbored by the weeds. The principal means by which weeds cause these effects are: 1) competing with crop plants for water, nutrients, sunlight and other essentials for growth and development, 2) production of toxic or irritant chemicals that cause human or animal health problem, 3) production of immense quantities of seed or vegetative reproductive parts or both that contaminate agricultural products and perpetuate the species in agricultural lands, and 4) production on agricultural and nonagricultural lands of vast amounts of vegetation that must be disposed of. Herbicide tolerant weeds are a problem with nearly all herbicides in use, there is a need to effectively manage these weeds. There are over 365 weed biotypes currently identified as being herbicide resistant to one or more herbicides by the Herbicide Resistance Action Committee (HRAC), the North American Herbicide Resistance Action Committee (NAHRAC), and the Weed Science Society of America (WSSA).

The phytoene desaturase (PDS) enzyme is an essential enzyme in the carotenoid biosysnthesis pathway. This enzyme is the target of herbicides that include Pyridazinones, Pyridinecarboxamides, beflubutamid, fluridone, fluorochloridone and flurtamone.

BRIEF DESCRIPTION OF THE FIGURES

The following drawings form part of the present specification and are included to further demonstrate certain aspects of the present invention. The invention may be better understood by reference to one or more of these drawings in combination with the detailed description of specific embodiments presented herein. The invention can be more fully understood from the following description of the figures:

FIG. 1. Treatment of Amaranthus palmeri with ssDNA trigger polynucleotides and PDS inhibitor herbicide, norflurazon.

FIG. 2. Dandelion and Prickly lettuce treated with PDS ssDNA oligonucleotides

SUMMARY

In one aspect, the invention provides a method of plant control comprising an external application to a plant of a composition comprising a polynucleotide and a transfer agent, wherein the polynucleotide is essentially identical or essentially complementary to a PDS gene sequence or fragment thereof, or to the RNA transcript of said PDS gene sequence or fragment thereof, wherein said PDS gene sequence is selected from the group consisting of SEQ ID NO:1-78 and 2138 or a polynucleotide fragment thereof, whereby the plant growth or development or reproductive ability is reduced or the plant is made more sensitive to a PDS inhibitor herbicide relative to a plant not treated with said composition. In this manner, plants that have become resistant to the application of PDS containing herbicides may be made more susceptible to the herbicidal effects of a PDS inhibitor containing herbicide, thus potentiating the effect of the herbicide. The polynucleotide fragment is at least 18 contiguous nucleotides, at least 19 contiguous nucleotides, at least 20 contiguous nucleotides or at least 21 contiguous nucleotides in length and at least 85 percent identical to a PDS gene sequence selected from the group consisting of SEQ ID NO:1-78 and 2138 and the transfer agent is an organosilicone composition or compound. The polynucleotide fragment can also be sense or anti-sense ssDNA or ssRNA, dsRNA, or dsDNA, or dsDNA/RNA hybrids. The composition can include more than one polynucleotide fragments, and the composition can include a PDS inhibitor herbicide and/or other herbicides (co-herbicides) that enhance the plant control activity of the composition.

In another aspect, polynucleotide molecules and methods for modulating PDS gene expression in plant species are provided. The method reduces, represses or otherwise delays expression of a PDS gene in a plant comprising an external application to such plant of a composition comprising a polynucleotide and a transfer agent, wherein the polynucleotide is essentially identical or essentially complementary to a PDS gene sequence or fragment thereof, or to the RNA transcript of the PDS gene sequence or fragment thereof, wherein the PDS gene sequence is selected from the group consisting of SEQ ID NO:1-78 and 2138 or a polynucleotide fragment thereof. The polynucleotide fragment is at least 18 contiguous nucleotides, at least 19 contiguous nucleotides, at least 20 contiguous nucleotides at least 21 contiguous nucleotides in length and at least 85 percent identical to a PDS gene sequence selected from the group consisting of SEQ ID NO:1-78 and 2138 and the transfer agent is an organosilicone compound. The polynucleotide fragment can also be sense or anti-sense ssDNA or ssRNA, dsRNA, or dsDNA, or dsDNA/RNA hybrids. Polynucleotide molecules comprising SEQ ID NOs 79-2010 are fragments of the PDS gene.

In a further aspect, the polynucleotide molecule containing composition may be combined with other herbicidal (co-herbicides) compounds to provide additional control of unwanted plants in a field of cultivated plants.

In a further aspect, the polynucleotide molecule composition may be combined with any one or more additional agricultural chemicals, such as, insecticides, fungicides, nematocides, bactericides, acaricides, growth regulators, chemosterilants, semiochemicals, repellents, attractants, pheromones, feeding stimulants, biopesticides, microbial pesticides or other biologically active compounds to form a multi-component pesticide giving an even broader spectrum of agricultural protection.

DETAILED DESCRIPTION

Provided are methods and compositions containing a polynucleotide that provide for regulation, repression or delay of PDS (phytoene desaturase) gene expression and enhanced control of weedy plant species and importantly PDS inhibitor resistant weed biotypes. Aspects of the method can be applied to manage various weedy plants in agronomic and other cultivated environments.

The following definitions and methods are provided to better define the present invention and to guide those of ordinary skill in the art in the practice of the present invention. Unless otherwise noted, terms are to be understood according to conventional usage by those of ordinary skill in the relevant art. Where a term is provided in the singular, the inventors also contemplate aspects of the invention described by the plural of that term.

By “non-transcribable” polynucleotides is meant that the polynucleotides do not comprise a complete polymerase II transcription unit. As used herein “solution” refers to homogeneous mixtures and non-homogeneous mixtures such as suspensions, colloids, micelles, and emulsions.

Weedy plants are plants that compete with cultivated plants, those of particular importance include, but are not limited to important invasive and noxious weeds and herbicide resistant biotypes in crop production, such as, Amaranthus species—A. albus, A. blitoides, A. hybridus, A. palmeri, A. powellii, A. retroflexus, A. spinosus, A. tuberculatus, and A. viridis; Ambrosia species—A. trifida, A. artemisifolia; Lolium species—L. multiflorum, L. rigidium, L perenne; Digitaria species—D. insularis; Euphorbia species—E. heterophylla; Kochia species—K. scoparia; Sorghum species—S. halepense; Conyza species—C. bonariensis, C. canadensis, C. sumatrensis; Chloris species—C. truncate; Echinochola species—E. colona, E. crus-galli; Eleusine species—E. indica; Poa species—P. annua; Plantago species—P. lanceolata; Avena species—A. fatua; Chenopodium species—C. album; Setaria species—S. viridis, Abutilon theophrasti, Ipomoea species, Sesbania, species, Cassia species, Sida species, Brachiaria, species and Solanum species.

Additional weedy plant species found in cultivated areas include Alopecurus myosuroides, Avena sterilis, Avena sterilis ludoviciana, Brachiaria plantaginea, Bromus diandrus, Bromus rigidus, Cynosurus echinatus, Digitaria ciliaris, Digitaria ischaemum, Digitaria sanguinalis, Echinochloa oryzicola, Echinochloa phyllopogon, Eriochloa punctata, Hordeum glaucum, Hordeum leporinum, Ischaemum rugosum, Leptochloa chinensis, Lolium persicum, Phalaris minor, Phalaris paradoxa, Rottboellia exalta, Setaria faberi, Setaria viridis var, robusta-alba schreiber, Setaria viridis var, robusta-purpurea, Snowdenia polystachea, Sorghum sudanese, Alisma plantago-aquatica, Amaranthus lividus, Amaranthus quitensis, Ammania auriculata, Ammania coccinea, Anthemis cotula, Apera spica-venti, Bacopa rotundifolia, Bidens pilosa, Bidens subalternans, Brassica tournefortii, Bromus tectorum, Camelina microcarpa, Chrysanthemum coronarium, Cuscuta campestris, Cyperus difformis, Damasonium minus, Descurainia sophia, Diplotaxis tenuifolia, Echium plantagineum, Elatine triandra var, pedicellate, Euphorbia heterophylla, Fallopia convolvulus, Fimbristylis miliacea, Galeopsis tetrahit, Galium spurium, Helianthus annuus, Iva xanthifolia, Ixophorus unisetus, Ipomoea indica, Ipomoea purpurea, Ipomoea sepiaria, Ipomoea aquatic, Ipomoea triloba, Lactuca serriola, Limnocharis flava, Limnophila erecta, Limnophila sessiliflora, Lindernia dubia, Lindernia dubia var, major, Lindernia micrantha, Lindernia procumbens, Mesembryanthemum crystallinum, Monochoria korsakowii, Monochoria vaginalis, Neslia paniculata, Papaver rhoeas, Parthenium hysterophorus, Pentzia suffruticosa, Phalaris minor, Raphanus raphanistrum, Raphanus sativus, Rapistrum rugosum, Rotala indica var, uliginosa, Sagittaria guyanensis, Sagittaria montevidensis, Sagittaria pygmaea, Salsola iberica, Scirpus juncoides var, ohwianus, Scirpus mucronatus, Setaria lutescens, Sida spinosa, Sinapis arvensis, Sisymbrium orientale, Sisymbrium thellungii, Solanum ptycanthum, Sonchus aspen, Sonchus oleraceus, Sorghum bicolor, Stellaria media, Thlaspi arvense, Xanthium strumarium, Arctotheca calendula, Conyza sumatrensis, Crassocephalum crepidiodes, Cuphea carthagenenis, Epilobium adenocaulon, Erigeron philadelphicus, Landoltia punctata, Lepidium virginicum, Monochoria korsakowii, Solanum americanum, Solanum nigrum, Vulpia bromoides, Youngia japonica, Hydrilla verticillata, Carduus nutans, Carduus pycnocephalus, Centaurea solstitialis, Cirsium arvense, Commelina diffusa, Convolvulus arvensis, Daucus carota, Digitaria ischaemum, Echinochloa crus-pavonis, Fimbristylis miliacea, Galeopsis tetrahit, Galium spurium, Limnophila erecta, Matricaria perforate, Papaver rhoeas, Ranunculus acris, Soliva sessilis, Sphenoclea zeylanica, Stellaria media, Nassella trichotoma, Stipa neesiana, Agrostis stolonifera, Polygonum aviculare, Alopecurus japonicus, Beckmannia syzigachne, Bromus tectorum, Chloris inflate, Echinochloa erecta, Portulaca oleracea, and Senecio vulgaris. It is believed that all plants contain a phytoene desaturase gene in their genome, the sequence of which can be isolated and polynucleotides made according to the methods of the present invention that are useful for regulation, suppressing or delaying the expression of the target PDS gene in the plants and the growth or development of the treated plants.

Some cultivated plants may also be weedy plants when they occur in unwanted environments. For example, corn plants growing in a soybean field. Transgenic crops with one or more herbicide tolerances will need specialized methods of management to control weeds and volunteer crop plants.

A “trigger” or “trigger polynucleotide” is a polynucleotide molecule that is homologous or complementary to a target gene polynucleotide. The trigger polynucleotide molecules modulate expression of the target gene when topically applied to a plant surface with a transfer agent, whereby a plant treated with said composition has its growth or development or reproductive ability regulated, suppressed or delayed or said plant is more sensitive to a PDS inhibitor herbicide as a result of said polynucleotide containing composition relative to a plant not treated with a composition containing the trigger molecule. Trigger polynucleotides disclosed herein are generally described in relation to the target gene sequence and maybe used in the sense (homologous) or antisense (complementary) orientation as single stranded molecules or comprise both strands as double stranded molecules or nucleotide variants and modified nucleotides thereof depending on the various regions of a gene being targeted.

It is contemplated that the composition will contain multiple polynucleotides and herbicides that include but not limited to PDS gene trigger polynucleotides and a PDS inhibitor herbicide and anyone or more additional herbicide target gene trigger polynucleotides and the related herbicides and anyone or more additional essential gene trigger polynucleotides. Essential genes are genes in a plant that provide key enzymes or other proteins, for example, a biosynthetic enzyme, metabolizing enzyme, receptor, signal transduction protein, structural gene product, transcription factor, or transport protein; or regulating RNAs, such as, microRNAs, that are essential to the growth or survival of the organism or cell or involved in the normal growth and development of the plant (Meinke, et al., Trends Plant Sci. 2008 September; 13(9):483-91). The suppression of an essential gene enhances the effect of a herbicide that affects the function of a gene product different than the suppressed essential gene. The compositions of the present invention can include various trigger polynucleotides that modulate the expression of an essential gene other than a PDS gene.

Herbicides for which transgenes for plant tolerance have been demonstrated and the method of the present invention can be applied, include but are not limited to: auxin-like herbicides, glyphosate, glufosinate, sulfonylureas, imidazolinones, bromoxynil, delapon, dicamba, cyclohezanedione, protoporphyrionogen oxidase inhibitors, 4-hydroxyphenyl-pyruvate-dioxygenase inhibitors herbicides. For example, transgenes and their polynucleotide molecules that encode proteins involved in herbicide tolerance are known in the art, and include, but are not limited to an 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS), for example, as more fully described in U.S. Pat. Nos. 7,807,791 (SEQ ID NO:5); 6,248,876 B1; 5,627,061; 5,804,425; 5,633,435; 5,145,783; 4,971,908; 5,1062,910; 5,188,642; 4,940,835; 5,866,775; 6,225,114 B1; 6,130,366; 5,1060,667; 4,535,060; 4,769,061; 5,633,448; 5,510,471; U.S. Pat. No. Re. 36,449; U.S. Pat. Nos. RE 37,287 E; and 5,491,288; tolerance to sulfonylurea and/or imidazolinone, for example, as described more fully in U.S. Pat. Nos. 5,605,011; 5,013,659; 5,141,870; 5,767,361; 5,7106,180; 5,304,732; 4,761,373; 5,3106,107; 5,928,937; and 5,378,824; and international publication WO 96/33270; tolerance to hydroxyphenylpyruvatedioxygenases inhibiting herbicides in plants are described in U.S. Pat. Nos. 6,245,968 B1; 6,268,549; and 6,069,115; US Pat. Pub. 20110191897 and U.S. Pat. No. 7,1062,379 SEQ ID NO:3; U.S. Pat. No. 7,935,869; U.S. Pat. No. 7,304,209, SEQ ID NO:1, 3, 5 and 15; aryloxyalkanoate dioxygenase polynucleotides, which confer tolerance to 2,4-D and other phenoxy auxin herbicides as well as to aryloxyphenoxypropionate herbicides as described, for example, in WO2005/107437; U.S. Pat. No. 7,838,733 SEQ ID NO:5;) and dicamba-tolerance polynucleotides as described, for example, in Herman et al. (2005) J. Biol. Chem. 280: 24759-24767. Other examples of herbicide-tolerance traits include those conferred by polynucleotides encoding an exogenous phosphinothricin acetyltransferase, as described in U.S. Pat. Nos. 5,969,213; 5,489,520; 5,550,1068; 5,874,265; 5,919,675; 5,561,236; 5,648,477; 5,646,024; 6,177,616; and 5,879,903. Plants containing an exogenous phosphinothricin acetyltransferase can exhibit improved tolerance to glufosinate herbicides, which inhibit the enzyme glutamine synthase. Additionally, herbicide-tolerance polynucleotides include those conferred by polynucleotides conferring altered protoporphyrinogen oxidase (protox) activity, as described in U.S. Pat. Nos. 6,288,306 B1; 6,282,837 B1; and 5,767,373; and WO 01/12825. Plants containing such polynucleotides can exhibit improved tolerance to any of a variety of herbicides which target the protox enzyme (also referred to as protox inhibitors). Polynucleotides encoding a glyphosate oxidoreductase and a glyphosate-N-acetyl transferase (GOX described in U.S. Pat. No. 5,463,175 and GAT described in U.S. Patent publication 20030083480, dicamba monooxygenase U.S. Patent publication 20030135879, all of which are incorporated herein by reference); a polynucleotide molecule encoding bromoxynil nitrilase (Bxn described in U.S. Pat. No. 4,810,648 for Bromoxynil tolerance, which is incorporated herein by reference); a polynucleotide molecule encoding phytoene desaturase (crtI) described in Misawa et al, (1993) Plant J. 4:833-840 and Misawa et al, (1994) Plant J. 6:481-489 for norflurazon tolerance; a polynucleotide molecule encoding acetohydroxyacid synthase (AHAS, aka ALS) described in Sathasiivan et al. (1990) Nucl. Acids Res. 18:1068-2193 for tolerance to sulfonylurea herbicides; and the bar gene described in DeBlock, et al. (1987) EMBO J. 6:2513-2519 for glufosinate and bialaphos tolerance. The transgenic coding regions and regulatory elements of the herbicide tolerance genes are targets in which polynucleotide triggers and herbicides can be included in the composition of the present invention.

PDS inhibitor herbicides include but are not limited to norflurazon, diflufenican, picolinafen, beflubutamid, fluridone, fluorochloridone and flurtamone.

Numerous herbicides with similar or different modes of action (herein referred to as co-herbicides) are available that can be added to the composition of the present invention, for example, members of the herbicide families that include but are not limited to amide herbicides, aromatic acid herbicides, arsenical herbicides, benzothiazole herbicides, benzoylcyclohexanedione herbicides, benzofuranyl alkylsulfonate herbicides, carbamate herbicides, cyclohexene oxime herbicides, cyclopropylisoxazole herbicides, dicarboximide herbicides, dinitroaniline herbicides, dinitrophenol herbicides, diphenyl ether herbicides, dithiocarbamate herbicides, halogenated aliphatic herbicides, imidazolinone herbicides, inorganic herbicides, nitrile herbicides, organophosphorus herbicides, oxadiazolone herbicides, oxazole herbicides, phenoxy herbicides, phenylenediamine herbicides, pyrazole herbicides, pyridazine herbicides, pyridazinone herbicides, pyridine herbicides, pyrimidinediamine herbicides, pyrimidinyloxybenzylamine herbicides, quaternary ammonium herbicides, thiocarbamate herbicides, thiocarbonate herbicides, thiourea herbicides, triazine herbicides, triazinone herbicides, triazole herbicides, triazolone herbicides, triazolopyrimidine herbicides, uracil herbicides, and urea herbicides. In particular, the rates of use of the added herbicides can be reduced in compositions comprising the polynucleotides of the invention. Use rate reductions of the additional added herbicides can be 10-25 percent, 26-50 percent, 51-75 percent or more can be achieved that enhance the activity of the polynucleotides and herbicide composition and is contemplated as an aspect of the invention. Representative co-herbicides of the families include but are not limited to acetochlor, acifluorfen, acifluorfen-sodium, aclonifen, acrolein, alachlor, alloxydim, allyl alcohol, ametryn, amicarbazone, amidosulfuron, aminopyralid, amitrole, ammonium sulfamate, anilofos, asulam, atraton, atrazine, azimsulfuron, BCPC, beflubutamid, benazolin, benfluralin, benfuresate, bensulfuron, bensulfuron-methyl, bensulide, bentazone, benzfendizone, benzobicyclon, benzofenap, bifenox, bilanafos, bispyribac, bispyribac-sodium, borax, bromacil, bromobutide, bromoxynil, butachlor, butafenacil, butamifos, butralin, butroxydim, butylate, cacodylic acid, calcium chlorate, cafenstrole, carbetamide, carfentrazone, carfentrazone-ethyl, CDEA, CEPC, chlorflurenol, chlorflurenol-methyl, chloridazon, chlorimuron, chlorimuron-ethyl, chloroacetic acid, chlorotoluron, chlorpropham, chlorsulfuron, chlorthal, chlorthal-dimethyl, cinidon-ethyl, cinmethylin, cinosulfuron, cisanilide, clethodim, clodinafop, clodinafop-propargyl, clomazone, clomeprop, clopyralid, cloransulam, cloransulam-methyl, CMA, 4-CPB, CPMF, 4-CPP, CPPC, cresol, cumyluron, cyanamide, cyanazine, cycloate, cyclosulfamuron, cycloxydim, cyhalofop, cyhalofop-butyl, 2,4-D, 3,4-DA, daimuron, dalapon, dazomet, 2,4-DB, 3,4-DB, 2,4-DEB, desmedipham, dicamba, dichlobenil, ortho-dichlorobenzene, para-dichlorobenzene, dichlorprop, dichlorprop-P, diclofop, diclofop-methyl, diclosulam, difenzoquat, difenzoquat metilsulfate, diflufenican, diflufenzopyr, dimefuron, dimepiperate, dimethachlor, dimethametryn, dimethenamid, dimethenamid-P, dimethipin, dimethylarsinic acid, dinitramine, dinoterb, diphenamid, diquat, diquat dibromide, dithiopyr, diuron, DNOC, 3,4-DP, DSMA, EBEP, endothal, EPTC, esprocarb, ethalfluralin, ethametsulfuron, ethametsulfuron-methyl, ethofumesate, ethoxyfen, ethoxysulfuron, etobenzanid, fenoxaprop-P, fenoxaprop-P-ethyl, fentrazamide, ferrous sulfate, flamprop-M, flazasulfuron, florasulam, fluazifop, fluazifop-butyl, fluazifop-P, fluazifop-P-butyl, flucarbazone, flucarbazone-sodium, flucetosulfuron, fluchloralin, flufenacet, flufenpyr, flufenpyr-ethyl, flumetsulam, flumiclorac, flumiclorac-pentyl, flumioxazin, fluometuron, fluoroglycofen, fluoroglycofen-ethyl, flupropanate, flupyrsulfuron, flupyrsulfuron-methyl-sodium, flurenol, fluridone, fluorochloridone, fluoroxypyr, flurtamone, fluthiacet, fluthiacet-methyl, fomesafen, foramsulfuron, fosamine, glufosinate, glufosinate-ammonium, glyphosate, halosulfuron, halosulfuron-methyl, haloxyfop, haloxyfop-P, HC-252, hexazinone, imazamethabenz, imazamethabenz-methyl, imazamox, imazapic, imazapyr, imazaquin, imazethapyr, imazosulfuron, indanofan, iodomethane, iodosulfuron, iodosulfuron-methyl-sodium, ioxynil, isoproturon, isouron, isoxaben, isoxachlortole, isoxaflutole, karbutilate, lactofen, lenacil, linuron, MAA, MAMA, MCPA, MCPA-thioethyl, MCPB, mecoprop, mecoprop-P, mefenacet, mefluidide, mesosulfuron, mesosulfuron-methyl, mesotrione, metam, metamifop, metamitron, metazachlor, methabenzthiazuron, methylarsonic acid, methyldymron, methyl isothiocyanate, metobenzuron, metolachlor, S-metolachlor, metosulam, metoxuron, metribuzin, metsulfuron, metsulfuron-methyl, MK-66, molinate, monolinuron, MSMA, naproanilide, napropamide, naptalam, neburon, nicosulfuron, nonanoic acid, norflurazon, oleic acid (fatty acids), orbencarb, orthosulfamuron, oryzalin, oxadiargyl, oxadiazon, oxasulfuron, oxaziclomefone, oxyfluorfen, paraquat, paraquat dichloride, pebulate, pendimethalin, penoxsulam, pentachlorophenol, pentanochlor, pentoxazone, pethoxamid, petrolium oils, phenmedipham, phenmedipham-ethyl, picloram, picolinafen, pinoxaden, piperophos, potassium arsenite, potassium azide, pretilachlor, primisulfuron, primisulfuron-methyl, prodiamine, profluazol, profoxydim, prometon, prometryn, propachlor, propanil, propaquizafop, propazine, propham, propisochlor, propoxycarbazone, propoxycarbazone-sodium, propyzamide, prosulfocarb, prosulfuron, pyraclonil, pyraflufen, pyraflufen-ethyl, pyrazolynate, pyrazosulfuron, pyrazosulfuron-ethyl, pyrazoxyfen, pyribenzoxim, pyributicarb, pyridafol, pyridate, pyriftalid, pyriminobac, pyriminobac-methyl, pyrimisulfan, pyrithiobac, pyrithiobac-sodium, quinclorac, quinmerac, quinoclamine, quizalofop, quizalofop-P, rimsulfuron, sethoxydim, siduron, simazine, simetryn, SMA, sodium arsenite, sodium azide, sodium chlorate, sulcotrione, sulfentrazone, sulfometuron, sulfometuron-methyl, sulfosate, sulfosulfuron, sulfuric acid, tar oils, 2,3,6-TBA, TCA, TCA-sodium, tebuthiuron, tepraloxydim, terbacil, terbumeton, terbuthylazine, terbutryn, thenylchlor, thiazopyr, thifensulfuron, thifensulfuron-methyl, thiobencarb, tiocarbazil, topramezone, tralkoxydim, tri-allate, triasulfuron, triaziflam, tribenuron, tribenuron-methyl, tricamba, triclopyr, trietazine, trifloxysulfuron, trifloxysulfuron-sodium, trifluralin, triflusulfuron, triflusulfuron-methyl, trihydroxytriazine, tritosulfuron, [3-[2-chloro-4-fluoro-5-(-methyl-6-trifluoromethyl-2,4-dioxo-,2,3,4-t-etrahydropyrimidin-3-yl)phenoxy]-2-pyridyloxy]acetic acid ethyl ester (CAS RN 353292-3-6), 4-[(4,5-dihydro-3-methoxy-4-methyl-5-oxo)-H-,2,4-triazol-ylcarbonyl-sulfamoyl]-5-methylthiophene-3-carboxylic acid (BAY636), BAY747 (CAS RN 33504-84-2), topramezone (CAS RN 2063-68-8), 4-hydroxy-3-[[2-[(2-methoxyethoxy)methyl]-6-(trifluoro-methyl)-3-pyridi-nyl]carbonyl]-bicyclo[3.2.]oct-3-en-2-one (CAS RN 35200-68-5), and 4-hydroxy-3-[[2-(3-methoxypropyl)-6-(difluoromethyl)-3-pyridinyl]carbon-yl]-bicyclo[3.2.]oct-3-en-2-one. Additionally, including herbicidal compounds of unspecified modes of action as described in CN101279950A, CN101279951A, DE10000600A1, DE10116399A1, DE102004054666A1, DE102005014638A1, DE102005014906A1, DE102007012168A1, DE102010042866A1, DE10204951A1, DE10234875A1, DE10234876A1, DE10256353A1, DE10256354A1, DE10256367A1, EP1157991A2, EP1238586A1, EP2147919A1, EP2160098A2, JP03968012B2, JP2001253874A, JP2002080454A, JP2002138075A, JP2002145707A, JP2002220389A, JP2003064059A, JP2003096059A, JP2004051628A, JP2004107228A, JP2005008583A, JP2005239675A, JP2005314407A, JP2006232824A, JP2006282552A, JP2007153847A, JP2007161701A, JP2007182404A, JP2008074840A, JP2008074841A, JP2008133207A, JP2008133218A, JP2008169121A, JP2009067739A, JP2009114128A, JP2009126792A, JP2009137851A, US20060111241A1, US20090036311A1, US20090054240A1, US20090215628A1, US20100099561A1, US20100152443A1, US20110105329A1, US20110201501A1, WO2001055066A2, WO2001056975A1, WO2001056979A1, WO2001090071A2, WO2001090080A1, WO2002002540A1, WO2002028182A1, WO2002040473A1, WO2002044173A2, WO2003000679A2, WO2003006422A1, WO2003013247A1, WO2003016308A1, WO2003020704A1, WO2003022051A1, WO2003022831A1, WO2003022843A1, WO2003029243A2, WO2003037085A1, WO2003037878A1, WO2003045878A2, WO2003050087A2, WO2003051823A1, WO2003051824A1, WO2003051846A2, WO2003076409A1, WO2003087067A1, WO2003090539A1, WO2003091217A1, WO2003093269A2, WO2003104206A2, WO2004002947A1, WO2004002981A2, WO2004011429A1, WO2004029060A1, WO2004035545A2, WO2004035563A1, WO2004035564A1, WO2004037787A1, WO2004067518A1, WO2004067527A1, WO2004077950A1, WO2005000824A1, WO2005007627A1, WO2005040152A1, WO2005047233A1, WO2005047281A1, WO2005061443A2, WO2005061464A1, WO2005068434A1, WO2005070889A1, WO2005089551A1, WO2005095335A1, WO2006006569A1, WO2006024820A1, WO2006029828A1, WO2006029829A1, WO2006037945A1, WO2006050803A1, WO2006090792A1, WO2006123088A2, WO2006125687A1, WO2006125688A1, WO2007003294A1, WO2007026834A1, WO2007071900A1, WO2007077201A1, WO2007077247A1, WO2007096576A1, WO2007119434A1, WO2007134984A1, WO2008009908A1, WO2008029084A1, WO2008059948A1, WO2008071918A1, WO2008074991A1, WO2008084073A1, WO2008100426A2, WO2008102908A1, WO2008152072A2, WO2008152073A2, WO2009000757A1, WO2009005297A2, WO2009035150A2, WO2009063180A1, WO2009068170A2, WO2009068171A2, WO2009086041A1, WO2009090401A2, WO2009090402A2, WO2009115788A1, WO2009116558A1, WO2009152995A1, WO2009158258A1, WO2010012649A1, WO2010012649A1, WO2010026989A1, WO2010034153A1, WO2010049270A1, WO2010049369A1, WO2010049405A1, WO2010049414A1, WO2010063422A1, WO2010069802A1, WO2010078906A2, WO2010078912A1, WO2010104217A1, WO2010108611A1, WO2010112826A3, WO2010116122A3, WO2010119906A1, WO2010130970A1, WO2011003776A2, WO2011035874A1, WO2011065451A1, all of which are incorporated herein by reference.

An agronomic field in need of plant control is treated by application of the composition directly to the surface of the growing plants, such as by a spray. For example, the method is applied to control weeds in a field of crop plants by spraying the field with the composition. The composition can be provided as a tank mix, a sequential treatment of components (generally the polynucleotide containing composition followed by the herbicide), or a simultaneous treatment or mixing of one or more of the components of the composition from separate containers. Treatment of the field can occur as often as needed to provide weed control and the components of the composition can be adjusted to target specific weed species or weed families through utilization of specific polynucleotides or polynucleotide compositions capable of selectively targeting the specific species or plant family to be controlled. The composition can be applied at effective use rates according to the time of application to the field, for example, preplant, at planting, post planting, post harvest. PDS inhibitor herbicides can be applied to a field at rates of 0.5 lb/ac to 5 lb/ac (pounds per acre) or more. The polynucleotides of the composition can be applied at rates of 1 to 30 grams per acre depending on the number of trigger molecules needed for the scope of weeds in the field.

Crop plants in which weed control is needed include but are not limited to, i) corn, soybean, cotton, canola, sugar beet, alfalfa, sugarcane, rice, and wheat; ii) vegetable plants including, but not limited to, tomato, sweet pepper, hot pepper, melon, watermelon, cucumber, eggplant, cauliflower, broccoli, lettuce, spinach, onion, peas, carrots, sweet corn, Chinese cabbage, leek, fennel, pumpkin, squash or gourd, radish, Brussels sprouts, tomatillo, garden beans, dry beans, or okra; iii) culinary plants including, but not limited to, basil, parsley, coffee, or tea; or, iv) fruit plants including but not limited to apple, pear, cherry, peach, plum, apricot, banana, plantain, table grape, wine grape, citrus, avocado, mango, or berry; v) a tree grown for ornamental or commercial use, including, but not limited to, a fruit or nut tree; or, yl) an ornamental plant (e.g., an ornamental flowering plant or shrub or turf grass). The methods and compositions provided herein can also be applied to plants produced by a cutting, cloning, or grafting process (i.e., a plant not grown from a seed) include fruit trees and plants that include, but are not limited to, citrus, apples, avocados, tomatoes, eggplant, cucumber, melons, watermelons, and grapes as well as various ornamental plants.

Pesticidal Mixtures

The polynucleotide compositions may also be used as mixtures with various agricultural chemicals and/or insecticides, miticides and fungicides, pesticidal and biopesticidal agents. Examples include but are not limited to azinphos-methyl, acephate, isoxathion, isofenphos, ethion, etrimfos, oxydemeton-methyl, oxydeprofos, quinalphos, chlorpyrifos, chlorpyrifos-methyl, chlorfenvinphos, cyanophos, dioxabenzofos, dichlorvos, disulfoton, dimethylvinphos, dimethoate, sulprofos, diazinon, thiometon, tetrachlorvinphos, temephos, tebupirimfos, terbufos, naled, vamidothion, pyraclofos, pyridafenthion, pirimiphos-methyl, fenitrothion, fenthion, phenthoate, flupyrazophos, prothiofos, propaphos, profenofos, phoxime, phosalone, phosmet, formothion, phorate, malathion, mecarbam, mesulfenfos, methamidophos, methidathion, parathion, methyl parathion, monocrotophos, trichlorphon, EPN, isazophos, isamidofos, cadusafos, diamidaphos, dichlofenthion, thionazin, fenamiphos, fosthiazate, fosthietan, phosphocarb, DSP, ethoprophos, alanycarb, aldicarb, isoprocarb, ethiofencarb, carbaryl, carbosulfan, xylylcarb, thiodicarb, pirimicarb, fenobucarb, furathiocarb, propoxur, bendiocarb, benfuracarb, methomyl, metolcarb, XMC, carbofuran, aldoxycarb, oxamyl, acrinathrin, allethrin, esfenvalerate, empenthrin, cycloprothrin, cyhalothrin, gamma-cyhalothrin, lambda-cyhalothrin, cyfluthrin, beta-cyfluthrin, cypermethrin, alpha-cypermethrin, zeta-cypermethrin, silafluofen, tetramethrin, tefluthrin, deltamethrin, tralomethrin, bifenthrin, phenothrin, fenvalerate, fenpropathrin, furamethrin, prallethrin, flucythrinate, fluvalinate, flubrocythrinate, permethrin, resmethrin, ethofenprox, cartap, thiocyclam, bensultap, acetamiprid, imidacloprid, clothianidin, dinotefuran, thiacloprid, thiamethoxam, nitenpyram, chlorfluazuron, diflubenzuron, teflubenzuron, triflumuron, novaluron, noviflumuron, bistrifluoron, fluazuron, flucycloxuron, flufenoxuron, hexaflumuron, lufenuron, chromafenozide, tebufenozide, halofenozide, methoxyfenozide, diofenolan, cyromazine, pyriproxyfen, buprofezin, methoprene, hydroprene, kinoprene, triazamate, endosulfan, chlorfenson, chlorobenzilate, dicofol, bromopropylate, acetoprole, fipronil, ethiprole, pyrethrin, rotenone, nicotine sulphate, BT (Bacillus Thuringiensis) agent, spinosad, abamectin, acequinocyl, amidoflumet, amitraz, etoxazole, chinomethionat, clofentezine, fenbutatin oxide, dienochlor, cyhexatin, spirodiclofen, spiromesifen, tetradifon, tebufenpyrad, binapacryl, bifenazate, pyridaben, pyrimidifen, fenazaquin, fenothiocarb, fenpyroximate, fluacrypyrim, fluazinam, flufenzin, hexythiazox, propargite, benzomate, polynactin complex, milbemectin, lufenuron, mecarbam, methiocarb, mevinphos, halfenprox, azadirachtin, diafenthiuron, indoxacarb, emamectin benzoate, potassium oleate, sodium oleate, chlorfenapyr, tolfenpyrad, pymetrozine, fenoxycarb, hydramethylnon, hydroxy propyl starch, pyridalyl, flufenerim, flubendiamide, flonicamid, metaflumizole, lepimectin, TPIC, albendazole, oxibendazole, oxfendazole, trichlamide, fensulfothion, fenbendazole, levamisole hydrochloride, morantel tartrate, dazomet, metam-sodium, triadimefon, hexaconazole, propiconazole, ipconazole, prochloraz, triflumizole, tebuconazole, epoxiconazole, difenoconazole, flusilazole, triadimenol, cyproconazole, metconazole, fluquinconazole, bitertanol, tetraconazole, triticonazole, flutriafol, penconazole, diniconazole, fenbuconazole, bromuconazole, imibenconazole, simeconazole, myclobutanil, hymexazole, imazalil, furametpyr, thifluzamide, etridiazole, oxpoconazole, oxpoconazole fumarate, pefurazoate, prothioconazole, pyrifenox, fenarimol, nuarimol, bupirimate, mepanipyrim, cyprodinil, pyrimethanil, metalaxyl, mefenoxam, oxadixyl, benalaxyl, thiophanate, thiophanate-methyl, benomyl, carbendazim, fuberidazole, thiabendazole, manzeb, propineb, zineb, metiram, maneb, ziram, thiuram, chlorothalonil, ethaboxam, oxycarboxin, carboxin, flutolanil, silthiofam, mepronil, dimethomorph, fenpropidin, fenpropimorph, spiroxamine, tridemorph, dodemorph, flumorph, azoxystrobin, kresoxim-methyl, metominostrobin, orysastrobin, fluoxastrobin, trifloxystrobin, dimoxystrobin, pyraclostrobin, picoxystrobin, iprodione, procymidone, vinclozolin, chlozolinate, flusulfamide, dazomet, methyl isothiocyanate, chloropicrin, methasulfocarb, hydroxyisoxazole, potassium hydroxyisoxazole, echlomezol, D-D, carbam, basic copper chloride, basic copper sulfate, copper nonylphenolsulfonate, oxine copper, DBEDC, anhydrous copper sulfate, copper sulfate pentahydrate, cupric hydroxide, inorganic sulfur, wettable sulfur, lime sulfur, zinc sulfate, fentin, sodium hydrogen carbonate, potassium hydrogen carbonate, sodium hypochlorite, silver, edifenphos, tolclofos-methyl, fosetyl, iprobenfos, dinocap, pyrazophos, carpropamid, fthalide, tricyclazole, pyroquilon, diclocymet, fenoxanil, kasugamycin, validamycin, polyoxins, blasticiden S, oxytetracycline, mildiomycin, streptomycin, rape seed oil, machine oil, benthiavalicarbisopropyl, iprovalicarb, propamocarb, diethofencarb, fluoroimide, fludioxanil, fenpiclonil, quinoxyfen, oxolinic acid, chlorothalonil, captan, folpet, probenazole, acibenzolar-S-methyl, tiadinil, cyflufenamid, fenhexamid, diflumetorim, metrafenone, picobenzamide, proquinazid, famoxadone, cyazofamid, fenamidone, zoxamide, boscalid, cymoxanil, dithianon, fluazinam, dichlofluanide, triforine, isoprothiolane, ferimzone, diclomezine, tecloftalam, pencycuron, chinomethionat, iminoctadine acetate, iminoctadine albesilate, ambam, polycarbamate, thiadiazine, chloroneb, nickel dimethyldithiocarbamate, guazatine, dodecylguanidine-acetate, quintozene, tolylfluanid, anilazine, nitrothalisopropyl, fenitropan, dimethirimol, benthiazole, harpin protein, flumetover, mandipropamide and penthiopyrad.

Polynucleotides

As used herein, the term “DNA”, “DNA molecule”, “DNA polynucleotide molecule” refers to a single-stranded DNA (ssDNA) or double-stranded DNA (dsDNA) molecule of genomic or synthetic origin, such as, a polymer of deoxyribonucleotide bases or a DNA polynucleotide molecule. As used herein, the term “DNA sequence”, “DNA nucleotide sequence” or “DNA polynucleotide sequence” refers to the nucleotide sequence of a DNA molecule. As used herein, the term “RNA”, “RNA molecule”, “RNA polynucleotide molecule” refers to a single-stranded RNA (ssRNA) or double-stranded RNA (dsRNA) molecule of genomic or synthetic origin, such as, a polymer of ribonucleotide bases that comprise single or double stranded regions. Unless otherwise stated, nucleotide sequences in the text of this specification are given, when read from left to right, in the 5′ to 3′ direction. The nomenclature used herein is that required by Title 37 of the United States Code of Federal Regulations §1.822 and set forth in the tables in WIPO Standard ST.25 (1998), Appendix 2, Tables 1 and 3.

As used herein, “polynucleotide” refers to a DNA or RNA molecule containing multiple nucleotides and generally refers both to “oligonucleotides” (a polynucleotide molecule of typically 50 or fewer nucleotides in length) and polynucleotides of 51 or more nucleotides. Embodiments include compositions including oligonucleotides having a length of 18-25 nucleotides (18-mers, 19-mers, 20-mers, 21-mers, 22-mers, 23-mers, 24-mers, or 25-mers), for example, oligonucleotides SEQ ID NO:2011-2136 or fragments thereof or medium-length polynucleotides having a length of 26 or more nucleotides (polynucleotides of 26, 27, 28, 29, 30, 106, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, about 65, about 70, about 75, about 80, about 85, about 90, about 95, about 100, about 110, about 120, about 130, about 140, about 150, about 160, about 170, about 180, about 190, about 200, about 210, about 220, about 230, about 240, about 250, about 260, about 270, about 280, about 290, or about 300 nucleotides), for example, oligonucleotides of SEQ ID NO:79-2010 or fragments thereof or long polynucleotides having a length greater than about 300 nucleotides (for example, polynucleotides of between about 300 to about 400 nucleotides, between about 400 to about 500 nucleotides, between about 500 to about 600 nucleotides, between about 600 to about 700 nucleotides, between about 700 to about 800 nucleotides, between about 800 to about 900 nucleotides, between about 900 to about 1000 nucleotides, between about 300 to about 500 nucleotides, between about 300 to about 600 nucleotides, between about 300 to about 700 nucleotides, between about 300 to about 800 nucleotides, between about 300 to about 900 nucleotides, or about 1000 nucleotides in length, or even greater than about 1000 nucleotides in length, for example up to the entire length of a target gene including coding or non-coding or both coding and non-coding portions of the target gene), for example, polynucleotides of Table 1 (SEQ ID NO:1-78) and SEQ ID NO: 2138, wherein the selected polynucleotides or fragments thereof are homologous or complementary to SEQ ID NO:1-78 and 2138 suppresses, represses or otherwise delay the expression of the target PDS gene. A target gene comprises any polynucleotide molecule in a plant cell or fragment thereof for which the modulation of the expression of the target gene is provided by the methods and compositions. Where a polynucleotide is double-stranded, its length can be similarly described in terms of base pairs. Oligonucleotides and polynucleotides can be made that are essentially identical or essentially complementary to adjacent genetic elements of a gene, for example, spanning the junction region of an intron and exon, the junction region of a promoter and a transcribed region, the junction region of a 5′ leader and a coding sequence, the junction of a 3′ untranslated region and a coding sequence.

Polynucleotide compositions used in the various embodiments include compositions including oligonucleotides or polynucleotides or a mixture of both, including RNA or DNA or RNA/DNA hybrids or chemically modified oligonucleotides or polynucleotides or a mixture thereof. In some embodiments, the polynucleotide may be a combination of ribonucleotides and deoxyribonucleotides, for example, synthetic polynucleotides consisting mainly of ribonucleotides but with one or more terminal deoxyribonucleotides or synthetic polynucleotides consisting mainly of deoxyribonucleotides but with one or more terminal dideoxyribonucleotides. In some embodiments, the polynucleotide includes non-canonical nucleotides such as inosine, thiouridine, or pseudouridine. In some embodiments, the polynucleotide includes chemically modified nucleotides. Examples of chemically modified oligonucleotides or polynucleotides are well known in the art; see, for example, US Patent Publication 20110171287, US Patent Publication 20110171176, and US Patent Publication 20110152353, US Patent Publication, 20110152346, US Patent Publication 20110160082, herein incorporated by reference. For example, including but not limited to the naturally occurring phosphodiester backbone of an oligonucleotide or polynucleotide can be partially or completely modified with phosphorothioate, phosphorodithioate, or methylphosphonate internucleotide linkage modifications, modified nucleoside bases or modified sugars can be used in oligonucleotide or polynucleotide synthesis, and oligonucleotides or polynucleotides can be labeled with a fluorescent moiety (for example, fluorescein or rhodamine) or other label (for example, biotin).

The polynucleotides can be single- or double-stranded RNA or single- or double-stranded DNA or double-stranded DNA/RNA hybrids or modified analogues thereof, and can be of oligonucleotide lengths or longer. In more specific embodiments the polynucleotides that provide single-stranded RNA in the plant cell are selected from the group consisting of (a) a single-stranded RNA molecule (ssRNA), (b) a single-stranded RNA molecule that self-hybridizes to form a double-stranded RNA molecule, (c) a double-stranded RNA molecule (dsRNA), (d) a single-stranded DNA molecule (ssDNA), (e) a single-stranded DNA molecule that self-hybridizes to form a double-stranded DNA molecule, and (f) a single-stranded DNA molecule including a modified Pol III gene that is transcribed to an RNA molecule, (g) a double-stranded DNA molecule (dsDNA), (h) a double-stranded DNA molecule including a modified Pol III gene that is transcribed to an RNA molecule, (i) a double-stranded, hybridized RNA/DNA molecule, or combinations thereof. In some embodiments these polynucleotides include chemically modified nucleotides or non-canonical nucleotides. In some embodiments, the oligonucleotides may be blunt-ended or may comprise a 3′ overhang of from 1-5 nucleotides of at least one or both of the strands. Other configurations of the oligonucleotide are known in the field and are contemplated herein. In embodiments of the method the polynucleotides include double-stranded DNA formed by intramolecular hybridization, double-stranded DNA formed by intermolecular hybridization, double-stranded RNA formed by intramolecular hybridization, or double-stranded RNA formed by intermolecular hybridization. In one embodiment the polynucleotides include single-stranded DNA or single-stranded RNA that self-hybridizes to form a hairpin structure having an at least partially double-stranded structure including at least one segment that will hybridize to RNA transcribed from the gene targeted for suppression. Not intending to be bound by any mechanism, it is believed that such polynucleotides are or will produce single-stranded RNA with at least one segment that will hybridize to RNA transcribed from the gene targeted for suppression. In certain other embodiments the polynucleotides further includes a promoter, generally a promoter functional in a plant, for example, a pol II promoter, a pol III promoter, a pol IV promoter, or a pol V promoter.

The term “gene” refers to chromosomal DNA, plasmid DNA, cDNA, intron and exon DNA, artificial DNA polynucleotide, or other DNA that encodes a peptide, polypeptide, protein, or RNA transcript molecule, and the genetic elements flanking the coding sequence that are involved in the regulation of expression, such as, promoter regions, 5′ leader regions, 3′ untranslated regions. The gene or a fragment thereof is isolated and subjected to polynucleotide sequencing methods that determines the order of the nucleotides that comprise the gene. Any of the components of the gene are potential targets for the oligonucleotides and polynucleotides.

The polynucleotide molecules are designed to modulate expression by inducing regulation or suppression of an endogenous PDS gene in a plant and are designed to have a nucleotide sequence essentially identical or essentially complementary to the nucleotide sequence of an endogenous PDS gene of a plant or to the sequence of RNA transcribed from an endogenous PDS gene of a plant, including a transgene in a plant that provides for a herbicide resistant PDS enzyme, which can be coding sequence or non-coding sequence. Effective molecules that modulate expression are referred to as “a trigger molecule, or trigger polynucleotide”. By “essentially identical” or “essentially complementary” is meant that the trigger polynucleotides (or at least one strand of a double-stranded polynucleotide or portion thereof, or a portion of a single strand polynucleotide) are designed to hybridize to the endogenous gene noncoding sequence or to RNA transcribed (known as messenger RNA or an RNA transcript) from the endogenous gene to effect regulation or suppression of expression of the endogenous gene. Trigger molecules are identified by “tiling” the gene targets with partially overlapping probes or non-overlapping probes of antisense or sense polynucleotides that are essentially identical or essentially complementary to the nucleotide sequence of an endogenous gene. Multiple target sequences can be aligned and sequence regions with homology in common are identified as potential trigger molecules for the multiple targets. Multiple trigger molecules of various lengths, for example 18-25 nucleotides, 26-50 nucleotides, 51-100 nucleotides, 101-200 nucleotides, 201-300 nucleotides or more can be pooled into a few treatments in order to investigate polynucleotide molecules that cover a portion of a gene sequence (for example, a portion of a coding versus a portion of a noncoding region, or a 5′ versus a 3′ portion of a gene) or an entire gene sequence including coding and noncoding regions of a target gene. Polynucleotide molecules of the pooled trigger molecules can be divided into smaller pools or single molecules inorder to identify trigger molecules that provide the desired effect.

The target gene RNA and DNA polynucleotide molecules (Table 1, SEQ ID NO: 1-78, and SEQ ID NO: 2138) are sequenced by any number of available methods and equipment. Some of the sequencing technologies are available commercially, such as the sequencing-by-hybridization platform from Affymetrix Inc. (Sunnyvale, Calif.) and the sequencing-by-synthesis platforms from 454 Life Sciences (Bradford, Conn.), Illumina/Solexa (Hayward, Calif.) and Helicos Biosciences (Cambridge, Mass.), and the sequencing-by-ligation platform from Applied Biosystems (Foster City, Calif.), as described below. In addition to the single molecule sequencing performed using sequencing-by-synthesis of Helicos Biosciences, other single molecule sequencing technologies are encompassed by the method of the invention and include the SMRT.™ technology of Pacific Biosciences, the Ion Torrent.™. technology, and nanopore sequencing being developed for example, by Oxford Nanopore Technologies. A PDS target gene comprising DNA or RNA can be isolated using primers or probes essentially complementary or essentially homologous to SEQ ID NO:1-78 and 2138 or a fragment thereof. A polymerase chain reaction (PCR) gene fragment can be produced using primers essentially complementary or essentially homologous to SEQ ID NO:1-78 and 2138 or a fragment thereof that is useful to isolate a PDS gene from a plant genome. SEQ ID NO: 1-78 and 2138 or fragments thereof can be used in various sequence capture technologies to isolate additional target gene sequences, for example, including but not limited to Roche NimbleGen® (Madison, Wis.) and Streptavdin-coupled Dynabeads® (Life Technologies, Grand Island, N.Y.) and US20110015084, herein incorporated by reference in its entirety.

Embodiments of functional single-stranded polynucleotides have sequence complementarity that need not be 100 percent, but is at least sufficient to permit hybridization to RNA transcribed from the target gene or DNA of the target gene to form a duplex to permit a gene silencing mechanism. Thus, in embodiments, a polynucleotide fragment is designed to be essentially identical to, or essentially complementary to, a sequence of 18 or more contiguous nucleotides in either the target PDS gene sequence or messenger RNA transcribed from the target gene. By “essentially identical” is meant having 100 percent sequence identity or at least about 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, or 99 percent sequence identity when compared to the sequence of 18 or more contiguous nucleotides in either the target gene or RNA transcribed from the target gene; by “essentially complementary” is meant having 100 percent sequence complementarity or at least about 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, or 99 percent sequence complementarity when compared to the sequence of 18 or more contiguous nucleotides in either the target gene or RNA transcribed from the target gene. In some embodiments polynucleotide molecules are designed to have 100 percent sequence identity with or complementarity to one allele or one family member of a given target gene (coding or non-coding sequence of a gene); in other embodiments the polynucleotide molecules are designed to have 100 percent sequence identity with or complementarity to multiple alleles or family members of a given target gene.

In certain embodiments, the polynucleotides used in the compositions that are essentially identical or essentially complementary to the target gene or transcript will comprise the predominant nucleic acid in the composition. Thus in certain embodiments, the polynucleotides that are essentially identical or essentially complementary to the target gene or transcript will comprise at least about 50%, 75%, 95%, 98% or 100% of the nucleic acids provided in the composition by either mass or molar concentration. However, in certain embodiments, the polynucleotides that are essentially identical or essentially complementary to the target gene or transcript can comprise at least about 1% to about 50%, about 10% to about 50%, about 20% to about 50%, or about 30% to about 50% of the nucleic acids provided in the composition by either mass or molar concentration. Also provided are compositions where the polynucleotides that are essentially identical or essentially complementary to the target gene or transcript can comprise at least about 1% to 100%, about 10% to 100%, about 20% to about 100%, about 30% to about 50%, or about 50% to a 100% of the nucleic acids provided in the composition by either mass or molar concentration.

“Identity” refers to the degree of similarity between two polynucleic acid or protein sequences. An alignment of the two sequences is performed by a suitable computer program. A widely used and accepted computer program for performing sequence alignments is CLUSTALW v1.6 (Thompson, et al. Nucl. Acids Res., 22: 4673-4680, 1994). The number of matching bases or amino acids is divided by the total number of bases or amino acids, and multiplied by 100 to obtain a percent identity. For example, if two 580 base pair sequences had 145 matched bases, they would be 25 percent identical. If the two compared sequences are of different lengths, the number of matches is divided by the shorter of the two lengths. For example, if there are 100 matched amino acids between a 200 and a 400 amino acid protein, they are 50 percent identical with respect to the shorter sequence. If the shorter sequence is less than 150 bases or 50 amino acids in length, the number of matches are divided by 150 (for nucleic acid bases) or 50 (for amino acids), and multiplied by 100 to obtain a percent identity.

Trigger molecules for specific gene family members can be identified from coding and/or non-coding sequences of gene families of a plant or multiple plants, by aligning and selecting 200-300 polynucleotide fragments from the least homologous regions amongst the aligned sequences and evaluated using topically applied polynucleotides (as sense or anti-sense ssDNA or ssRNA, dsRNA, or dsDNA) to determine their relative effectiveness in inducing the herbicidal phenotype. The effective segments are further subdivided into 50-60 polynucleotide fragments, prioritized by least homology, and reevaluated using topically applied polynucleotides. The effective 50-60 polynucleotide fragments are subdivided into 19-30 polynucleotide fragments, prioritized by least homology, and again evaluated for induction of the yield/quality phenotype. Once relative effectiveness is determined, the fragments are utilized singly, or again evaluated in combination with one or more other fragments to determine the trigger composition or mixture of trigger polynucleotides for providing the yield/quality phenotype.

Trigger molecules for broad activity can be identified from coding and/or non-coding sequences of gene families of a plant or multiple plants, by aligning and selecting 200-300 polynucleotide fragments from the most homologous regions amongst the aligned sequences and evaluated using topically applied polynucleotides (as sense or anti-sense ssDNA or ssRNA, dsRNA, or dsDNA) to determine their relative effectiveness in inducing the yield/quality phenotype. The effective segments are subdivided into 50-60 polynucleotide fragments, prioritized by most homology, and reevaluated using topically applied polynucleotides. The effective 50-60 polynucleotide fragments are subdivided into 19-30 polynucleotide fragments, prioritized by most homology, and again evaluated for induction of the yield/quality phenotype. Once relative effectiveness is determined, the fragments may be utilized singly, or in combination with one or more other fragments to determine the trigger composition or mixture of trigger polynucleotides for providing the yield/quality phenotype.

Methods of making polynucleotides are well known in the art. Chemical synthesis, in vivo synthesis and in vitro synthesis methods and compositions are known in the art and include various viral elements, microbial cells, modified polymerases, and modified nucleotides. Commercial preparation of oligonucleotides often provides two deoxyribonucleotides on the 3′ end of the sense strand. Long polynucleotide molecules can be synthesized from commercially available kits, for example, kits from Applied Biosystems/Ambion (Austin, Tex.) have DNA ligated on the 5′ end in a microbial expression cassette that includes a bacterial T7 polymerase promoter that makes RNA strands that can be assembled into a dsRNA and kits provided by various manufacturers that include T7 RiboMax Express (Promega, Madison, Wis.), AmpliScribe T7-Flash (Epicentre, Madison, Wis.), and TranscriptAid T7 High Yield (Fermentas, Glen Burnie, Md.). dsRNA molecules can be produced from microbial expression cassettes in bacterial cells (Ongvarrasopone et al. ScienceAsia 33:35-39; Yin, Appl. Microbiol. Biotechnol 84:323-333, 2009; Liu et al., BMC Biotechnology 10:85, 2010) that have regulated or deficient RNase III enzyme activity or the use of various viral vectors to produce sufficient quantities of dsRNA. PDS gene fragments are inserted into the microbial expression cassettes in a position in which the fragments are express to produce ssRNA or dsRNA useful in the methods described herein to regulate expression on a target PDS gene. Long polynucleotide molecules can also be assembled from multiple RNA or DNA fragments. In some embodiments design parameters such as Reynolds score (Reynolds et al. Nature Biotechnology 22, 326-330 (2004), Tuschl rules (Pei and Tuschl, Nature Methods 3(9): 670-676, 2006), i-score (Nucleic Acids Res 35: e123, 2007), i-Score Designer tool and associated algorithms (Nucleic Acids Res 32: 936-948, 2004. Biochem Biophys Res Commun 316: 1050-1058, 2004, Nucleic Acids Res 32: 893-901, 2004, Cell Cycle 3: 790-5, 2004, Nat Biotechnol 23: 995-1001, 2005, Nucleic Acids Res 35: e27, 2007, BMC Bioinformatics 7: 520, 2006, Nucleic Acids Res 35: e123, 2007, Nat Biotechnol 22: 326-330, 2004) are known in the art and may be used in selecting polynucleotide sequences effective in gene silencing. In some embodiments the sequence of a polynucleotide is screened against the genomic DNA of the intended plant to minimize unintentional silencing of other genes.

The trigger polynucleotide and oligonucleotide molecule compositions are useful in compositions, such as liquids that comprise the polynucleotide molecules at low concentrations, alone or in combination with other components, for example one or more herbicide molecules, either in the same solution or in separately applied liquids that also provide a transfer agent. While there is no upper limit on the concentrations and dosages of polynucleotide molecules that can useful, lower effective concentrations and dosages will generally be sought for efficiency. The concentrations can be adjusted in consideration of the volume of spray or treatment applied to plant leaves or other plant part surfaces, such as flower petals, stems, tubers, fruit, anthers, pollen, or seed. In one embodiment, a useful treatment for herbaceous plants using 25-mer oligonucleotide molecules is about 1 nanomole (nmol) of oligonucleotide molecules per plant, for example, from about 0.05 to 1 nmol per plant. Other embodiments for herbaceous plants include useful ranges of about 0.05 to about 100 nmol, or about 0.1 to about 20 nmol, or about 1 nmol to about 10 nmol of polynucleotides per plant. Very large plants, trees, or vines may require correspondingly larger amounts of polynucleotides. When using long dsRNA molecules that can be processed into multiple oligonucleotides, lower concentrations can be used. To illustrate embodiments, the factor 1×, when applied to oligonucleotide molecules is arbitrarily used to denote a treatment of 0.8 nmol of polynucleotide molecule per plant; 10×, 8 nmol of polynucleotide molecule per plant; and 100×, 80 nmol of polynucleotide molecule per plant.

The polynucleotide compositions are useful in compositions, such as liquids that comprise polynucleotide molecules, alone or in combination with other components either in the same liquid or in separately applied liquids that provide a transfer agent. As used herein, a transfer agent is an agent that, when combined with a polynucleotide in a composition that is topically applied to a target plant surface, enables the polynucleotide to enter a plant cell. In certain embodiments, a transfer agent is an agent that conditions the surface of plant tissue, e.g., leaves, stems, roots, flowers, or fruits, to permeation by the polynucleotide molecules into plant cells. The transfer of polynucleotides into plant cells can be facilitated by the prior or contemporaneous application of a polynucleotide-transferring agent to the plant tissue. In some embodiments the transferring agent is applied subsequent to the application of the polynucleotide composition. The polynucleotide transfer agent enables a pathway for polynucleotides through cuticle wax barriers, stomata and/or cell wall or membrane barriers into plant cells. Suitable transfer agents to facilitate transfer of the polynucleotide into a plant cell include agents that increase permeability of the exterior of the plant or that increase permeability of plant cells to oligonucleotides or polynucleotides. Such agents to facilitate transfer of the composition into a plant cell include a chemical agent, or a physical agent, or combinations thereof. Chemical agents for conditioning or transfer include (a) surfactants, (b) an organic solvent or an aqueous solution or aqueous mixtures of organic solvents, (c) oxidizing agents, (d) acids, (e) bases, (f) oils, (g) enzymes, or combinations thereof. Embodiments of the method can optionally include an incubation step, a neutralization step (e.g., to neutralize an acid, base, or oxidizing agent, or to inactivate an enzyme), a rinsing step, or combinations thereof. Embodiments of agents or treatments for conditioning of a plant to permeation by polynucleotides include emulsions, reverse emulsions, liposomes, and other micellar-like compositions. Embodiments of agents or treatments for conditioning of a plant to permeation by polynucleotides include counter-ions or other molecules that are known to associate with nucleic acid molecules, e.g., inorganic ammonium ions, alkyl ammonium ions, lithium ions, polyamines such as spermine, spermidine, or putrescine, and other cations. Organic solvents useful in conditioning a plant to permeation by polynucleotides include DMSO, DMF, pyridine, N-pyrrolidine, hexamethylphosphoramide, acetonitrile, dioxane, polypropylene glycol, other solvents miscible with water or that will dissolve phosphonucleotides in non-aqueous systems (such as is used in synthetic reactions). Naturally derived or synthetic oils with or without surfactants or emulsifiers can be used, e.g., plant-sourced oils, crop oils (such as those listed in the 9^thCompendium of Herbicide Adjuvants, publicly available on the worldwide web (internet) at herbicide.adjuvants.com can be used, e.g., paraffinic oils, polyol fatty acid esters, or oils with short-chain molecules modified with amides or polyamines such as polyethyleneimine or N-pyrrolidine. Transfer agents include, but are not limited to, organosilicone preparations.

In certain embodiments, an organosilicone preparation that is commercially available as Silwet® L-77 surfactant having CAS Number 27306-78-1 and EPA Number: CAL.REG.NO. 5905-50073-AA, and currently available from Momentive Performance Materials, Albany, N.Y. can be used to prepare a polynucleotide composition. In certain embodiments where a Silwet L-77 organosilicone preparation is used as a pre-spray treatment of plant leaves or other plant surfaces, freshly made concentrations in the range of about 0.015 to about 2 percent by weight (wt percent) (e.g., about 0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04, 0.045, 0.05, 0.055, 0.06, 0.065, 0.07, 0.075, 0.08, 0.085, 0.09, 0.095, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.5 wt percent) are efficacious in preparing a leaf or other plant surface for transfer of polynucleotide molecules into plant cells from a topical application on the surface. In certain embodiments of the methods and compositions provided herein, a composition that comprises a polynucleotide molecule and an organosilicone preparation comprising Silwet L-77 in the range of about 0.015 to about 2 percent by weight (wt percent) (e.g., about 0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04, 0.045, 0.05, 0.055, 0.06, 0.065, 0.07, 0.075, 0.08, 0.085, 0.09, 0.095, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.5 wt percent) is used or provided.

In certain embodiments, any of the commercially available organosilicone preparations provided such as the following Breakthru S 321, Breakthru S 200 Cat#67674-67-3, Breakthru OE 441 Cat#68937-55-3, Breakthru S 278 Cat #27306-78-1, Breakthru S 243, Breakthru S 233 Cat#134180-76-0, available from manufacturer Evonik Goldschmidt (Germany), Silwet® HS 429, Silwet® HS 312, Silwet® HS 508, Silwet® HS 604 (Momentive Performance Materials, Albany, N.Y.) can be used as transfer agents in a polynucleotide composition. In certain embodiments where an organosilicone preparation is used as a pre-spray treatment of plant leaves or other surfaces, freshly made concentrations in the range of about 0.015 to about 2 percent by weight (wt percent) (e.g., about 0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04, 0.045, 0.05, 0.055, 0.06, 0.065, 0.07, 0.075, 0.08, 0.085, 0.09, 0.095, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.5 wt percent) are efficacious in preparing a leaf or other plant surface for transfer of polynucleotide molecules into plant cells from a topical application on the surface. In certain embodiments of the methods and compositions provided herein, a composition that comprises a polynucleotide molecule and an organosilicone preparation in the range of about 0.015 to about 2 percent by weight (wt percent) (e.g., about 0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04, 0.045, 0.05, 0.055, 0.06, 0.065, 0.07, 0.075, 0.08, 0.085, 0.09, 0.095, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.5 wt percent) is used or provided.

Organosilicone preparations used in the methods and compositions provided herein can comprise one or more effective organosilicone compounds. As used herein, the phrase “effective organosilicone compound” is used to describe any organosilicone compound that is found in an organosilicone preparation that enables a polynucleotide to enter a plant cell. In certain embodiments, an effective organosilicone compound can enable a polynucleotide to enter a plant cell in a manner permitting a polynucleotide mediated suppression of a target gene expression in the plant cell. In general, effective organosilicone compounds include, but are not limited to, compounds that can comprise: i) a trisiloxane head group that is covalently linked to, ii) an alkyl linker including, but not limited to, an n-propyl linker, that is covalently linked to, iii) a poly glycol chain, that is covalently linked to, iv) a terminal group. Trisiloxane head groups of such effective organosilicone compounds include, but are not limited to, heptamethyltrisiloxane. Alkyl linkers can include, but are not limited to, an n-propyl linker Poly glycol chains include, but are not limited to, polyethylene glycol or polypropylene glycol. Poly glycol chains can comprise a mixture that provides an average chain length “n” of about “7.5”. In certain embodiments, the average chain length “n” can vary from about 5 to about 14. Terminal groups can include, but are not limited to, alkyl groups such as a methyl group. Effective organosilicone compounds are believed to include, but are not limited to, trisiloxane ethoxylate surfactants or polyalkylene oxide modified heptamethyl trisiloxane.

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In certain embodiments, an organosilicone preparation that comprises an organosilicone compound comprising a trisiloxane head group is used in the methods and compositions provided herein. In certain embodiments, an organosilicone preparation that comprises an organosilicone compound comprising a heptamethyltrisiloxane head group is used in the methods and compositions provided herein. In certain embodiments, an organosilicone composition that comprises Compound I is used in the methods and compositions provided herein. In certain embodiments, an organosilicone composition that comprises Compound I is used in the methods and compositions provided herein. In certain embodiments of the methods and compositions provided herein, a composition that comprises a polynucleotide molecule and one or more effective organosilicone compound in the range of about 0.015 to about 2 percent by weight (wt percent) (e.g., about 0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04, 0.045, 0.05, 0.055, 0.06, 0.065, 0.07, 0.075, 0.08, 0.085, 0.09, 0.095, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.5 wt percent) is used or provided.

Compositions include but are not limited components that are one or more polynucleotides essentially identical to, or essentially complementary to a PDS gene sequence (promoter, intron, exon, 5′ untranslated region, 3′ untranslated region), a transfer agent that provides for the polynucleotide to enter a plant cell, a herbicide that complements the action of the polynucleotide, one or more additional herbicides that further enhance the herbicide activity of the composition or provide an additional mode of action different from the complementing herbicide, various salts and stabilizing agents that enhance the utility of the composition as an admixture of the components of the composition.

Methods include one or more applications of a polynucleotide composition and one or more applications of a permeability-enhancing agent for conditioning of a plant to permeation by polynucleotides. When the agent for conditioning to permeation is an organosilicone composition or compound contained therein, embodiments of the polynucleotide molecules are double-stranded RNA oligonucleotides, single-stranded RNA oligonucleotides, double-stranded RNA polynucleotides, single-stranded RNA polynucleotides, double-stranded DNA oligonucleotides, single-stranded DNA oligonucleotides, double-stranded DNA polynucleotides, single-stranded DNA polynucleotides, chemically modified RNA or DNA oligonucleotides or polynucleotides or mixtures thereof.

Compositions and methods are useful for modulating the expression of an endogenous PDS gene or transgenic PDS gene (for example, US Patent Publ. No. 20110098180) in a plant cell. In various embodiments, a PDS gene includes coding (protein-coding or translatable) sequence, non-coding (non-translatable) sequence, or both coding and non-coding sequence. Compositions can include polynucleotides and oligonucleotides designed to target multiple genes, or multiple segments of one or more genes. The target gene can include multiple consecutive segments of a target gene, multiple non-consecutive segments of a target gene, multiple alleles of a target gene, or multiple target genes from one or more species.

One aspect is a method for modulating expression of a PDS gene in a plant including (a) conditioning of a plant to permeation by polynucleotides and (b) treatment of the plant with the polynucleotide molecules, wherein the polynucleotide molecules include at least one segment of 18 or more contiguous nucleotides cloned from or otherwise identified from the target PDS gene in either anti-sense or sense orientation, whereby the polynucleotide molecules permeate the interior of the plant and induce modulation of the target gene. The conditioning and polynucleotide application can be performed separately or in a single step. When the conditioning and polynucleotide application are performed in separate steps, the conditioning can precede or can follow the polynucleotide application within minutes, hours, or days. In some embodiments more than one conditioning step or more than one polynucleotide molecule application can be performed on the same plant. In embodiments of the method, the segment can be cloned or identified from (a) coding (protein-encoding), (b) non-coding (promoter and other gene related molecules), or (c) both coding and non-coding parts of the target gene. Non-coding parts include DNA, such as promoter regions or the RNA transcribed by the DNA that provide RNA regulatory molecules, including but not limited to: introns, 5′ or 3′ untranslated regions, and microRNAs (miRNA), trans-acting siRNAs, natural anti-sense siRNAs, and other small RNAs with regulatory function or RNAs having structural or enzymatic function including but not limited to: ribozymes, ribosomal RNAs, t-RNAs, aptamers, and riboswitches.

All publications, patents and patent applications are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.

The following examples are included to demonstrate examples of certain preferred embodiments. It should be appreciated by those of skill in the art that the techniques disclosed in the examples that follow represent approaches the inventors have found function well in the practice, and thus can be considered to constitute examples of preferred modes for its practice. However, those of skill in the art should, in light of the present disclosure, appreciate that many changes can be made in the specific embodiments that are disclosed and still obtain a like or similar result without departing from the spirit and scope.

EXAMPLES
Example 1
Polynucleotides Related to the PDS Gene Sequences

The target PDS polynucleotide molecule was isolated from the genome of Abutilon theophrasti, Amaranthus chlorostachys, Amaranthus graecizans, Amaranthus palmeri, Amaranthus rudis, Amaranthus hybridus, Amaranthus lividus, Amaranthus spinosus, Amaranthus viridis, Ambrosia artemisiifolia, Ambrosia trifida, Commelina diffusa, Conyza candensis, Digitaria sanguinalis, Euphorbia heterophylla, Kochia scoparia, Lolium multiflorum. and include molecules related to the expression of a polypeptide identified as a PDS, that include regulatory molecules, cDNAs comprising coding and noncoding regions of a PDS gene and fragments thereof as shown in Table 1.

Polynucleotide molecules were extracted from these plant species by methods standard in the field, for example, total RNA is extracted using Trizol Reagent (Invitrogen Corp, Carlsbad, Calif. Cat. No. 15596-018), following the manufacturer's protocol or modifications thereof by those skilled in the art of polynucleotide extraction that may enhance recover or purity of the extracted RNA. Briefly, start with 1 gram of ground plant tissue for extraction. Prealiquot 10 milliliters (mL) Trizol reagent to 15 mL conical tubes. Add ground powder to tubes and shake to homogenize. Incubate the homogenized samples for 5 minutes (min) at room temperature (RT) and then add 3 mL of chloroform. Shakes tubes vigorously by hand for 15-30 seconds (sec) and incubate at RT for 3 min. Centrifuge the tubes at 7,000 revolutions per minute (rpm) for 10 min at 4 degrees C. Transfer the aqueous phase to a new 1.5 mL tube and add 1 volume of cold isopropanol. Incubate the samples for 20-30 min at RT and centrifuge at 10,000 rpm for 10 min at 4 degrees C. Wash pellet with Sigma-grade 80 percent ethanol. Remove the supernatant and briefly air-dry the pellet. Dissolve the RNA pellet in approximately 200 microliters of DEPC treated water. Heat briefly at 65 degrees C. to dissolve pellet and vortex or pipet to resuspend RNA pellet. Adjust RNA concentraiton to 1-2 microgram/microliter.

DNA was extracted using EZNA SP Plant DNA Mini kit (Omega Biotek, Norcross Ga., Cat#D5511) and Lysing Matrix E tubes (Q-Biogen, Cat#6914), following the manufacturer's protocol or modifications thereof by those skilled in the art of polynucleotide extraction that may enhance recover or purity of the extracted DNA. Briefly, aliquot ground tissue to a Lysing Matrix E tube on dry ice, add 800 μl Buffer SP1 to each sample, homogenize in a bead beater for 35-45 sec, incubate on ice for 45-60 sec, centrifuge at ≧14000 rpm for 1 min at RT, add 10 microliter RNase A to the lysate, incubate at 65° C. for 10 min, centrifuge for 1 min at RT, add 280 μl Buffer SP2 and vortex to mix, incubate the samples on ice for 5 min, centrifuge at ≧10,000 g for 10 min at RT, transfer the supernatant to a homogenizer column in a 2 ml collection tube, centrifuge at 10,000 g for 2 min at RT, transfer the cleared lysate into a 1.5 ml microfuge tube, add 1.5 volumes Buffer SP3 to the cleared lysate, vortex immediately to obtain a homogeneous mixture, transfer up to 650 μl supernatant to the Hi-Bind column, centrifuge at 10,000 g for 1 min, repeat, apply 100 μl 65° C. Elution Buffer to the column, centrifuge at 10,000 g for 5 min at RT.

Next-generation DNA sequencers, such as the 454-FLX (Roche, Branford, Conn.), the SOLiD (Applied Biosystems,), and the Genome Analyzer (HiSeq2000, Illumina, San Diego, Calif.) were used to provide polynucleotide sequence from the DNA and RNA extracted from the plant tissues. Raw sequence data is assembled into contigs. The contig sequence is used to identify trigger molecules that can be applied to the plant to enable regulation of the gene expression.

The target DNA sequence isolated from genomic (gDNA) and coding DNA (cDNA) from the various weedy plant species for the PDS gene and the assembled contigs as set forth in SEQ ID NOs 1-78 and Table 1. The EPSPS gene was isolated from dandelion (Taraxacum officinale) and a PDS3 gene promoter fragment (SEQ ID NO: 2138) was used as a target for testing trigger molecules.

Example 2
Polynucleotides Related to the Trigger Molecules

The gene sequences and fragments of Table 1 were divided into 200 polynucleotide (200-mer) lengths with 25 polynucleotide overlapping regions (SEQ ID NO:79-2010). These polynucleotides are tested to select the most efficacious trigger regions across the length of any target sequence. The trigger polynucleotides are constructed as sense or anti-sense ssDNA or ssRNA, dsRNA, or dsDNA, or dsDNA/RNA hybrids and combined with an organosilicone based transfer agent to provide a polynucleotide preparation. The polynucleotides are combined into sets of two to three polynucleotides per set, using 4-8 nmol of each polynucleotide. Each polynucleotide set is prepared with the transfer agent and applied to a plant or a field of plants in combination with a PDS inhibitor containing herbicide, or followed by a PDS inhibitor treatment one to three days after the polynucleotide application, to determine the effect on the plant's susceptibility to a PDS inhibitor. The effect is measured as stunting the growth and/or killing of the plant and is measured 8-14 days after treatment with the polynucleotide set and PDS inhibitor. The most efficacious sets are identified and the individual polynucleotides are tested in the same methods as the sets are and the most efficacious single 200-mer identified. The 200-mer sequence is divided into smaller sequences of 50-70-mer regions with 10-15 polynucleotide overlapping regions and the polynucleotides tested individually. The most efficacious 50-70-mer is further divided into smaller sequences of 25-mer regions with a 12 to 13 polynucleotide overlapping region and tested for efficacy in combination with PDS inhibitor treatment. By this method it is possible to identify an oligonucleotide or several oligonucleotides that are the most efficacious trigger molecule to effect plant sensitivity to a PDS inhibitor or modulation of a PDS gene expression. The modulation of PDS gene expression is determined by the detection of PDS siRNA molecules specific to a PDS gene or by an observation of a reduction in the amount of PDS RNA transcript produced relative to an untreated plant or by merely observing the anticipated phenotype of the application of the trigger with the PDS inhibitor containing herbicide. Detection of siRNA can be accomplished, for example, using kits such as mirVana (Ambion, Austin Tex.) and mirPremier (Sigma-Aldrich, St Louis, Mo.).

The target DNA sequence isolated from genomic (gDNA) and coding DNA (cDNA) from the various weedy plant species for the PDS gene and the assembled contigs as set forth in SEQ ID NOs 1-78 were divided into polynucleotide fragments as set forth in SEQ ID NOs 79-2010.

The gene sequences and fragments of Table 1 were compared and 21-mers of contiguous polynucleotides were identified that had homology across the various PDS gene sequences. The purpose is to identify trigger molecules that are useful as herbicidal molecules or in combination with a PDS inhibitor herbicide across a broad range of weed species. The sequences SEQ ID NOs 2011-2136 represent the 21-mers that were present in the PDS gene of at least eight of the weed species of Table 1. It is contemplated that additional 21-mers can be selected from the sequences of Table 1 that are specific for a single weed species or a few weeds species within a genus or trigger molecules that are at least 18 contiguous nucleotides, at least 19 contiguous nucleotides, at least 20 contiguous nucleotides or at least 21 contiguous nucleotides in length and at least 85 percent identical to a PDS gene sequence selected from the group consisting of SEQ ID NO:1-78 or fragment thereof.

By this method it is possible to identify an oligonucleotide or several oligonucleotides that are the most efficacious trigger molecule to effect plant sensitivity to PDS inhibitor or modulation of PDS gene expression. The modulation of PDS gene expression is determined by the detection of PDS siRNA molecules specific to PDS gene or by an observation of a reduction in the amount of PDS RNA transcript produced relative to an untreated plant or by merely observing the anticipated phenotype of the application of the trigger with the PDS inhibitor containing herbicide. Detection of siRNA can be accomplished, for example, using kits such as mirVana (Ambion, Austin Tex.) and mirPremier (Sigma-Aldrich, St Louis, Mo.).

Example 3
Methods Related to Treating Plants or Plant Parts with a Topical Mixture of the Trigger Molecules

Glyphosate-sensitive Palmer amaranth (A. palmeri R-22) plants were grown in the greenhouse (30/20 C day/night T; 14 hour photoperiod) in 4 inch square pots containing Sun Gro® Redi-Earth and 3.5 kg/cubic meter Osmocote® 14-14-14 fertilizer. Palmer amaranth plants at 5 to 10 cm in height were pre-treated with a mixture of oligonucleotides one of which was a SEQ ID NO: 2137 at 0.8 nmol comprising at least one oligonucleotide targeting PDS coding or noncoding regions, formulated in 10 millimolar sodium phosphate buffer (pH 6.8) containing 2% ammonium sulfate and 0.5% Silwet L-77. Plants were treated manually by pipetting 10 μL of polynucleotide solution on four fully expanded mature leaves, for a total of 40 microliters of solution per plant. Twenty-four and forty-eight hours later, the plants were treated with norflurazon (Solicam®, Syngenta, Greensboro, N.C.) at 675 g ai/ha, crop oil concentrate (COC) at 1% is added to the herbicide treatments. Four replications of each treatment was conducted. Plant height is determined just before ssDNA treatment and at intervals upto twelve days after herbicide treatments to determine effect of the oligonucleotide and herbicide treatments. The norflurazon and oligonucleotide treatment resulted in more injury to the plants than the norflurazon alone, see FIG. 1.

Treatment of dandelion (Taraxacum officinale) and prickly lettuce (Lactuca serriola) with a pool of antisense ssDNA trigger polynucleotides resulted in a strong response by the treated plant to the trigger polynucleotides without the addition of a herbicide. The treatment was conducted in sequential steps, the first step was the plants were treated with 0.1 percent Silwet L-77 and then treatment with the ssDNA trigger oligonucleotide pools (pool 1 and pool 2) in 0.01 percent Silwet L-77 and 5 mM sodium phosphate buffer (pH6.8). Pool 1 (SEQ ID NO: 2139-2144) and Pool 2 (SEQ ID NO: 2145-2150) both provide a strong growth inhibition in the plants to treatment with the polynucleotide relative to the plant not treated (control) with the polynucleotide. The result is illustrated in FIG. 2, the image was taken 38 days after treatment.

In another treatment of dandelion, 5 pools of 4 or 5 dsDNA oligonucleotides (homologous and complementary to the dandelion PDS3 gene promoter, PDS3P) each were mixed in a liquid solution (formulation) of 1 percent Silwet L-77 plus 2 percent ammonium sulfate plus 20 mM sodium phosphate buffer at 10 nm per oligonucleotide in 10 microliters droplets applied to four leaves of a treated plant with four replications per pool. Trigger pool PDS3P 1-5 contains SEQ ID NO: 2153-2157, PDS3P 6-10 contains SEQ ID NO: 2158-2162, PDS3P 11-15 contains SEQ ID NO: 2163-2167, PDS3P 16-20 contains SEQ ID NO: 2168-2172, PDS3P 21-24 contains SEQ ID NO: 2173-2176. The growth of the treated and control (formulation treated) were rated 14 days after the treatment relative to the untreated control. The growth of the treated plants were substantially reduced (47-66 percent, visual rating) relative to the control (10 percent) treated with the formulation without the oligonucleotides as shown in Table 2. In another treatment of dandelion, two long polynucleotide trigger molecules, SEQ ID NO: 2151 and SEQ ID NO: 2152 demonstrated an average in 4 replications of 15-40 percent growth reduction by visual rating 14 days after treatment, however, there was more variability in the replications of this test compared to tests where the shorter oligonucleotide triggers were used.

TABLE 2

Dandelion treated with dsDNA oligonucleotides to PDS3 promoter target

trigger

Trigger pools
type
REP 1
REP 2
REP 3
REP 4
AVG

PDS3P 1-5
dsDNA
50
50
50
50
50

PDS3P 6-10
dsDNA
55
65
60
50
57.5

PDS3P 11-15
dsDNA
50
50
50
40
47.5

PDS3P 16-20
dsDNA
75
60
60
50
61.25

PDS3P 21-24
dsDNA
70
70
60
65
66.25

Control
none
10
10
10
10
10

Example 4
A Method to Control Weeds in a Field

A method to control weeds in a field comprises the use of trigger polynucleotides that can modulate the expression of a PDS gene in one or more target weed plant species. An analysis of PDS gene sequences from seventeen plant species provided a collection of 2′-mer polynucleotides that can be used in compositions to affect the growth or develop or sensitivity to PDS inhibitor herbicide to control multiple weed species in a field. A composition containing 1 or 2 or 3 or 4 or more of the polynucleotides of (SEQ ID NOs 2011-2136) would enable broad activity of the composition against the multiple weed species that occur in a field environment.

The method includes creating a composition that comprises components that include at least one polynucleotide of SEQ ID NOs 2011-2136 or any other effective gene expression modulating polynucleotide essentially identical or essentially complementary to SEQ ID NO:1-78 or fragment thereof, a transfer agent that mobilizes the polynucleotide into a plant cell and a PDS inhibiting herbicide and optionally a polynucleotide that modulates the expression of an essential gene and optionally a herbicide that has a different mode of action relative to a PDS inhibitor. The polynucleotide of the composition includes a dsRNA, ssDNA or dsDNA or a combination thereof. A composition containing a polynucleotide can have a use rate of about 1 to 30 grams or more per acre depending on the size of the polynucleotide and the number of polynucleotides in the composition. The composition may include one or more additional herbicides as needed to provide effective multi-species weed control. A field of crop plants in need of weed plant control is treated by spray application of the composition. The composition can be provided as a tank mix, a sequential treatment of components (generally the polynucleotide followed by the herbicide), a simultaneous treatment or mixing of one or more of the components of the composition from separate containers. Treatment of the field can occur as often as needed to provide weed control and the components of the composition can be adjusted to target specific weed species or weed families.

TABLE 1

Weed species and PDS gene sequences

SEQ

ID NO
SPECIES
TYPE
LENGTH
SEQ

1

Abutilon

cDNA
1915
TTGAAGAAAATGAGTCTCTGTGGGAGTGTTTCTGC

theophrasti

TGTGCACTTAAACTTCCAAAGCAACACGATAAGCAT

GGGAAGTGTTTTAGCTTTTAGAAGCGGTGAATCCA

TGGGAAATTCCTTGAGAATTCCCTTAAAAAAGAGG

TCAAGTAAGGGTGCACGTCCTTTGCAGGTAGTTTG

CATAGATTATCCAAGGCCAGAGCTTGAGAGTACTG

CTAACTTTTTGGAGGCTGCTTCTCTATCTGCTTCTTT

TCGTTCTGCTCCCCGTCCAACTAAGCCATTGAAAGT

CATAATTGCTGGTGCAGGTTTGGGTGGTTTGTCAA

CTGCTAAGTATCTGGCGGATGCAGGTCATAAACCA

ATATTATTAGAAGCGAGAGATGTTCTAGGTGGAAA

GGTGGCTGCATGGAAAGATGATGATGGAGATTGG

TATGAGACAGGCTTACATATATTCTTTGGGGCTTAC

CCAAATGTGCAAAACTTGTTTGGTGAACTTGGCATC

AATGATCGGCTGCAATGGAAGGAGCATTCTATGAT

ATTTGCGATGCCAAATAAACCTGGAGAGTTCAGTC

GATTTGATTTTCCAGAAGTTCTACCTGCACCCTTAA

ATGGGATATGGGCCATTTTGAAGAACAATGAAATG

CTGACTTGGCCAGAGAAAGTGAAATTTGCAATAGG

ACTGCTACCCGCAATTGTTGGTGGACAAGCTTATGT

TGAGGCCCAAGATGGTTTATCTGTTAAAGAGTGGA

TGAGAAAGCAGGGGGTACCTGATCGTGTGACCGA

GGAGGTGTTTATTGCCATGTCAAAGGCTCTAAACTT

CATTAACCCAGATGAACTTTCAATGCAATGTATATT

GATTGCTTTGAATCGATTTCTTCAGGAGAAACATG

GATCAAAGATGGCATTCTTGGATGGCAACCCTCCA

GAGAGGCTTTGCATGCCAATCGTTAATCATATTGA

GTCATTAGGTGGTGAGGTCCGGCTTAACTCACGAA

TAAAGAAAATAGAGCTCAATGATGATGGAACTGTG

AGTAGTTTTCTTTTAACTAATGGCAGTACAATTGAA

GGAGATGCTTATGTAGTTGCAACTCCAGTTGATATC

TTCAAGTTACTTTTGCCTGAAGACTGGAGAGCGATT

TCTTACTTCAAGAAGTTAGAGAAATTAGTAGGAGT

TCCAGTTATCAATGTTCACATCTGGTTCGATAGGAA

ATTGAAGAACACCGCTGATAATCTTCTCTTCAGCAG

AAGTTCTCTTCTAAGTGTTTATGCCGACATGTCTGT

AACGTGTAAGGAATACTACAATCCAAACCAATCCA

TGTTGGAGTTGGTTTTTGCTCCGGCAGAAGAATGG

GTTGCACGTAGTGACTCAGAAATTATTGATGCTAC

AATGAAGGAACTTGCAAAGCTCTTTCCTGATGAAA

TATCTGCAGATCAGAGTAAAGCAAAAATCGTGAAG

TACCATGTCGTTAAAACACCAAGATCTGTATATAAA

ACTGTTCCGAATTGTGAACCCTGCCGCCCCTTGCAA

AGATCTCCGATACAAGGATTCTATCTAGCAGGTGA

TTACACAAAGCAAAAGTATTTAGCTTCAATGGAAG

GTGCTGTCCTCTCAGGGAAGCTTTGTGCACAGTCTA

TTGTACAGGATTACGAGTTGCTTAGCTACTTTGGGA

CAAAGAAGGTTGACAGTGGCAAGCATCAACTGATG

TCGTTTAAATCGAGGTAAACAGTTCACAAGTTACC

GAGGATCATCTGCTAATCCATTGTTTAAGGCCACTT

AGATTAGAGGTCTTTTTTCATTACATATGTATACTG

AATACCCCATATAAAAACCTGAAACTTGTGCAAAG

ATAGCATCACAAACTGTGTGTAAAATTCTTTTGATG

GAATCTACATGATCTTCAATATCCCGTTAAAAGAAA

AAA

2

Amaranthus

cDNA
414
GATTCAGTTGGACCAGAGTGGAAGCGTGAAGAGT

chlorostachys

TTTTTGCTAAATAACGGGAGGGAAATACGAGGAGA

TGCCTATGTTTTTGCCACCCCAGTTGACATCTTGAA

GCTGTTACTACCCGATACTTGGAAGGAAATCTCATA

CTTCAAAAAGCTTGAGAAATTAGTGGGCGTTCCTG

TGATTAATGTTCACATATGGTTTGACAGAAAATTAA

AGAATACATATGACCATCTACTCTTCAGCAGGAGTC

CTCTTTTGAGTGTCTACGCTGATATGTCGGAGACAT

GCAAGGAATATAAGGATCCTAATAGATCCATGCTG

GAGCTGGTTTTTGCACCCGCGGAGGAATGGATTTC

ACGAAGCGACACTGATATTATCGAGGCAACAATGA

AAGAGCTTGCCAAGCTTTTCCCGGG

3

Amaranthus

cDNA
2020
GAACAAACTTTGTGGGGGGGTGGTGAAAAATGAG

graecizans

TCATTTTGGATATGCTTGTGCTACTCAATCCACATC

AAGATATGTTCTTTTAGGAAATTCAAATAACCCCAC

TTCAGTTTCATCTATTGGAAGTGATTTTTTGGGTCA

TTCTGTGAGAAATTTCAGTGTTAGTAAAGTTTATGG

TGGAAAGCAAAGAAATGGGCACTGCCCTTTAAAGG

TTGTTTGTATAGATTATCCTAGGCCAGAGCTTGAAA

GTACATCCAATTTCTTGGAAGCCGCCTACTTATCTT

CTACTTTTCGGAATTCGCCTCGTCCTCAGAAGCCAT

TAGAAGTTGTAATTGCCGGAGCAGGTTTGGCTGGT

CTATCCACGGCAAAGTATTTAGCTGATGCAGGTCA

CAAACCCATATTGCTGGAAGCACGAGATGTTTTAG

GAGGAAAGGTTGCAGCATGGAAGGATGAGGATGG

TGACTGGTATGAGACTGGGCTACATATATTCTTTGG

GGCATATCCAAATATCCAAAATCTATTTGGAGAACT

TGGTATAAATGACCGATTGCAATGGAAGGAGCACT

CTATGATTTTTGCAATGCCTAGCAAACCCGGTGAAT

TCAGTCGCTTTGATTTTCTCGAAGTCCTGCCTGCAC

CATTGAATGGCATATGGGCAATCCTAAGGAATAAT

GAAATGCTAACCTGGCCAGAAAAAATCAAGTTTGC

CATTGGCTTGTTGCCTGCTATGGCTGGCGGACAGT

CATATGTTGAGGCACAAGATGGTTTGAGTGTCCAA

GAGTGGATGAGAAAGCAAGGAGTACCCGATCGTG

TAACTGATGAAGTATTTATTGCCATGTCAAAGGCAC

TGAACTTCATAAATCCCGATGAACTTTCGATGCAGT

GCATCTTGATAGCTCTTAACCGATTCCTACAGGAGA

AACATGGTTCTAAGATGGCCTTTCTAGACGGAAAC

CCTCCAGAGAGGCTTTGCATGCCTATTGTTAAGCAC

ATTGAGTCACTAGGTGGTGAAGTTCAACTTAACTCT

CGTATACAAAAGATTGAGTTGGATCAGAGTGGAAG

CGTGAAGAGTTTTTTGCTAAATAACGGGAGGGAAA

TACGAGGAGATGCCTATGTTTTTGCCACCCCAGTTG

ACATCTTGAAGCTGTTACTACCTGATACTTGGAAGG

AAATCTCATACTTCAAAAAGCTTGAGAAATTAGTG

GGCGTTCCTGTGATTAATGTTCACATATGGTTTGAC

AGAAAATTAAAGAATACGTATGACCATCTACTCTTC

AGCAGGAGTCCTCTTTTGAGTGTCTATGCTGATATG

TCAGAGACATGCAAGGAGTATAAGGATCCAAATAG

ATCCATGCTGGAACTTGTTTTTGCACCCGCGGAGG

AATGGATTTCACGAAGCGACACTGATATTATCGAG

GCAACAATGAATGAGCTTGCCAAGCTTTTCCCGGA

TGAAATCGCTGCTGACGGGAGCAAGGCCAAGATCC

TTAAATATCATGTCGTCAAAACTCCAAGGTCGGTTT

ATAAGACAGTACCGGATTGTGAGCCTTGTCGGCCG

CTGCAAAGATCACCAATAGAGGGATTCTATTTAGC

TGGTGATTACACAAAACAAAAATATTTGGCTTCTAT

GGAAGGTGCTGTCTTATCTGGGAAGCTTTGTGCAC

AGGCTATTGTACAGGATTATGATCTGCTGAGTTCTC

GAGCACAAAGAGAATTGGCGGCGAGAAGCAATGT

ATAACCCTGGATTGCTTCGACATCCGCCATTGATTT

TCATTCGAGATCAGGATTGGGAATCTGATCAGTCA

TCGAATAATGATCGGCTGTAAACAAAATTATGGGG

GTTGCATACCGGTGCTCGTCAAGTTGACGTATAAA

TTCTCCAGAATGAAGATTTATTTGTAATGATATCTA

TTAAATATTTTAATTTATTTTCTGATAGAAATATGTA

TAGCTCACTTCTAGGGAATAAACATGTATGTGGAC

CAGTTAACTTGATTGAAATGTAAGTATCAACTTTGT

4

Amaranthus

cDNA
1938
CTAAATTCCAACAATTTGGTCCATTTTTCTTGTTCTT

hybridus

TCAGTTTCACATACCCTCTTATCAATCTATATCCAAA

ACTATTTCATTTTCCAAACTCTTTTAAACCCAAAAAT

CAAAACTTTTGATTGAAGAACAAACTTTGGGGTTTT

GGAAAATGAGTCATTTTGGATATGCTTGTGCTACTC

AATCCACATCAAGATATGTTCTTTTAGGAAATTCAA

ATAACCACACTTCAATTTCATCTATTGGAAGTGATT

TTTTGGGTCATTCTGTGAGAAATTTCAGTTTTAGTA

AAGTTTATGGGGGAAAGCAAAGAAATGGGCACTG

CCCTTTAAAGGTTGTTTGTATGGATTATCCTAGGCC

TGAGCTTGAAAGTACATCCAATTTCTTGGAAGCTGC

CTACTTATCTTCTACTTTTCGGAATTCGCCTCGTCCT

CAGAAGCCATTAGAAGTTGTAATTGCTGGAGCAGG

TTTGGCTGGTCTATCCACGGCAAAGTATTTAGCTGA

TGCAGGTCACAAACCCATATTGCTGGAAGCACGAG

ATGTTTTAGGAGGAAAGGTTGCAGCGTGGAAGGA

TGAGGATGGTGACTGGTACGAGACTGGGCTACAT

ATATTCTTTGGGGCTTATCCAAATATCCAAAATCTA

TTTGGAGAACTTGGTATAAATGATCGATTGCAATG

GAAGGAGCACTCTATGATTTTTGCAATGCCTAGCA

AGCCTGGTGAATTCAGTCGCTTTGATTTTCCCGAAG

TCCTGCCTGCACCATTAAATGGCATATGGGCAATCC

TAAGGAATAATGAAATGCTAACCTGGCCAGAAAAA

ATCAAGTTTGCCATTGGCTTGTTGCCTGCTATGGCT

GGCGGACAGTCATATGTTGAAGCACAAGACGGTTT

GAGTGTCCAAGAGTGGATGAGAAAACAAGGAGTA

CCCGATCGTGTAACTGATGAAGTATTTATTGCCATG

TCAAAGGCACTGAACTTCATAAATCCCGATGAACTT

TCAATGCAGTGCATCTTGATTGCTCTGAACCGATTC

CTGCAGGAGAAACATGGTTCTAAGATGGCCTTCCT

AGACGGAAACCCTCCAGAGAGGCTGTGCATGCCTA

TTGTTAAGCACATTGAGTCACTAGGTGGTGAAGTT

AAACTTAACTCTCGTATACAAAAGATTCAGTTGGAT

CAGAGTGGAAGCGTGAAGAGTTTTTTGCTAAATAA

CGGGAGGGAAATACGAGGAGATGCCTATGTTTTTG

CCACCCCAGTTGACATCTTGAAGCTGTTACTACCCG

ATACTTGGAAGGAAATCTCATACTTCAAAAAGCTTG

AAAAATTAGTGGGCGTTCCTGTGATTAATGTTCACA

TATGGTTTGACAGAAAATTAAAGAATACATATGAC

CATTTACTCTTCAGCAGAAGTCCTCTTTTGAGTGTCT

ATGCTGATATGTCGGAGACATGCAAGGAATATAAG

GATCCTAATAGATCCATGCTGGAACTGGTTTTTGCA

CCCGCGGAGGAATGGATTTCACGTAGCGACACTGA

TATTATAGAGGCAACAATGAAAGAGCTTGCCAAGC

TTTTCCCCGATGAAATTGCTGCCGATGGGAGCAAG

GCCAAGATCCTCAAATATCATGTCGTCAAAACTCCA

AGGTCGGTTTATAAGACTGTACCGGATTGTGAACC

TTGTCGGCCGCTGCAAAGATCACCAATAGAGGGTT

TCTATTTAGCTGGTGATTACACAAAACAAAAATATT

TGGCTTCTATGGAAGGTGCTGTCTTATCTGGGAAG

CTTTGTGCTCAGGCTATTGTACAGGATTATGATCTG

CTGAGTTCTCGAGCACAAAGAGAATTGGCGGCGAC

AAGCAATGTATAAACCTGGATTGCTTTGACATCCGC

CATTGATTTTCATTCGAGATCTGGATTGGGAATCTG

ATCAGTCATCGAAAAAT

5

Amaranthus

cDNA
1947
GGGTTTTGGAAAATGAGTCATTTTGGATATGCTTGT

lividus

GCTACTCAATCCACATCAAGATATGTTCTTTTGGGA

AATTCAAATAACCCCACTTCAATTTCATCTATTGGA

AGTGATTTTTTGGGTCATTCTGTGAGAAATTTCAGT

GTTAGTAAAGTTTATGGGGCAAAGCAAAGAAATG

GGCACTGCCCTTTAAAGGTTGTTTGTATAGATTATC

CTAGGCCTGAGCTTGAAAGTACATCCAATTTCTTGG

AAGCCGCCTACTTATCTTCTACTTTTCGGAATTCGCC

TCGTCCTCAGAAGCCATTAGAAGTTGTAATTGCCG

GAGCAGGTTTGGCTGGTCTATCCACAGCAAAGTAT

TTAGCTGATGCAGGTCACAAACCCATATTGTTGGA

AGCACGAGATGTTTTAGGAGGAAAGGTTGCAGCG

TGGAAGGATGAGGATGGTGACTGGTATGAGACTG

GGCTACATATATTCTTTGGGGCATATCCAAATATCC

AAAATCTATTTGGAGAACTTGGTATAAATGACCGA

CTGCAATGGAAGGAGCACTCTATGATTTTTGCAAT

GCCTAGCAAGCCCGGTGAATTCAGTCGCTTTGATTT

TCCAGAAATCCTGCCTGCACCATTAAATGGCATATG

GGCAATCCTAAGGAATAATGAAATGCTAACCTGGC

CAGAAAAAATCAAGTTTGCCATTGGCTTGTTGCCTG

CTATGGCGGGCGGACAGTCATATGTTGAAGCACAA

GATGGTTTGAGTGTTCAAGAGTGGATGAGAAAAC

AAGGAGTACCTGATCGTGTAACTGATGAAGTGTTT

ATTGCCATGTCAAAGGCACTGAACTTCATAAATCCC

GATGAACTTTCAATGCAGTGCATCTTGATTGCTCTG

AACCGATTCCTGCAGGAGAAACATGGTTCTAAGAT

GGCCTTCCTAGACGGAAACCCTCCAGAGAGGCTGT

GCATGCCTATTGTTAAGCACATCGAGTCACTAGGT

GGTGAAGTTAAACTTAACTCTCGGATACAAAAGAT

TCAGTTGGACCAGAGTGGAAGCGTGAAGAGTTTTT

GCTAAATAACGGGAGGGAAATACGAGGAGATGCC

TATGTTTTGCCACCCCAGTTGACATCTTGAAGCTGT

TACTACCCGATACTTGGAAGGAAATCTCATACTTCA

AAAAGCTTGAGAAATTAGTGGGCGTTCCTGTGATT

AATGTTCACATATGGTTTGACAGAAAATTAAAGAA

TACATATGACCATCTACTCTTCAGCAGGAGTCCTCT

TTTGAGTGTCTACGCTGATATGTCGGAGACATGCA

AGGAATATAAGGATCCTAATAGATCCATGCTGGAA

CTGGTTTTTGCACCCGCGGAGGAATGGATTTCACG

AAGCGACACTGATATTATCGAGGCAACAATGAAAG

AGCTTGCCAAGCTTTTCCCGGATGAAATCGCTGCC

GATGGAAGCAAGGCCAAGATCCTTAAGTATCATGT

TGTGAAAACACCAAGGTCGGTTTATAAGACTGTAC

CGGATTGTGAACCTTGTCGGCCGCTGCAAAGATCA

CCAATAGAGGGTTTCTATTTAGCTGGTGATTACACA

AAACAAAATATTTGGCTTCTATGGAAGGTGCTGTCT

TATCTGGGAAGCTTTGTGCACAGGCTATCGTACAG

GATTATGATCTGCTGAGTTCTCGAGCACAAAGAGA

ATTGGCGGCGACAAGCAATGTATAACCCTAAATTG

CTTCGACATCCGCCATCGACTTTCATTCGAGATCTG

GATTGGGAATCTGATCATCGAATAATGATCAGCTG

TAAAGAAAATTGTGGGGGTTGCATACTGGTGCTGT

TCAAGTTCTTGATGTACAAATTCTCCTGAAAGAAGA

TTTATTTGTAATGATATATCAATTGATAGAAATATA

TATAGCTTACTTCTAGGGAATTATGTATATGCACCA

TTTA

6

Amaranthus

cDNA
2117
CCCTCTTATCAATCTATATCCAAAACTATTTCATTTT

palmeri

CCAAACTTTTTTAAACCCAAAAATCAAAACTTTTGA

TTGAAGAACAAACTTTGGGGGTTTTGGAAAATGAG

TCATTTTGGATATGCTTGTGCTACTCAATCCACATC

AAGATATGTTCTTTTAGGAAATTCAAATAACCCCAC

TTCAATTTCATCTATTGGAAGTGATTTTTTGGGTCAT

TCTGTGAGAAATTTCAGTGTTAGTAAAGTTTATGG

GGAAAGCAAAGAAATGGGCATTGCCCTTTAAAGGT

TGTTTGTATAGATTATCCTAGGCCAGAGCTTGAAA

GTACATCCAATTTCTTGGAAGCCGCCTACTTATCTT

CTACTTTTCGGAATTCGCCTCGTCCTCAGAAGCCAT

TAGAAGTTGTAATTGCTGGAGCAGGTTTGGCTGGT

TTATCCACGGCAAAGTATTTAGCTGATGCAGGTCA

CAAACCCATATTGTTGGAAGCACGAGATGTTTTAG

GAGGAAAGGTTGCAGCGTGGAAGGATGAGGATG

GTGACTGGTATGAGACTGGGCTACATATATTCTTTG

GGGCATATCCAAATGTCCAAAATCTATTTGGAGAA

CTTGGTATAAATGACCGACTGCAATGGAAGGAGCA

CTCTATGATTTTTGCAATGCCAGCAAGCCCGGTGAA

TTCAGTCGCTTTGATTTTCCCGAAATCCTGCCTGCA

CCATTAAATGGCATATGGGCAATCCTAAGGAATAA

TGAAATGCTAACCTGGCCAGAAAAAATCAAGTTTG

CCATTGGCTTGTTGCCTGCTATGGCGGGCGGACAG

TCATATGTTGAAGCACAAGATGGTTTGAGTGTCCA

AGAGTGGATGAGAAAACAAGGAGTACCCGATCGT

GTAACTGATGAAGTGTTTATTGCCATGTCAAAGGC

ACTGAACTTCATAAATCCCGATGAACTTTCAATGCA

GTGCATCTTGATTGCTCTGAACCGATTCCTGCAGGA

GAAACATGGTTCTAAGATGGCCTTCCTAGACGGAA

ACCCTCCAGAGAGGCTGTGCATGCCTATTGTTAAG

CACATCGAGTCACTAGGTGGTGAAGTTAAACTTAA

CTCTCGTATACAAAAGATTCAGTTGGACCAGAGTG

GAAGCGTGAAGAGTTTTTTGCTAAATAACGGGAGG

GAAATACGAGGAGATGCCTATGTTTTTGCCACCCC

AGTTGACATCTTGAAGCTGTTACTACCCGATACTTG

GAAGGAAATCTCATACTTCAAAAAGCTTGAGAAAT

TAGTGGGCGTTCCTGTGATTAATGTTCACATATGGT

TTGACAGAAAATTAAAGAATACATATGACCATCTAC

TCTTCAGCAGGAGTCCTCTTTTGAGTGTCTATGCTG

ATATGTCGGAGACATGCAAGGAATATAAGGATCCA

AATAGATCCATGCTGGAACTGGTTTTTGCACCCGC

GGAGGAATGGATTTCACGAAGCGACACTGATATTA

TGAGGCAACAATGAAAGAGCTTGCCAAGCTTTTCC

CGGATGAAATCGCTGCCGATGGAAGCAAGGCCAA

GATCCTCAAATATCATGTCGTCAAAACTCCAAGGTC

GGTTTATAAGACTGTACCGGATTGTGAACCTTGTC

GGCCGCTGCAAAGATCACCAATAGAGGGTTTCTAT

TTAGCTGGTGATTACACAAAACAAAAATATTTGGCT

TCTATGGAAGGTGCTGTCTTATCTGGGAAGCTTTGT

GCACAGGCTATCGTACAGGATTATGATCTGCTGAG

TTCTCGAGCACAAAGAGAATTGGCGGCGACAAGCA

ATGTATAACCCTAAATTGCTTCGACATCCGCCATCG

ATTTTCATTCGAGATTTGGATTGGGAATCTAATCAT

CGAATAATGATTAGATGTAAACAAAATTATGGGGG

TTGCATACTGGTGTTCTTCAAGTTCTTGATGTATAA

ATTCTCCAGAAAGAAGATTTATTTGTAATGATATAT

CAATTGATAGAAATATGTATAGCTTACTTCTAGGGA

ATTATGTATGTGCACCATTTGTAACTTGATTGAAAT

GTAAGTATCAACTTGGTCTCTTGATTGAAATGTAAG

TATCAACATCTGTCTCTTATACACATCT

7

Amaranthus

Genomic
14098
TTGTGACATTTTTCCACACAACATGTGATACCTCCA

palmeri

GATTTAGCTTGAAAAGANNTTGATAGACTACTCAT

ATCAACAAGGTGCATCTTCTTTTCATGAGAGCCCAT

TTGCTAAGAATTCCACAGTTAAGCGTGCTTCATGGA

GAGCAATCTTAGGATGAGTGACCTTCGAGGAAGTT

TTCCTGGGTGCGCACGGGTGAGGCCAAAGTGCGTT

AAAAAGACTTGTGTTGGTCTGTGGGGCTTGTCTAC

AGTCTCCATGAGTAGTCACCGGCGGTACGAGAGGC

CGGGGTGTTACATAAACAGACTCAAAGGCGCTAAG

CCAAGTAGCCAATAGCAACATGTGTGGCCTGCGGA

CAGTCACAAAAACACACAATTTCTTATTTTTACTCTC

TTTTATCTCTTTTAGGCTTTAGCCATCAACAATAAAA

CAACATGATAAAGCAATTCATTTACTGCTAAATTCC

AACAATTTGGTCCCTTTTTCCTGTTCTTTCAGTTTCA

CATACCCTCTTATCAATCTATATCCAAAACTATTTCA

TTTTCCAAACTCTTTTAAACCCAAAAATCAAAACTTT

TGATTGAAGAACAAACTTTGGGGGTTTTGGAAAAT

GAGTCATTTTGGATATGCTTGTGCTACTCAATCCAC

ATCAAGATATGTTCTTTTAGGAAATTCAAATAACCC

CACTTCAATTTCATCTATTGGAAGTGATTTTTTGGG

TCATTCTGTGAGAAATTTCAGTGTTAGTAAAGTTTA

TGGAGGAAAGCAAAGAAATGGGCATTGCCCTTTAA

AGGTTTTCTGCCTTTTTTTTTTTTTTGATGATTTGATT

TTCTGGGTAGGGATAAATGATAAAGATTGATTCAT

TTTTTTTAAATGAATAATTTGTTTTTTTGTATGATGC

AGGTTGTTTGTATAGATTATCCTAGGCCAGAGCTTG

AAAGTACATCCAATTTCTTGGAAGCCGCCTACTTAT

CTTCTACTTTTCGGAATTCGCCTCGTCCTCAGAAGC

CATTAGAAGTTGTAATTGCTGGAGCAGGTGAGTGG

AAGGGTTCTTTACCTATTCTGTTGATTAGGGTCTTG

TTGTGTTGCTTTTTGCTTTGCCAAATTGGATGCTGTT

CTTGATTTTCTGGAGCTTTGGGCAAAATAGAAGCA

AAATTGAAAGCTAATTGAGTCAATTGAGATGTTTTT

GAGAAATCATTTATTGGCCGTTACTGTTTATTAGAG

AAAAAATATGGGTCAAGAAACGAAAAGATAATGG

AAAAACTACTTATAGGTGTCTTTTTTGATCATGAAT

CATGATGGATATATATGGTGTCAACTATCAAGACT

GCCATATAACTAATGTAGTATGCTTCCTTAAGGGGT

GGTGAAGAATAGACGTGTGGATGAGAAAATTGCT

GGGAATTTCCTATGCTTATGTAGAATGAGCTTCCTC

TTGTTGACATTAGTGAAAAGTGAAAAATTGGTGTA

TGAGTTTGCTTGATCGCTTTTGTGAGTGCTTCATTG

TCCGTTCCACACCTAGGTTATGTTGTAGGGTTGCAA

TATGTTAAATTGTTAGTGACGGCTGTCGTATAACAT

TATTGTATCTTATGCCATGGGCCAAATTTACCCCTA

TTCAACGACGCCATGCAGACCTAGGTGTAGTGAAA

AGTATGCAAGGGTTAATTGGACATCAAGCATGGCG

CCATGTTGTTTGAGTGTGGCAAAAAGACTTTACGCT

ACACCTCTAGACCAGTTAAGTATGTAAAGGGTGTT

GGGTCACCGCTCTAAAGTGGTGTGTCACATTTTATC

GAATTCGAGGATAAGCTGATCGTGGTATCAAGTGA

GAAAGAACGCAATATAGTGGAATTAGAAAGTTAA

GTAATAAGAAAAAAGAAAAAAATGATATCTAGCTT

TAGGAAAATCTATCAGTGAGGAGAATATTGCAAAA

TACGTGGAAATTAAAACCAAGACAAAGCTAGCGAT

ATATGAGACAAAGTTAAAAATGTACAAAGAAATAT

ACGATAAGTTGACTCGAAAGAAGAGGATAACGATC

TTTATAGGATAGCCTAAAGGAGACAAATGATTATA

AACGATACTAGTTGAATGAACTATGAAGAGTGTCT

TAACCAAGCAAATATTGTTTAGAAATAAATTCAAAA

CTTTTTAATTCTTCAAATATGAACATGAGAACTGAC

TTCTCATTCTTTATTTTACTTCAAGGTTTGGCTGGTC

TATCCACGGCAAAGTATTTAGCTGATGCAGGTCAC

AAACCCATATTGTTGGAAGCACGAGATGTTTTAGG

AGGAAAGGTGTGTGCTATACGTTTCTCGTAGCTTAT

GAAACAAATTCATCGTGCTTATTCTCTTATTAGTTTA

TTTCAGACTATCAGATCATTTTTGAACTTTTTCCTCC

CTCTGTTCGGCTGTATTATTATATATGTGCAGCATG

ATTAAAAAATGGGTGCATTAACATATATGAAGTTTT

TTTTTTTTATCAAGGCGAGATTTTGTCATCCAAAAA

CTTTACTTCTGAACGTGCTGTATGATCCTGTTTCTGT

ATCTTCATTTGCTGGGATTTTCTCGAGGTTCCTGAC

TGCTTTCAGTTATTGTAGTTACCCATCCTGCATAAAT

TTGAGTTTACAGTTATTGTAATGAAAATAAATCGGC

TAATTATATCCTCGTCACAGTATGATGAATCTTGGG

CTAGTAAGAAAATGAGGTAGGAGGAATAATTATG

GTTAGTTTGATAATATGTGCCAAGAGAAATATTGT

AGTGTAAAGTTTCATTGTATTTCTTCCCGTGCTTATA

ATTTTTGCTCCACAGGTTGCAGCGTGGAAGGATGA

GGATGGTGACTGGTATGAGACTGGGCTACATATAT

TCTGTGAGTGATCTTCTAATTTTCTGCTTAATTGGCC

AGTTACCCATGTTCTTACAATGCGCTCTCTAGTCGT

GTTTATTGGAAAATCGATGTACTGAACATCTTCATA

TTTTCTTGAAGTTGGGGCATATCCAAATATCCAAAA

TCTATTTGGAGAACTTGGTATAAATGACCGACTGC

AATGGAAGGAGCACTCTATGATTTTTGCAATGCCT

AGCAAGCCCGGTGAATTCAGTCGCTTTGATTTTCCC

GAAATCCTGCCTGCACCATTAAATGGTTAGTATATC

GGTGATAACTGCCAAATTACTTGATGCAATGCAGT

ACCTTGTTAAGTACTTTGGATGTGACTCCACCTATA

ATACTTGCTATAATCTTCAATTTATTTCTCTTTCCTAC

ATTAGAAACTATAAGTATCCCGCTAAAGGACATGA

CCCCACTTACAAAGTTACAATACCCCATTAAAATAC

CCACTCACCCACTTTTTTTAATCGGTGTACCATCCGC

CCGAGGAGCAATCTCGAGGGGACAGCAGAGTACT

ACTTTAGTGTTATTGTGATGAAATAGGTACCTGCAT

CATATCTCATGTCCTGTGGATACCCATAAATGAACG

AAAAATTTCATTTTTATACGTATTATCCTGCTTTAGA

AGCTTGGAATATCATTGAACTTTTTTAATGTCCCAA

CATGAAAACAATCTGCATCTTGGTCTGTTTGCTACT

CCTAAATCCTAATGAGTCGGGCTGATTTATGTCTTT

GATGCTTTTGATCGTGTTTCGCAGGCATATGGGCA

ATCCTAAGGAATAATGAAATGCTAACCTGGCCAGA

AAAAATCAAGTTTGCCATTGGCTTGTTGCCTGCTAT

GGCAGGCGGACAGTCATATGTTGAAGCACAAGAT

GGTTTGAGTGTCCAAGAGTGGATGAGAAAACAAG

TAGGAGCAGACTTTCGTTTCAGATTTTCCTCATTTT

GTTAATGGTTCTAGACTTCTAGCTGTAAACTTTGAC

TTTGTTGGGACGTCAATGCTGAAATTTTGTTTGTGC

ATTAATGCAGGGAGTACCCGATCGTGTAACTGATG

ATGTGTTTATTGCCATGTCAAAGGCACTGAACTTCA

TAAATCCTGATGAACTTTCAATGCAGTGCATCTTGA

TTGCTCTGAACCGATTCCTGCAGGCATGACTGCCTT

TCATTTTCTGCTTTAAATTTTTGGTTTTGTACGATAC

TTCTTAGTGCTTGTTTTTGCGACTATTCTCGAGTAAA

TAGGGGATATAAAATGACCGTGCTGTTTTTCATAA

ACTGACCTTGGGTAATGTATATCAACAGGAGAAAC

ATGGTTCTAAGATGGCCTTCCTAGACGGAAACCCT

CCAGAGAGGCTGTGCATGCCTATTGTTAAGCACAT

CGAGTCACTAGGTGGTGAAGTTAAACTAAATTCTC

GTATACAAAAGATTCAGTTGGACCAGAGTGGAAGC

GTGAAGAGTTTTTTGCTAAATAACGGGAGGGAAAT

ACGAGGAGATGCCTATGTTTTTGCCACCCCAGGTTT

TCTTCTCTCCCTTTTTTTACCATTAGTTCTCTATCAGA

CTCCGTAAAAGCTAGAGTAAAGAAAATGAAGATTC

TATTACAGAAATGGACACACTGTAAAGCTTAATTA

GTTTTGATCTTGGGCAAAGCATTTGTGTTTCCAAAT

TTGTTAATGGTTATTATTTAAATAGAACACTTATGTT

TGTGATGGGTAACAAACTAACAATAGGTCAAGCGT

TGAGCCAAAGTGTTATAACAATGATTATATAGTGT

ATATCATAGTGTAAAATTGCGGTAAATTGTGGTAA

TGGACGCAATCACAGTGTCGGGAGTGATTCGGTAT

CATAACGCCTAAATATCGGTCGAAACCATAAGCTTT

GAAACGGCCCAAAACACGGTTTTTTTTAAAAACTTT

ACGACGCGAGAAATATCGTTTTGTTTATTTTGAAAA

CCTTTACGAAGCGACGATGCGATGCAGCCTTGTTTT

AACTCTATAGTGTACATAGGAATATACAATTAAGCA

AATAGTCGTAAGTGATATCTCAAAAGGGACAAGTG

TGAAATAGGCTAAAGAGTTGAATTAATTGTGGGAT

TGACAATTGTTTCATCACTGGTCCTCTATTGCTTTCC

TTGGTAAAATGTTGCATACTTGTTTATTGATTTACA

CTACATATAATTAGTTCTGTAGAATATGTTCTTGAG

TCAAAGCATGGGTCGATGTTTGAGGTTGATGTTGG

ATTTGCTTGGGCAAGCAATTACGAATATCTTGGTTT

AAGGAACCCATGAAAATGGAGCAGCTTGCAACGA

AAACAAAGCCCAGTTGAAAGCCTGCTCGGGTGAGC

AGCATCGCGTTGGGGCCAGCATGATGAGCTGTTCA

AACACAGAAGTTACTGGAGTGCTAGTGCTCTGGCA

AGCAAGCACAGCGCAGCTTACTTTTCTTTAATTTTT

GATTCTATCTAGAATTCTAACTAAACCCTAATGCTT

ACGATTGATTAGTATAATTAAAACCCATAAAGTGA

ATGAGTTGTTCAAATACTTGACAATTGACATTATTT

GAGTGGTCGTGGATGTAGTGTTGTAACAAAATTGT

CACTTATGAGTTAGGACCATATCCTTGCGAAGGTG

GAGATACACTTGGTAGAATACGGTGAAAAGTATCA

CCTTTCCATAGATAGTATAGCGTTATAAGTGAATTT

ATTATATTGTGCTGTCATATCAGTGTAACATAATTT

GTAGCTAATCCGCTTTTTGAATACGGAATTCGCTCG

AAATTGTTGAAAAATAACCCAAGACCGACCATATTT

TGCTTTTTTCGGTTTGCGATTCGCAGGGAGATTAGA

GAACCATGTAACATTGTATTTTGATATAATTTTTGA

ATTTCATTGTCAGTTGACATCTTGAAGCTGTTACTA

CCCGATACTTGGAAGGAAATCTCATACTTCAAAAA

GCTTGAGAAATTAGTGGGCGTTCCTGTGATTAATG

TTCACATATGGTTAGTTAATTCTTCATTCTATATTAA

ATTTACTTGTTAGGTTTTATACCTAATCAACTGCTTT

TAGTTTTGACATTTTGTCCGACAATAAGTGGACGTT

TCTGTTTTGTTGCGTTTTGTGAATTTCTTTTGATTAC

AGGGGCTAATTATATAATAATGCTTCATGCAGGTTT

GACAGAAAATTAAAGAATACATATGACCATCTACT

CTTCAGCAGGTAGTATTTCGTTTCTTTAATCATCCTA

TTTCTCTTTCGTAACTTAAATAATCTCGTTCTTCCCCT

TCCCTCCTTCACTTCAACACTTGTTTCAATTCTTCATT

TTTGGTCGTAGTAAAAACTGATGAATATTTGACAA

GAGTCGCATCATAAGTAATATGAACATTGGAGGAG

TGACAATCATCATCTATGAAGTATAAACTAAGATTC

TTTGAAGAAGGGGAAAGTTTAAGTGAAAATTTTCT

TTCCATTGGGAAATAAGTCTTTTGATTAACGTCTTG

AATAGATGAAGGATGCGAATTTTTGGATTCAAATG

AAGAGAAACGTTTTATGTGATCTAGTTGCGAGTCG

ATGGTGCCTTGAATTTCTTCAAAATTGAGCATTTTG

TTAATGTTCGCTTTATTTTTGCACTTTCATGTCCTTTT

CTTAAAGTTTTATATGGCTATACATTCTCAATTTAG

GGCGACCTCGATGCTTAAACCTTTACAAACACACAT

CATATAAGAATGAGAGTGTTAAAATTTACCTCTTAA

TCTCAGTATAAAGTGTCTCCTTTACTTTTGCACAAAT

TTTAGGAACGTGTAAGTTAGGATACAAATTGAAGT

TAGGGAATCTTGTAGGGCTCATAAAAAATGACAAT

CACAAATAACTTTCTAAATATCGAAATGGGTCACTT

GTGGTGAACTGATCCAATATGAAAATTAGACACTT

GTGCTAAGATGGAGCAAGTATTATAACTTATGAAA

ACATAATACTTGGGGTGGATGTACCTTTGGTAGGA

ACCATAGTGCCAAAATGCAATTAACGGTTGCAATT

GCGGTAACGACACGATGATGCGTTTATCATAACTC

CAAATATCGGCTAAAAGCATGAGATATTCCTTGTAC

CGGCCCAAAACACGGTTTTTTTACACCTTCACATCA

CGAGAAATATCGTTTTTTTGAAAATCTTTAGAACAC

GGCCGATGCATTGCGATGCGACCTTATTTTTGCACT

ATGGTAGGGACAACATTTGCGGATGCACACATTGG

ATACCGTTTCTGACCCCCTTTTCACTTTTACAGATCC

TATGGATATAAGTATGTTACTGATTCTAAAACTTCA

TTCCCTAGGATTAAATGTAGAAACCATATAAGGAT

GGATCTTTAAGATACTTTTATCTATATCCTTTCCTGA

ACCCTATTAAATATCTATGGCCTACAAGAGGTGGTC

ACAATTCATCATCCTCTTCGTCCACTTCATGCATTTT

AAACATATCTTCGAGTTCTCCTTTAATTGTTTATCTT

TGTTATTTCAGGAGTCCTCTTTTGAGTGTCTATGCT

GATATGTCGGAGACATGCAAGGTGAGCATATTCCC

ATTTGTCGCTCTTTTGATTTCTGACTTGTATGTTCTG

GTTCTCCATTTGTCGCTCTTTCGCGCGTATAATTTCG

AATGTTAGCCACTCCCCGTCACTCCTCCCATTCTGC

AATCACCGGGATTTTAACTATGAGGGTCCTTAGAA

TCGATTATAAAAATTCGACAAAAACAAAAAAAAAA

GACATAAAATTGACGGGCCATAACAATTTTACATA

AGATATTCAACATTTTTTTTGCGAATTTTCTTAATAA

ATTCCGTAATTCCGTACATCTATACTCCCGAGCCCC

TTCATGTGTGCGCTGCGGCTTTAAGAAACCTTTCTT

ATAAGTGTTGACTGTATGAGCTGACAGGCTGTCTTT

TCCGTCCCAATAATCATTTACAGGAATATAAGGATC

CAAATAGATCCATGCTGGAACTGGTTTTTGCACCCG

CGGAGGAATGGATTTCTCGAAGCGACACTGATATT

ATCGAGGCAACAATGAAAGAGCTTGCCAAGCTTTT

CCCGGATGAAATCGCTGCCGATGGAAGCAAGGCC

AAGATCCTCAAATATCATGTCGTCAAAACTCCAAGG

TGATTGATAAGCTTGTGAAATTAAAATTGGATAATT

TTATGCTACCGCTAGAAACAGCATTAATGTTGTGCC

CGCGGGCTCTTTTATAGGTCGGTTTATAAGACTGTA

CCGGATTGTGAACCTTGTCGGCCGCTGCAAAGATC

ACCAATAGAGGGTTTCTATTTAGCTGGTGATTACAC

AAAACAAAAATATTTGGCTTCTATGGAAGGTGCTG

TCTTATCTGGGAAGCTTTGTGCACAGGCTATCGTAC

AGGTAATCAAATTTTGATGGAACACCGCGTGCATG

CTGAGTAGACTTTTTGTGTTTTGATTTGTTCTGAAAT

TGACCCAAAACCGACCGGAAATCATGGGTTATAAC

TCGGAAAATATGACCCGTAACCTGAAAATGACTCA

AAACCCACCGTAGCCCAAATCCAACCGTTTCGACTT

GTTTACCTAATTTTGTCAACTTTTCTTGTTCCACATC

GTTAATTTTCTGTCGGAACCCACTTTCTTTCTAGTCT

ATTTTTGTATTTCTTTTTTCTTTGTTGATTCTTTTATT

CGTTTATACCTAGTTATGTTTTTTTTTTTTGAAAATTT

GGAATAGATTAATAAAAGGAGGAAAAGAAACACA

ACACTGTAACTTGGGACACCAAACCTAGTTATGTTT

ATATATTTATATGTATTTTATATATTTATATGCTTTT

GACTACTGAGGTATTATGATAGTTTCTATGAGCGT

GATATACTGGGTATGAAGATGATTTATTCTTTTTTA

ATAAAAAAGTTTAGGTCTTTTTTGAAAACATTTTAG

TGATTTTTTCTAAACTTGTAACCCGATCGAAATTCA

ATCCGAACCAAAAATAACCCGATCGAAAGTGACTC

AACCCAAAAGCTTCCCTGATCTAATTGTGATGATAG

CTTTGAAATTTTCATCGTTTTAGTCAAAAAGTTCTGT

TGAGTAGTTTAAATAACTGGTTCACATTTTGTAATT

ATATGCAGGATTATGATCTGCTGAGTTCTCGAGCA

CAAAGAGAATTGGCGGCGACAAGCAATGTATAACC

CTAAGTTGCTTCGACATCCGCCATCGATTTTCATTC

GAGATCTGGATTGGGAATCTGATCATCGAATAACG

ATCAGCTGCAAACAAAATTATGAGGGTTGCATACT

GGGGCTGTTCAAGTTCTTGATGTATAAATTCTCCAG

AAAGAAGATTTATTTGTAACGATATATAGAAATAT

GTATAGCTTACTTCTAGGGAATTATGTATGTGCACC

ATCTGTAACTTGATTGAAATGTAAGTATCAACTTGG

TCTCTTGATTGAAATGTAAGTATCAACATAATACAA

ATTTATACCAATACATTTATTTCCCTTTTTTGTTTAAT

TATGTGTTTTTTGTTGTTTTTTATTTGTAACTAGAGT

CACTCATACTCCAACGGTCTGTCTGGTTTGTGGTAT

TAAACGGTGGTGATGAGAATAAAAACTAGTGTAAT

TTTGATTAAAAATTCTCTTGCTATTTTGATGGCCATG

GTTGTGTTTGATGAGAAGGAATATGAAAACTAGTG

TAGGTGGTATTAAACAGTGCCACGGTGGTAATGAG

AATGAAAACTAGTGTAATTTGGGTTAAAAAAATCT

CTTGTCTTTAATCATCTCATTTTCTTTATAAATTTCAA

TCCAATGCATTACTATCGGGAGAGATGGTATCAGG

TGGTAATGGAAATTTGTAAATAAAAAGAAAAATTT

TGTGATCAAAGTTTCATCGCTATAAAGCATTCTCAT

TACCACCATTTAGTACCACTAATCAAACAGGCCGCA

AGAGCTTTAGCGTTGGCTTCCATTGGATGATTATG

GGGGTTAACGAGTCTGTTAAGGTGCCCATTATTAT

CTATATGTAGTTGTCTTCCATTGAAACTTGATAAGT

AACTTCTACCATTACCAAGTGTTTGTATATGAATCA

TTTTTTTTTTCTCTTTGTCTGGGTTGTTCAGACTCAC

TTTTAAAATTCTTCTTCATTAGCAAGTCCATTAGACT

TGTTTCAGTGCACTTCTGATTATAGTGTAAACAGAA

ACAAGGTTGCATCACATCAACCACGTTGTAAAGATT

TTCAAAACAGACGAATTGATATTTTTCGCGTTACCG

CATTTTTACATATCAAGTAGCTGTTTATTCAAGGAT

TAACAACTCATATAAAGTATCATAAGCTTATCAATA

TCTTTATGATTTATGAATGGAGTAATAAGAGAAGTT

AACTTATCTTGGTTTAGACTCTTGAGCGGAGCCGTA

CAATTACAAATCATTGACATACATGATACATTGCAT

AGGGACCCATCAAAAAATCAAAAAGGAAGACGAT

TGATCCTAAACGGAAACGAATGAAATTAAAAGAGA

GTAAAAAAAACACATTAATTTTAGAGGTTTTATATA

TTTTATATATTTTTTTTGTAATTTTAGAGCCTAAAAA

TAAGTTATTATACTCCGTCAAAGTTAGTATAAACTA

ACGTTAACAAATATTTGAAGCTCCCTTAATTTATGG

AGTTCTATGTGATTGGACATCTTACACATGCTCAGA

ACCACACCTGAATACAAAATATCAATATAATTCTGG

TATCCGAGCTGATAGTTCGATCAAAAATTAAAAAG

GTGGGTCCAAAAAGAATGTTGTCCCTACCCTAAGG

GCTAACAGTGTGTTTGGCAAGAGGGACTTGAGGTT

GGGGAATGAGATTTTTGGGTAAGATTATAAAAAGT

CTCTTATTTGTTTAAGGGGATTGAGAAAAGATGAG

ACTTGAGACTTAGAAAGGAAAAGTCCCCAAAAAAT

GTCTTGGTGGGAGGGCAGTATTTGGGGATGAAAC

TTAGAAAATTTATAAAAAGACAATTTTGCCATAAAT

GTAAAGAAATCTAAGAGTTATAAGGACAATTTTGT

AAATATAATCGATTTTTATTTAATTTCTTATCTATTTT

TATCATTTGACTGACAACGACATAAGACATTTATTT

TCAAAGTCTCAACTCAAGTCTCAACCTAAAGTCTCA

TTCTAAGTCTCGACTATAATCTCATAATTTCCATTCC

CACATGCCAAACACCCCCTAATTGATTACTCCCACG

TTCAAACTTGACGGGATTCACATGTAAAAGAAAAT

GTTGAGACAGTTTATCCCATATTGATAAATTAAAGA

TGTTGTGCACACTTTATAATTCATTAAAACTAGAGG

TGCTCATTCGGGTCATCGGGTTGATTTCAGGTTATG

TGTTTCAGGTCGGTTCAAAATCGGGATTTGTGTTCA

CATTGGCTTTTACATAATTATAGATCCACTTTTAAAT

CGGGTCTAATCGGGTTCGATTATAAAGTCGGATGT

CTATCGGGTCATCGGGTATGTTTTGAACACCTCTAA

TTAAAACCCATCCCTTCCGATCTAACTTAACATTCAT

GTACCTCGTTAAACCACAAAATCTGTTTCTAAGCTT

GTAATTTCAACAAAATCTAACCAACTTAAGTCTTAA

GTTAAAAACCAAGAGGAAAAGGGCGGTTTCAATCT

TCAATCTCGAGTGGACGCCATAACTAATGGCTGAT

GCAGATCATCTCACATTCTTAACATTTCAATTCACTG

AATCTTGGGATTTTGGTGTTTAAAAACAAGATCATG

GTAATCCTTTAAACCTTAAATTGTAATTAAAGTCAT

TAAATTTGTGGTTTTGATGTATTCAACGTTTAAAGT

ATTTAATTTACCCAAGATCAGGTAGTGGGGGATTG

TGCATTTGTGCATCAGATCAGTACAGGATTAATGT

GCAGCAACAGTTCATTCGAGTCTTAGAGGGTGAGC

GAGGGGATTGACTATATAATATAGGGCCGTCTTAT

TCTTCCGTATGAAAAAGTTAACAAGAAATGTATGTT

AAGTCTATTAATAAAATAAAAATATTACTACAAATA

AAGTGCAAATAAAAGTTTTACACAGGGCCCCTAAA

TTTTTCAAAACGGCTCTCAGCCACACAAGTAGACAG

TCATCAGCCGAGTACTTCCTCCGTCTAACAAATTGT

GACAGTGAGGATAAATATAGTTAATTATGTCCAAA

ATTTATAATATAAATATAAAGATTTCGTAGGTGAAC

TGTAAATAAATCAACCCAAAATAACAATACAAATTT

TTGTGAGAGATGGTCTCTTTGAGAGACCATCTCTA

GTTGGGCGGCTCATTATATATTTTTTAAAATATTGT

AAGTAGGCATTAGGAATGATCTAAGTATACATTTA

AGATATTGAAAGTAGGCATTAAGGATACGATAATA

AGTAAGCACTAAGGATAATGTTAGTAGACATTAAA

AATATGATAAATAGACATTAATCTTTAATGGGTTGG

ACTTGAGATATATTTTTCAAAGAGACGATCTCTCAA

GAGATTAGCTGAAATACCAATGAGAACAAATTTAA

CAAACGAAAAGAGTAATAAATATATGAGGAGTTAA

AACTTAAAATGCATGTGAGAACAAAAATGCAAGAA

AATGATGAAACATTTTTATAAAGGAGAATTGTAGC

AAAATAAAAAGAATGAACAAAAGTAAAAGGTATTT

CCTCTGTTTCATAATCGTTGCTAGCGTTAGTGACAT

TTTCTAACATAACATGTCACACTAATGGAGAAAGTA

TTTGACAAGTCTCTTAGTCAATTGAAAGCATATTTC

TTAGGAAAAAGATGAGCTGAGTTTGTTCAGTGATT

TGATGATGTGATCAAATCATTAGTGAATCAGTGAA

ACCATACTCATGATTATATGATTACAACTTTAACAA

ACAAGTAAATATTGCATCTTTGGAGATATCAATGA

GTCAATTGACTAATGAATGTTCTAAAAGACTAAACA

CAAAAGATTGCACCAACTCATAACACCCCATCTATC

TATCTTTTTAATTTAGTATCATTTTTTATTTTGGGTTA

TTCGTCTCATTTGTATTAATAATACATCACTTTCTTT

GAACCTTATTCATACATTTTAACCCTTTTTTTAATAT

CATCCACGCAATTCAATCTCTTTTGGCTTATTACCAA

TAAGACTCAAAAAAATGTACGACCTTAACAAAGAA

ATTTATTGTCGATTAAATCATCATCATCATCATACCC

AGTGTATCTCGCTCATTATTGTCGATTAAATCTTAAT

AGAAAATATTATGTACAACTTCACATAAATAATAAA

TTAGAAATACTCATAATTTAGTAAGTCATTTTACTAT

ACTTCATATAAATATAAAGAATTTTAATAAAATTTTC

CATCACCTCTTATTATCGGAAATTCTCTAACCTGCAC

CCGAGTCAAAAAATTAAAAAAATAATAAATTGCAA

AAGCAAAAACCTTTATCAACCACAAGACTGAAAAA

ATAGTAATTAATTTGTCACCAAAGATATATTATATG

AATAATAACTAATTAGTGTTGTTTTTTAGGATATAT

GCATTTAAAAAATGTTACCTTATGATTAGCAAAATC

AAGCAACAAAACTATATGATGATTTAAGTTTGTCTC

ATTTGAGACCATCCAACAAGAAGTCATGTGGAAAA

TCCTAAACTATAGTGATTAGAAAGACTAGTATACCA

AATCTTTGAATAAGATGACAAAAGATATTGATTAA

ACTAATCTTAATTAGCTATATCCAAAATATTTGGCG

ATTTATGGCGTTTGATAAATGACTGATAGCTGGTA

GTTGATAACTGATTATAGTGACTGATTTGATCAGTT

GATTTTATTAACTGTTTCAACCAGTTAATTCACCAA

AGACTAGCATTAGCTGGTTTGACCACCCAACCCTTA

TTTATATCAAAATAAGCTAAAATTACCCAATAAGCT

AATTTGTCAAATACCCGTGTATATTATGTAAGTTTG

AGAGTAAAAATATTTTTTTTTAGAAAAAATATTAAT

TTAACTTTTACTTATCTTGCCTTTCCTCGGCCTATCG

ATTCAGTAATAAAAAAAATTCTCTCAATATAATGTT

ATAGAAATATACTCTCTCTGTTCTTTTAAGTTTGTTC

ACATTACTCTAACGGGCAGTTTCATATGTTTGTCCT

ATTTAGAATACTTTTCTATTTTGGAAAGTTTTTATCT

TCCATGTGCTCTCTTTATCCCTCATTTAACCC

8

Amaranthus

Genomic
8797
AGGGATAAATGATAAAGATTGATTCATTTTTTTTAA

palmeri

ATGAATAATTTGTTTTTTTGTATGATGCAGGTTGTTT

GTATAGATTATCCTAGGCCAGAGCTTGAAAGTACA

TCCAATTTCTTGGAAGCCGCCTACTTATCTTCTACTT

TTCGGAATTCGCCTCGTCCTCAGAAGCCATTAGAA

GTTGTAATTGCTGGAGCAGGTGAGTGGAAGGGTT

CTTTACTCATTCTGTTCATTAGGGTCTTGTTGTGTTG

CTTTTTGCTTTGCCAAATTGGATGCTGTTCTTGATTT

TCAGGAGCTTTGGGCAAAATAGAAGCAAAATTGAA

AGCTAATTGAGTCAATTGAGATGTTTTTGAGAAATC

ATTTGTTGGCCGTTACTGTTTATTAGAGAAAAAATA

TGGGTCAAGAAACGAAAAGATAATGGAAAAACTA

CTTATAGGTGTCTTTTTTGATCATGAATCATGATGG

ATATATATGGTGTCAACTATCAAGACTGCCATATAA

CTAATGTAGTATGCTTCCTTAAGGGGTGGTGAAGA

ATAGACGTGTGGATGAGAAAATTGCTGGGAATTTC

CTATGCTTATGTAGAATGAGCTTCCTCTTGTTGACA

TTAGTGAAAAGTGAAAAATTGGTGTATGAGTTTGC

TTGATCGCTTTTGTGAGTGCTTCATTGTCCGTTCCAC

ACCTAGGTTATGTTGTAGGGTTGCAATATGTTAAAT

TGTTAGTGACGGCTGTCGTATAACATTATTGTATCT

TATGCCATGGGCCAAATTTACCCCTATTCAACGACG

CCATGCAGACCTAGGTGTAGTGAAAAGTATGCAAG

GGTTAATTGGACATCAAGCATGGCGCCATGTTGTT

TGAGTGTGGCAAAAAGACTTTACGCTACACCTCTA

GACCAGTTAAGTATGTAAAGGGTGTTGGGTCACCG

CTCTAAAGTGGTGTGTCACATTTTATCGAATTCGAG

GATAAGCTGATCGTGGTATCAAGTGAGAAAGAAC

GCAATATAGTGGAATTAGAAAGTTAAGTAATAAGA

AAAAAGAAAAAAATGATATCTAGCTTTAGGAAAAT

CTATCAGTGAGGAGAATATTGCAAAATATGTGGAA

ATTAAAACCAAGACAAAGCTAGCGATATATGAGAC

AAAGTTAAAAATGTACAAAGAAATATACGATAAGT

TGACTCGAAAGAAGAGGATAACGATCTTTATAGGA

TAGCCTAAAGGAGACAAATGATTATAAACGATACT

AGTTGAATGAACTATGAAGAGTGTCTTAACCAAGC

AAATATTGTTTAGAAATAGATTCAGAACTTTTTAAT

TCTTCAAATGTGAACGTGAGAACTGACTTCTCATTC

TTTATTTTACTTCAAGGTTTGGCTGGTTTATCCACG

GCAAAGTATTTAGCTGATGCAGGTCACAAACCCAT

ATTGTTGGAAGCACGAGATGTTTTAGGAGGAAAG

GTGTGTGCTATACGTTTCTCATAGCTTATGAAATAA

ATTCATCGTGGTTACTCTCTTATTAGCTTATTTCAGA

CTATCAAATAATTTTTGAACTTTTTCCTCCCTCTGTT

CGGCTGTATTATTATATATGTGCAGCATGATTAAAA

CTGGGTTCATTAAAATATATGAAGTTTTTTTTATCA

AGGCGAGATTTTGTCATCCAAAAACTTTACTTCTGA

ACGTGCTGTATGATCCTGTTTCTGTATCTTCATTTGC

TGGGATTTTCTTGAGGTTCCTGACTGCTTTCAGTTA

TTGTAGTTACCCATCCTGCATAAGTCTGAGTTTACA

GTTATTATAATGAAAATGAATCGGCTAATTATATCC

TCATCACAGTATGATGAATCTTGGGCTAGTATGAA

AATGAGGTAGGAAGAATAATTTGGGTTAGTTTCGT

AATATGTGCCAAGAGAAATATTGTAGTGCAAAGTT

TCTTTGTATTTCTTCTCGTGCTTATATTTTTTGCTCCA

CAGGTTGCAGCGTGGAAGGATGAGGATGGTGACT

GGTATGAGACTGGGCTACATATATTCTGTGAGTGA

TCTTCTAATTTTCTGCTTAATTGGCCAGTTACCCATG

TTCTTACAATGCGCTCTCTAGTCGTGTTTATTGGAA

AATCGATGTACTGAACATCTTCATATTTTCTTGAAG

TTGGGGCATATCCAAATATCCAAAATCTATTTGGAG

AACTTGGTATAAATGACCGACTGCAATGGAAGGAG

CACTCTATGATTTTTGCAATGCCTAGCAAGCCCGGT

GAATTCAGTCGCTTTGATTTTCCCGAAATCCTGCCT

GCACCATTAAATGGTTAGTATATCGGTGATAACTG

CCAAATTACTTGATGCAATGCAGTACCTTGTTAAGT

ACTTTGGATGTGACTCCACCTATAATACTTGCTATA

ATCTTCAATTTATTTCTCTTTCCTACATTAGAAACTA

TAAGTATCCCGCTAAAGGACATGACCCCACTTACAA

AGTTACAATACCCCATGAAAATACCCACTCACCCAC

TTTTTTTAATCGGTGTACCATCCGCCCGAGGAGCAA

TCTCGAGGGGACAGCAGAGTACTACTTTAGTGTTA

TTGTGATGAAATAGGTACCTGCATCATATCTCATGT

CCTGTGGATACCCATAAATGAACGAAAAATTTCATT

TTTATACATATTATCCTGCTTTAGAAGCTTGGAATA

TCATTGAACTTTTTTAACGTCCCACCATGAAAACAA

TCTGCATCTTGGTCTGTTTGCAACTCCTAAATCCTAA

TGAGTCGGGCTGATTTATGTCTTTGATGCTTTTGAC

CGTGTTTGGCAGGCATATGGGCAATCCTAAGGAAT

AATGAAATGCTAACCTGGCCAGAAAAAATCAAGTT

TGCCATTGGCTTGTTGCCTGCTATGGCAGGCGGAC

AGTCATATGTTGAAGCACAAGATGGTTTGAGTGTC

CAAGAGTGGATGAGAAAACAAGTAGGAGCAGACT

TTCGTTTCAGATTTTCCTCATTTTGTTAATGGTTCTA

GCTGTAAACTTTGACTTTGTTGGGACGTCAATGCTG

AAATTTTGTTTGTGCATTAATGCAGGGAGTACCCG

ATCGTGTAACTGATGATGTGTTTATTGCCATGTCAA

AGGCACTGAACTTCATAAATCCCGATGAACTTTCAA

TGCAGTGCATCTTGATTGCTCTGAACCGATTCCTGC

AGGCATGACTGCTTTTTAATTTCCGCTTTAAATTTTT

GGTTTTGTACAATACTTCTTAGTGCTTGTTTTTGTGA

CTTTTCTCGAGTAAATAGGGGATGTAAAATGACCG

TGCTGTTTTTCATGAACTGACGTTGGGTAATGTATA

TCAACAGGAGAAACATGGTTCTAAGATGGCCTTCC

TAGACGGAAACCCTCCAGAGAGGCTGTGCATGCCT

ATTGTTAAGCACATCGAGTCACTAGGTGGTGAAGT

TAAACTAAATTCTCGTATACAAAAGATTCAGTTGGA

CCAGAGTGGAAGCGTGAAGAGTTTTTTGCTAAATA

ACGGGAGGGAAATACGAGGAGATGCCTATGTTTTT

GCCACCCCAGGTTTTCTTCTCTCCCTTTTTTTACCATT

AGTTTTCTATTAGACTCAGTAAAAGCTAGAGTAAA

GAAAATGAAGATTCTATTACAGAAATGGACACACT

GTAAAGCTTAATTAGTTTTGATCTTGGGCAAAGCAT

TTGTGTTTCCAAATTTGTTAATGGTTATTATTTAAAT

AGAACACTTATGTTTGTGATGGGTAACAATAGGTC

AAGCGTTGAGCCAAAGTGTTATAACAATGATTATA

TAGTGTATATCATAGTGTAAAATTGCGGTAACGGA

CGCAATCACAGTGTCGGGAGTGATTCGGTATCATA

ACGCCTAAATATCGGTCGAAACCATAAGCTTTGAA

ACGGCCCAAAACACGGTTTTTTTTAAAAACTTTACG

ACGCGAGAAATATCGTTTTGTTTATTTTGAAAACCT

TTACGAAGCGACGATGCGATGCAGCCTTGTTTTAA

CTCTATAGTGTACATAGGAATATACAATTAAGCAAA

TAGTCGTAAGTGATATCTCAAAAGGGACAAGTGTG

AAATAGGCTAAAGAGTTGAATTAATTGTGGGATTG

ACAATTGTTTCATCACTGGTCCTCTATTGCTTTCCTT

GGTAAAATGTTGCATACTTGTTTATTGATTTACACT

ACATATAATTAGTTCTGTAGAATATGTTCTTGAGTC

AAAGCATGGGTCGATGTTTGAGGTTGATGTTGGAT

TTGCTTGGGCAAGCAATTACGAATATCTTGGTTTAA

GGAACCCATGAAAATGGAGCAGCTTGCAACGAAA

ACAAAGCCCAGTTGAAAGCCTGCTCGGGTGAGCAG

CATCGCGTTGGGGCCAGCATGATGAGCTGTTCAAA

CACAGAAGTTACTGGAGTGCTAGTGCTCTGGCAAG

CAAGCACAGCGCAGCTTACTTTTCTTTAATTTTTGAT

TCTATCTAGAATTCTAACTAAACCCTAATGCTTACG

ATTGATTAGTATAATTAAAACCCATAAAGTGAATGA

GTTGTTCAAATACTTGACAATTGACATTATTTGAGT

GGTCGTGGATGTAGTGTTGTAACAAAATTGTCACT

TATGAGTTAGGACCATATCCTTGCGAAGGTGGAGA

TACACTTGGTAGAATACGGTGAAAAGTATCACCTTT

CCATAGATAGTATAGCGTTATAAGTGAATTTATTAT

ATTGTGCTGTCATATCAGTGTAACATAATTTGTAGC

TAATCCGCTTTTTGAATACGGAATTCGCTCGAAATT

GTTGAAAAATAACCCAAGACCGACCATATTTTGCTT

TTTTCGGTTTGCGATTCGCAGGGAGATTAGAGAAC

CATGTAACATTGTATTTTGATATAATTTTTGAATTTC

ATTGTCAGTTGACATCTTGAAGCTGTTACTACCCGA

TACTTGGAAGGAAATCTCATACTTCAAAAAGCTTGA

GAAATTAGTGGGCGTTCCTGTGATTAATGTTCACAT

ATGGTTAGTTAATTCTTCATTCTATATTAAATTTACT

TGTTAGGTTTTATACCTAATCAACTGCTTTTAGTTTT

GACATTTTGTCCGACAATAAGTGGACGTTTCTGTTT

TGTTGCGTTTTGTGAATTTCTTTTGATTACAGGGGC

TAATTATATAATAATGCTTCATGCAGGTTTGACAGA

AAATTAAAGAATACATATGACCATCTACTCTTCAGC

AGGTTGTATTTCGTTTCTTTAATCATCCTATTTCTCTT

TCGTAACTCTTAAATAATCTCGTTCTTCCCCTTCCCT

CCTTCACTTCAACTTGTTTCAACTCTTCATTTTCGGT

CGTAGTCAAATTTGATGAGTATTTGACAAGAGTTG

CATCATAAGTAATATGAACATTGGAGGAGTGACAA

TCATCATTTATGAAGTATTAACTAAGATTCCTTTAA

GAAGGTGAAAGTTTTAAGTGAAAATTTTCTTTCCAT

TGGGAAATAAGTCTTTTGATTAATGTCTTGAATAGA

TGAAGGATGCGAGTTTTTGGAATGAAGAGAAACG

TTTTATGTGATCTAGTTGCGAGTCGATAGTGCCCTG

AATTTCTTCAAAATTGAGCATTTTTGTTATCGTTCGC

TTTATTTTTGCACTTTCATGTCCTTTTCTTAAAGTTGT

ATATGACTTTTCATTCTCAACTTAGGCTTACCTCGAT

GCTTAAAGTGTCTCCTTTACTTTTGCCCAAATTTTAG

GAACGTGTAAGTTACAGGATACAAATTAAAGTTAG

GGAATCGTGTAGGGCTCGTAAAAAATGACAATCAC

CAATAACTTTCTAAATATCAAAATGGGTCACTTGTG

GTGAACTGATCCATATGAAAATTAGACACTTGTGCT

GAGATGGAGCAAGTATTATAACTTATGAAAACATA

ATACTTGGGGTGGATGTACCTTTGTTAGGAACCAT

AGTGCCAAAATGCAATAACGCCATAACGGTAACGA

CACGATGATGCGTTTATCATAACTCCAAATATCGGC

TAAAAGCATGAGATATTCCTTGTACCGGCCCAAAA

CAGGGTTTTTTTACACCTTTACATTATGAGAAATAT

CGTTTTTTTTTTTTTTTGAAAATCTTTAGAACACGAC

CGATGCAGCGCGATGCGACCTTATTTTTGCACTATG

GTAGGGACAGCATTTGCGGATGCACACATTGGTTA

CCATTTCTGACCCCCTTTTCACTTTTACAGATCCTAT

GGATATAAGTATGTTACTGATTCTAAAACTTCATTC

CCTAGGATTAAATGTAGAAACCATATAAGGATGGA

TCTTTAAGATACTTTTATCTATATCCTTTCCTGAACC

CTATTAAATATCTATGGCCTACAAGAGGTGGTCAC

AATTCATCATCCTCTTCGTCCACTTCATGCATTTTAA

ACATATCTTCGAGTTCTCCTTTAATTGTTTATCTTTG

TTATTCCAGGAGTCCTCTTTTGAGTGTCTATGCTGA

TATGTCGGAGACATGCAAGGTGAGCATATTCCCAT

TTGTCGCTCTTTTGATTTCTGACTTGTATGTTCTGGT

TCTCCATTTGTCGCTCTTTCGCGCGTATAATTTCGAA

TGTTAGCCACTCCCCGTCACTCCTCCCATTCTGCAAT

CACCGGGATTTTAACTATGAGGGTCCTTAGAATCG

ATTATAAAAATTCGACAAAAACAAAAAAAAAAGAC

ATAAAATTGACGGGCCATAACAATTTTACATAAGAT

ATTCAACATTTTTTTTGCGAATTTTCTTAATAAATTC

CGTAATTCCGTACATCTATACTCCCGAGCCCCTTCA

TGTGTGCGCTGCGGCTTTAAGAAACCTTTCTTATAA

GTGTTGACTGTATGAGCTGACAGGCTGTCTTTTCCG

TCCCAATAATCATTTACAGGAATATAAGGATCCAAA

TAGATCCATGCTGGAACTGGTTTTTGCACCCGCGG

AGGAATGGATTTCTCGAAGCGACACTGATATTATT

GAGGCAACAATGAAAGAGCTTGCCAAGCTTTTCCC

GGATGAAATTGCTGCCGATGGGAGCAAGGCCAAG

ATCCTCAAATATCATGTCGTCAAAACTCCAAGGTGA

TCGATAAGCTTGTGTAATTAAAATTGGATAATTTTA

TGCTACCGCTAGAAACAGCATTAATGTTGTGCCCG

CGGGCTCTTTTATAGGTCGGTTTATAAGACTGTACC

GGATTGTGAACCTTGTCGGCCGCTGCAAAGATCAC

CAATAGAGGGTTTCTATTTAGCTGGTGATTACACAA

AACAAAAATATTTGGCTTCTATGGAAGGTGCTGTCT

TATCTGGGAAGCTTTGTGCACAGGCTATCGTACAG

GTAATCAAATTTTGATGGAACACCGCGTGCATGCT

GATTAGACTTTTCGTATTTTGATTTGATTTGAAATTG

ACCCAAAACCGACCGGAAATTAGTGGGTTACTTAT

AACTCAGAAAATATGACCCGTAACCTGAAAATGAC

TCAAACCCACCGTAGCCCAAATCCAACCGTTTTGAC

TTGTTTACCTAATTTTGTCAACTTTTCTTGTTCCAAG

TCATTAGTTTTCTGTCGGAACCCACTTTCTTTCGAGT

CTTTTTTTGTATTTCTTTTATCTTCGTTGATGCTTTTA

TTCGTTTATACCTAGTTATGTTGATATATTTATATGT

ATATATTTATTTATATGCTTTTTACTACTGAGGTATG

ATGTTCTAGAGTATGATGATGATGATTTATTCTTTTT

ATATTAAAAAAAAAGTTTAGGTCTTTTTGAAAACAT

TTTAGTGATTTTTTCTAAACTTGTGACCCGATCGAA

ATTTGATCCGAACCAAAAATAACCCGATCAAAAGT

GACTCAACCCGAAACCTACCCTGATCTAATTGTAAT

GATAGCTTTGAAATTTTTATCGTTCTAGTTAACAAG

TTCTGTTGAAGTTAATATAAATCTCGAACGTTCCTA

TAAACTTATTTTTTAGATTGTCAAGGTTAGTTAGTT

GTATAGAAGTTAAGTAGCTTAAACAACTAGTCCAT

ATTTTGTATATGTGTAGGATTATGATCTGCTGAGTT

CTCGAGCACAAAGAGAATTGGCGGCGACAAGCAA

TGTATAACCCTAAATTGCTTCGACATCCGCCATCTA

TTTTCATTCGAGATTTGGATTGGGAATCTGATCATC

GAATAACGATCAGCTGCAAACAAAATTATGAGGGT

TGCATACTGGTGCTGTTCAAGTTCTTGATGTATAAA

TTCTCCAGAAAGAAGATTTATTTGTAATGATATATC

AATTGATAGAAATATGTATAGCTTACTTCTAAGGAA

TTATGTATGTGCACCATTTGTAACTTGATTGAAATG

TAAGTATCAACTTGGTCTCTTGATTGAAATGTAAGT

ATCAACATAATACAAATTTATACCAATACATTTATTT

CCCTTTTTTGTTTAATTATGTGTTTTTTGTTGTTTTTT

ATTTGTAACTAGAGTCACTCATACTCCAACGGTCTG

TCTGGTTTGTGGTATTAAACGGTGGTGATGAGAAT

AAAAACTAGTGTAATTTTGATTAAAAATTCTCTTGC

TATTTTGATGGCCATGGTTGTGTTTGATGAGAAGG

AATATGAAAACTAGTGTAGGTGGTATTAAACAGTG

CCACGGTGGTAATGAGAATGAAAACTAGTGTAATT

TGGGTTAAAAAAATCTCTTGTCTTTAATCATCTCATT

TTCTTTATAAATTTCAATCCAATGCATTACTATCGGG

AGAGATGGTATCAGGTGGTAATGGAAATTTGTAAA

TAAAAAGAAAAATTTTGTGATCAAAGT

9

Amaranthus

Genomic
1788
TTGAAAGCCTGCTCGGGCACGACACTGTAGGGCTC

palmeri

GGGCGAGCAGCATCGCGTTGGGGCCAGCATGATG

AGATGTTCAAACACAGAAGTTACTGGAGTGCTAGT

GCGCGGCTTACTTTTCTTTAATTTTGATTCTATCTAG

AATTCTAACTAAACCCTAATGCTTACGATTGATTAG

TATAATTAAAACCCATAAAATCTTCAGATTTTTCACC

ACAAAATATTTGAGCTTAGTAATCTACAAGAAATCT

TCAAACACATCAAATCTAGTTGTCTCTCATTCTCTAT

TGTAATTCTTATTATTACGAGTTCTTGTGTTCAAGA

ACTACAAGTTTGATTATTAATCAACCCAAGAAGTTC

GCCAAGGAGGATGTAGCCCAAACTGGGTGAACCTC

GGTAAATCTTTGAATTCTTCCTTGCTTTCTACTAATT

AATTGCGAATGAGTATGTAAGATATTGCATTATATT

TTTCATATTCAACAAAAGCATTCTACTACCAATCTTC

GTCTTGTAATTCGCTTTTGCAACGTTGTCCTTCAACT

AGTGAATGAGTTGTTCAAATACTTGACAATTGATAT

TATTTGAGTGGTCGTGGATGTAGTGTTGTAACTAA

ATTGTCACTTATGAGTTAGGACCATATCCTTGCAAA

GGTGGAGAGATCACTTGGCAGAATTCGGTGAAAA

GTAGCACCTTTCCATAGATAGTATAGCGTTATGAGT

GAATTTATTATATTGTGTTGTCTTATCAGTGTAACAT

AATTTGTAGCTAATTCGCTTTATGAATTCGGAATTC

GCTCGAAATTGTTGAAAAATAGCCCAAGACCGACC

ATATTTTGCTTTTTTCGATTTGCGATCCGCAGGGAG

ATTAGAGAACCATGTAACATTGTATTTTGATATAAT

TTTTGAATTTCATTGTCAGTTGACATCTTGAAGCTG

TTACTACCTGATACTTGGAAGGAAATCTCATACTTC

AAAAAACTTGAGAAATTAGTGGGCGTTCCTGTGAT

TAATGTTCACATATGGTTAGTTAATTCTTCATTCTAT

ATTAAATTTACTTGTTAGGTTTTATACCTTATCAACT

GCTTTTAGTTTTGACATTTTGTCCGACAATAAGTGG

GCGTTTCTGTTTTGTTGCGTTTTGTGAATTTCTTTTG

ATTACAGGGGCTAATTATATAATAATGCTTCATGCA

GGTTTGACAGAAAATTAAAGAATACATATGACCAT

CTACTCTTCAGCAGGTTGTATTTTGTTTCTTTAATCA

TCCATTTCTCTTTCGTAACTTAAATAATCTCGTTCTT

CCCCTTCCCTCCTTCACTTCAACACTTGTTTCAATTCT

TTCATTTTCGGTCGTAGTAAAAATTGATGTATATTT

GACAAGAGTTGCATCATAAGTAATATGAACATTGG

AGGAGTGACAATCATCATTTATGAAGTATAAACTA

AGATTCCTTTAAGAAGGTGAAAGTTTAAGTGAAAA

TTTTCTTTCCATTGGGAAATAGTCTTTTGATTAACAT

CTTGAATAGATGAAGGATGCGAGTTTTTGGAATGA

AGAGAAATATTTTATGTGATCTAGTTGAGAGTCGA

TGGTGCCTTGAATTTCTTCAAAATTGAGCATTTTGT

GAACGTTCGCTTTATTTTTGCACTTTCATGTCCTTTT

CTTAAAAGTAGTATATGGCTTTTCATTCTCAACTTA

GGCTTACCTCAATGCCTAAACCTTTACAAACACACA

TCATATAAGAATGAGTGTTAAAATTTACCTCTTCAT

CTCAGTAAAGTGTCTCATTTACTT

10

Amaranthus

Genomic
1277
ACCCATAAGGAGAGGGCGGTCACAAGAGTCCTTCG

palmeri

GTTAAGAGGAGTCTTCAAGGATAAGACCTGCAAAT

ATCCGAAAACCTAGTACCTATGGACTATAATTGTGT

TGGATAAAATAACAATTAGTTCATATTGGACTATAA

TTTTACCCTAGTGCCTATGGAAGATTGGGGAAATA

ATTTAATCATACTCCTTTTTTATTCATCTTTTTTATTT

ATTCTCATGCTATTTCTTTCACAATGTTTCAATTACC

TCACTTGCACTTCTACTGGCCTTTATTTCAATAATTT

AACTTTTTTTCACCCTTCAATATTTACAATCAATCCA

AGCGAGCACTAAGAAAAAAAACATTTGGCTTGATA

TATACTAATTTACCATAATAAAATCCAAACCTGCCA

AAAAAACATTTAGTTATTAAAAATGCTATGAAAATA

GTCTTTTTTTTTCTCAAGTGAAGTTCTGTAAATTAAA

AAAAGAAAAGCAAAGTAAATTACCTGGACCGTTGT

TGCGGTGGAGGAAAGTTCCAACGGGACTTTTGATC

TTAGTACCAAACACCGGTTCAATGAAGTTCAAGAA

TACCGACTCATCATTGTTGGCTAAAACCACAGCCTG

AAGTGCTGAATCAGCTACACCAAGCAGATCATCCG

CACTAAACTCAGCAAACTCATGAAACCCACTTATCT

TTCTTACATACTCCCACACCGGGTTTAACTCTTCCAC

ACAACTTGCAGCATGGTCTATTCCCTTTATCCCAAA

CTCCTCTACTCTTCCAACCTCTACTCTTGCAAACTTA

GCAAGCCGCCACAAATTACCCCACTCTTTTTCATTTT

CAGATGAATGGCTCACAAATCGTAGGACTACGTCA

TTATACAGAATGACTTCCGCAAGCATCGTGTGTCCG

TCTTCAAGCAGGACAGGCGGGGCTGACGGATTAG

CTCCTGCAGCAACGCTAATCCTAAAGGCGGATTCA

GCGTTCTCCACTTCAAGGGCCACAGCGCGAACACC

AAGCCCATGAGAACACACAAAAGAGGCGTGCGCA

CTGTGGTCAAATGTAGGAATTGAAGCAGTGTTGAG

CTTAGATGAAGCAGAGTAAGGAGCCGTGAATACG

AAACAAAGGTCGCCACTACGTAAGACGTAGGAGG

CATGTACAAGGTTGCCTGTCGAGAGATCGGATTTG

GCAACCAAAGGCATGCCAAGCCCTAACGAAAATAA

AAGGCTAGTGTTGGTTGCATCACCACACCAGAACT

CAATGTGGTGGAACCTTTTCACTTTGAAATG

11

Amaranthus

Genomic
1241
GATATACTGGGTATGAAGATGATTTATTCTTTTTTA

palmeri

ATAAAAAAGTTTAGGTCTTTTTTGAAAACATTTTAG

TGATTTTTTCTAAACTTGTAACCCGATCGAAATTCA

ATCCGAACCAAAAATAACCCGATCGAAAGTGACTC

AACCCAAAAGCTTCCCTGATCTAATTGTGATGATAG

CTTTGAAATTTTCATCGTTTTAGTCAAAAAGTTCTGT

TGAGTAGTTTAAATAACTGGTTCACATTTTGTAATT

ATATGCAGGATTATGATCTGCTGAGTTCTCGAGCA

CAAAGAGAATTGGCGGCGACAAGCAATGTATAACC

CTAAGTTGCTTCGACATCCGCCATCGATTTTCATTC

GAGATCTGGATTGGGAATCTGATCATCGAATAACG

ATCAGCTGCAAACAAAATTATGAGGGTTGCATACT

GGGGCTGTTCAAGTTCTTGATGTATAAATTCTCCAG

AAAGAAGATTTATTTGTAACGATATATAGAAATAT

GTATAGCTTACTTCTAGGGAATTATGTATGTGCACC

ATCTGTAACTTGATTGAAATGTAAGTATCAACTTGG

TCTCTTGATTGAAATGTAAGTATCAACATAATACAA

ATTTATACCAATACATTTATTTCCCTTTTTTGTTTAAT

TTTGTGTTTTTTGTTGTTTTTAATTTGTAACTAGACT

CACTCATACTCCAACGGTCCGTCTGGTTGGTGGTAT

TAAATGGGGTAATGAGAATAAAAATTAGTGTAATT

TTGGTTAAAAAATCTCTTGCTATCTTGATGGCCATG

CTTGTATTTGATGAGAAGGAATATGAAAACTAGTG

TAGGTGGTATTAAACAGTGTCACGGTGGTAGTGAG

AATGAAAACTAGTGTAATTTGGGTTAAAAAATCTC

GTCTTTAGTCATCTCATTTTCTTCAGAAATTTCATCT

CAATGCATTACTATCGGGAGAGATGGTATTAGGTG

GTNNNNNAAATTTGTAAATAAAAAAAACTTTTTGT

GATCAAAGTATCATCACTATAAATCATTCTCATTAN

NNNNNNTTAGTACCACTAATCAAACAGGCCGCAA

GAGCTTTAGCGTTGGCTTCCATTGGATGATTATGG

GGGTTAACGAGTCTGTTAAGGTGCCCATTATTATCT

ATATGTAGTTGTCTTCCATTGAAACTTGATAAGTAA

CTTCTACCATTACCAAGTGTTTGTATATGAATCATTT

TTTTTTTCTCTTTGTCTGGGTTGTTC

12

Amaranthus

Genomic
714
CTAATTATATAATAATGCTTCATGCAGGTTTGACAG

palmeri

AAAATTAAAGAATACATATGACCATCTACTCTTCAG

CAGGTTGTATTTTGTTTCTTTAATCATCCTATTTCTCT

TTCGTAACTTAAATAATCTCGTTCTTCCCCTTCCCTC

CTTCACTTCAACACTTGTTTCAATTCTTCATTTTCGG

TCGTAGTAAAAATTGATGTATATTTGACAAGAGTT

GCATCATAAGTAATATGAACATTGGAGGAGTGACA

ATCATCATTTATGAAGTATAAACTAAGATTCCTTTA

AGAAGGTGAAAGTTTAAGTGAAAATTTTCTTTCCAT

TGGGAAATAGTCTTTTGATTAACATCTTGAATAGAT

GAAGGATGCGAGTTTTTGGAATGAAGAGAAATATT

TTATGTGATCTAGTTGAGAGTCGATGGTGCCTTGA

ATTTCTTCAAAATTGAGCATTTTGTGAACGTTCGCT

TTATTTTTGCACTTTCATGTCCTTTTCTTAAAAGTAG

TATATGGCTTTTCATTCTCAACTTAGGCTTACCTCAA

TGCCTAAACCTTTACAAACACACATCATATAAGAAT

GAGTGTTAAAATTTACCTCTTCATCTCAGTAAAGTG

TCTCATTTACTTTTGCACAAATTTAAGGAACGTGTA

AGTTAGAGGATACAAATTAAAGTTAGGGAATCTTG

TAGGGCTCATAAAAAATGACAATCACCAA

13

Amaranthus

Genomic
367
TGGGTTTTAATATTAATCCAGGGAGAGGGTCTGGG

palmeri

TCGTCCATTTATTGTTTTGGGACACGACATTGGACC

AGATCCGTTGAGTCTCAAAACATTGGACTCATAGC

CTAAAAATAGGTGTAGGGATAGGACATATCCAATA

AAGTCTTGGACCCATAAGCGTACATCCCTAATATGT

AGTACTAGAATATTTTATATGTTAAACATTAAATGC

ATGACTTCTGATTCCTCGGGTCTAGTAATAGAGTAT

TCTTAGGGCTCGCCTGAATTGTGTATAAATATTTAA

GAGGTAAATAAAAGTTAAAGTAGGAAGATAAAGT

TAATTAAATAGAAGATTAAAGGCATTAAATTGTCGT

CATCATCATCAT

14

Amaranthus

Genomic
221
AGCTTGGTATAAATGAGCGATTACAATGAAAGGAG

palmeri

CACTCTATGATTTTTGCTATGCCAAGCAATCCTGGT

ATTTTCAGTCTTTTTTTTATTGAAGTCCTCCCAGGCT

CCAACAACATTTAACGTTTAGTTTGGTAATAAAATT

CGCAAAATGTCTGTATTTAGCGAAAGTCAAACTACT

CCTAATGACTTTCACGAGTCTCTTCATCAAGATGTT

TGGTG

15

Amaranthus

Genomic
133
TGACTCTCCATTTGATCTAAATAGAATTTCAACTCTT

palmeri

TTGTAGTTGACGAAGTCCAAATTAGTTGGAGTGTG

TATATTGAAATGCATGAACTCTTATGCTACTATTTAT

ATACTTTTTCCGTTTCATAATACT

16

Amaranthus

cDNA
2132
GCCTTTTGAATGTACATATTCTATTCTTGTAATCATT

rudis

TGATCAGCCAACATTAAGACCGTTTTCAATGAGAAC

TTCCTTCCGCAATACACAAAAAGATCCTCAAGACTA

GGCCCTAATAAATCAATCACGAGAATATTATCTTCC

CCATCCACTCCAGACCATTTCACAGTTGGAATCCCA

CTTCCTCCTTGAAGAATGGTGTATACCTTCGCCTCA

TACAGTAATTGCGGATGCTTCGTCTTGGTATTCTCG

AGCTTTACAGCGACAATCTCGAAGGTGTCGATATG

AGTAGCAAGGAAAATTTCACCGAAGGAACCACTGC

CGATCTTGCGACCTAGCTTGTACTTGCCTCCGACGA

TCCGATCCATAACGATTTCGATAAATTAAACAACCA

AAACTACCACCGTTGAAATTGATTGATATGGTGAA

ATCAATAGCGTGAAATTGAAAACATAAGTTAGGAT

TTTGGATAGATAAAGGGGAAAGTAGGTGCCGATG

AAGGGAAGAGAGAGAAAACTCAAGCTAAAAGCGG

GTAAGCAGACATCCAGAGAGAGAAAGAGAAAGAC

GATGAGTGTATGAGGTGGAGTTTTGGGGATTTTTA

ATTAGGGAAAGGGAAGGAAGGTGGAAATGGGAG

GAATTCTTTGGGGCTTATCCAAATATCCAAAATCTA

TTTGGAGAACTTGGTATAAATGATCGATTGCAATG

GAAGGAGCACTCTATGATTTTTGCAATGCCTAGCA

AGCCTGGTGAATTCAGTCGCTTTGATTTTCCCGAAG

TCCTGCCTGCACCATTAAATGGCATATGGGCAATCC

TAAGGAATAATGAAATGCTAACCTGGCCAGAAAAA

ATCAAGTTTGCCATTGGCTTGTTGCCTGCTATGGCT

GGCGGACAGTCATATGTTGAAGCACAAGACGGTTT

GAGTGTCCAAGAGTGGATGAGAAAACAAGGAGTA

CCCGATCGTGTAACTGATGAAGTATTTATTGCCATG

TCAAAGGCACTGAACTTCATAAATCCCGATGAACTT

TCAATGCAGTGCATCTTGATTGCTCTGAACCGATTC

CTGCAGGAGAAACATGGTTCTAAGATGGCCTTCCT

AGACGGAAACCCTCCAGAGAGGCTGTGCATGCCTA

TTGTTGAGCACATTGAGTCACTAGGTGGTGAAGTT

AAACTTAACTCTCGTATACAAAAGATTCAGTTGGAT

CAGAGTGGAAGCGTAAGAGTTTTTTGCTAACTAAT

GGGAGGGAAATAAGAGGAGATGCCTATGTATTTG

CTACCCCAGTTGACATTTTGAAGCTGTTGCTACCCG

ATACTTGGAAGGAAATCTCATACTTCAAAAAGCTTG

AGAAATTAGTGGGCGTTCCTGTGATTAATGTTCAC

ATATGGTTTGACAGAAAATTAAAGAATACGTATGA

CCATCTACTCTTCAGCAGGAGTCCTCTTTTGAGTGT

CTATGCTGATATGTCAGAGACATGCAAAGAATATA

AGGATCCAAATAGATCCATGCTGGAATTGGTTTTC

GCACCCGCGGAGGAATGGATTTCACGAAGCGACA

CTGATATTATTGAGGCAACAATGCAAGAGCTCGCC

AAGCTTTTCCCAGATGAAATCGCTGCTGATGGGAG

CAAGGCCAAGATCCTTAAATATCATGTCGTCAAAAC

TCCAAGGTCGGTTTATAAGACAGTACCGGATTGTG

AGCCTTGTCGGCCGCTGCAAAGATCACCGATAGAG

GGTTTCTATTTAGCTGGTGATTACACAAAACAAAAA

TATTTGGCTTCTATGGAAGGTGCTGTCTTATCTGGG

AAGCTTTGTGCTCAGGCTATTGTACAGGATTATGAT

CTGCTGAGTTCTCGAGCACAAAGAGAATTGGCGGC

GACAAGCAATGTATAACCCTGGATTGCTTTGACATC

CGCCATTGATTTTCATTCGAGATCTGGATTGGGAAT

CTGATCAGTCATCGAAAAATGATCAGCTGTAAACA

AAATTATGGGGGTTGCACATTGGTGTTCTCAAGTTC

TTGATTTATAAATTCTTCAGAAAGAAGATTTATTTG

TAATGATATATCAATTGATTGAAATATGTATAGCTT

ACTTCTAGGGAATTATGTATGTGCACCAGTTAACTT

GATTGAAAT

17

Amaranthus

cDNA
2088
TCCATTTTTCTTGTTCTTTCAGTTTCACATACCCTCTC

rudis

ATCAATCAATATCCAAAACTATTACATTTTCCAAACT

ATTTCAAACCCAAAAATCAAAAACTTTTGATTGAAG

AACAAACTTTGGGGGTTTTGGAAAATGAGTCATTT

TGGATATGCTTGTGCTACTCAATCCACATCAAGATA

TGTTCTTTTAGGAAATTCAAATAACCCCACTTCAATT

TCATCTATTGGAAGTGATTTTTTGGGTCATTCTGTG

AGAAATTTCAGTGTTAGTAAAGTTTATGGGGGAAA

GCAAAGAAATGGGCACTGCCCTTTAAAGGTTGTTT

GTATAGATTATCCTAGGCCAGAGCTTGAAAGTACA

TCCAATTTCTTGGAAGCCGCCTACTTATCTTCTACTT

TTCGGAATTCGCCTCGTCCTCAGAAGCCATTAGAA

GTTGTAATTGCCGGAGCAGGTTTGGCTGGTCTATC

CACGGCAAAGTATTTAGCTGATGCAGGTCACAAAC

CCATATTGCTGGAAGCACGAGATGTTTTAGGAGGA

AAGGTTGCAGCGTGGAAGGATGAGGATGGTGACT

GGTACGAGACTGGGCTACATATATTCTTTGGGGCT

TATCCAAATATCCAAAATCTATTTGGAGAACTTGGT

ATAAATGATCGATTGCAATGGAAGGAGCACTCTAT

GATTTTTGCAATGCCTAGCAAGCCTGGTGAATTCA

GTCGCTTTGATTTTCCCGAAGTCCTGCCTGCACCAT

TAAATGGCATATGGGCAATCCTAAGGAATAATGAA

ATGCTAACCTGGCCAGAAAAAATCAAGTTTGCCATT

GGCTTGTTGCCTGCTATGGCTGGCGGACAGTCATA

TGTTGAAGCACAAGACGGTTTGAGTGTCCAAGAGT

GGATGAGAAAACAAGGAGTACCCGATCGTGTAACT

GATGAAGTATTTATTGCCATGTCAAAGGCACTGAA

CTTCATAAATCCCGATGAACTTTCAATGCAGTGCAT

CTTGATTGCTCTGAACCGATTCCTGCAGGAGAAAC

ATGGTTCTAAGATGGCCTTCCTAGACGGAAACCCT

CCAGAGAGGCTGTGCATGCCTATTGTTGAGCACAT

TGAGTCACTAGGTGGTGAAGTTAAACTTAACTCTC

GTATACAAAAGATTCAGTTGGATCAGAGTGGAAGC

GTAAGAGTTTTTTGCTAACTAATGGGAGGGAAATA

AGAGGAGATGCCTATGTATTTGCTACCCCAGTTGA

CATTTTGAAGCTGTTGCTACCCGATACTTGGAAGG

AAATCTCATACTTCAAAAAGCTTGAGAAATTAGTG

GGCGTTCCTGTGATTAATGTTCACATATGGTTTGAC

AGAAAATTAAAGAATACGTATGACCATCTACTCTTC

AGCAGGAGTCCTCTTTTGAGTGTCTATGCTGATATG

TCAGAGACATGCAAAGAATATAAGGATCCAAATAG

ATCCATGCTGGAATTGGTTTTCGCACCCGCGGAGG

AATGGATTTCACGAAGCGACACTGATATTATTGAG

GCAACAATGCAAGAGCTCGCCAAGCTTTTCCCAGA

TGAAATCGCTGCTGATGGGAGCAAGGCCAAGATCC

TTAAATATCATGTCGTCAAAACTCCAAGGTCGGTTT

ATAAGACAGTACCGGATTGTGAGCCTTGTCGGCCG

CTGCAAAGATCACCGATAGAGGGTTTCTATTTAGCT

GGTGATTACACAAAACAAAAATATTTGGCTTCTATG

GAAGGTGCTGTCTTATCTGGGAAGCTTTGTGCTCA

GGCTATTGTACAGGATTATGATCTGCTGAGTTCTCG

AGCACAAAGAGAATTGGCGGCGACAAGCAATGTA

TAACCCTGGATTGCTTTGACATCCGCCATTGATTTT

CATTCGAGATCTGGATTGGGAATCTGATCAGTCAT

CGAAAAATGATCAGCTGTAAACAAAATTATGGGGG

TTGCACATTGGTGTTCTCAAGTTCTTGATTTATAAAT

TCTTCAGAAAGAAGATTTATTTGTAATGATATATCA

ATTGATTGAAATATGTATAGCTTACTTCTAGGGAAT

TATGTATGTGCACCAGTTAACTTGATTGAAAT

18

Amaranthus

Genomic
4346
AAGTATGTACAAGTTGTTAGGTCATCACTCAAAAG

rudis

TGATGTGTCACATTTCATCATATGAGCAAAAAGTAT

TTGGTTTTAGGGATAAGCGACTAAACAAATAGATC

TATGTGAAGATTAACATTTTGGAATATTGAAACTCT

ATTTGGGAAGTGATTGGAGTTGGTAGATAGAATG

GAAAAACTTAAGATGGACTTTATGTAGGAGATCAC

GTGGATTAATGGAGAGACCAGGCCATTCAAAACAA

ATAAGAAATTATGCACATTATTGTATACATGCAAAT

TAAGAAGAGAAACAAACTTGGTATCATGATGGGTG

AGTAGTTTGCCTATGACGTTGTAGAGGTGTGTGGA

TAAATGATTAGAACATGAGCTATGAATGGAAGAGA

AATATTAATGGTTGGTGCATATGCGCCTCAAGTGA

AGGCAAAGGAAGCAACACCAACAATGTCAAAGTCT

TATTTTTAGGTAATATGAAAAACAAAGGAAGCAAT

CAAAAGAAATTTCTCAGGCGAGTTGATGCAAATTA

TCCCAACATTAAGAAAATTTTGTATACTAGCGAACA

TGTAGCCATCCATCACAAACACGTAGTCCTAGATCT

TCATATGTGATCAACCTCGTGCAAGAATGAACTTCA

AGGACAAAGAAAAATCAAATGATAGAACCCAAAAT

AAGAGGATACGAATTTTTCATTTGATTAGACAAAT

GAGGAAGATCCAAATCCAACTTGGACAAAGATGAA

GAATGTTATCACCCGCACAACTAGGGGAATTCAAG

GTTAAGCGGATTGTGGTATGAGGTAAGAAAGAAT

ACAATATAGGGGAATTAGGAAGTAAAGGAATAAG

AAAAAAAAGAATGATATATAGCTTTAGGAAAATCT

AGGAGTGAGGAGAATATAGCAAAATATGAGGAAG

TTAAAACCAAGACGAAGCAAGCGATATGTGAGACA

AAGTTAAAAGATAAGAGATATACAATAAGCTGACT

CAAGAGAAGAGGATAATGATCTTTGTAGGGTAGCC

TAAAGGAGACAAATGATTATAAAAGATACTAGTTG

AATGAACTATGAAGTGTGTCTTGGATAAATAACAA

AATAATATTCTCCAAGATGAATAGATATACGATAAA

TGGAAGGAGTTTTTGACGAGTTGTGCAATGGATGT

CAAGGGGCACGATAGTATACATCTAGAAGAAATTC

TGAAAAGGTGCTTTTCTTAGAATGTAAATTGTGAG

AAAAAGGAAGAAGGCGATTATCAGTAAATCAATTG

TCTTTGTTCACAGAATGTGACACCAACATGTTGGAT

GGGGGAGAGAAGTTTTCTTTGTTAACGAATCTTTC

GGTTATGTATGGAAGTATGTTATTTTATGAGACATC

TTGTTCAAGAGCTCATCATTAATATAGAGGAGTAG

AGGTGTTCAACGGGATGGGTCGGGGCAAAATTTA

AATTGGTCGGGCCGGGGCGGGTCATGTCTAAGAG

GAGCAACAACATAAATAATAAAATATACCATCGTA

TGGACATATAGTTTAGAGATAGATTCAAAAATTTTT

ATATCTTCAAATATGAATGTGAGAACCGACTTCTCA

TACTTTATTTTACTTACAGGTTTGGCTGGTCTATCCA

CAGCAAAGTATTTAGCTGATGCAGGTCACAAACCC

ATATTGCTGGAAGCACGAGATGTTTTAGGAGGAAA

GGTGTGTGCTATACTTTTCTTGTAGCTTATGAAACA

ACTCCATTGTGCTTACTCTCTAATTAGTTTACTTCAG

ACTATCAGATGATTTTTGAACTTTTTCCTCCCTCTGT

TCGGCTGTATAATTATATATGAGAAACATGTTTAAA

AATGGGTGCATTAACATATATGAAGTTTTTTTTATC

AAGGCGAGATTTTGTCATCCAAAAACTTTACTTCTG

AATCTGAACATGCTGTATGATCCTGTTTCTTTATCTT

CATTTGTTGGGATTTTCTTGAGGCTCATGACTACTT

TCAGTTATTATAGTTACCCATCCTGCATAAATCCGA

GTTTACAGTTATAGTAATGAAAATAAATAGGCTAAT

TATATTCTCGTCGGTCATCACAGTATGATGAATCTT

GGGCTAATATGAAGATGAGGTAGGAAGAAGAATT

TGTGTTAGTATGATAATATGTGCCCGCCCTAAGCAA

GTGCAAGCCTTGCCTACGCCTAGGGCCCCCCAAAA

ATTTTAGTTTTCAACTAGTGCTAACGTTCGAACTTTT

CTATATATATACAATAGTTTAGGGGCCCAAATAATC

TTTCGCCCCGGGCCCCTAAAAACCTAGGGTCGGCT

AGTGCCAAGAGAAATATTGTTGTGCAAAGTTTCTT

GGTATTTTTTCTTGTGCTTACAATTCTTGCTCCACAG

ATTGCAGCGTGGAAGGATGAGGATGGTGACTGGT

ATGAGACTGGGCTACATATATTCTGTGAGTGATCTT

TTAATTTTCTGCTTAGTTGGGTAGTTACCCGTGTAC

TTATTATGTGCACTCTAGTCATGTTTATTGGAAAAA

TTTACTGCATATTTATCAGTCCGATGTACTGAACAT

CTTCATATTTTCTTGAAGTTGGGGCATATCCAAATA

TCCAAAATCTATTTGGAGAACTTGGTATAAATGACC

GATTGCAATGGAAGGAGCACTCTATGATTTTTGCA

ATGCCTAGCAAACCCGGTGAATTCAGTCGCTTTGAT

TTTCCCGAAGTCCTGCCTGCACCATTAAATGGTTAG

TATATCGGTGATGGTTTTTGTTGGCTGCCAAATTAC

TTGATGCAATGCATTACCTTGTAAAATACTCCTTCC

GTCCCCCTGATTTTGCCCCATATACTATTTTAGTCCG

TTCAATTGAATTTGCCCATTATTATTTTTGGACGTG

GTTCCACCTATAATACTTGCTATAACCTACAATTTAT

TTCTCTTTCCTACATCAAAAACTATGATTATCCCGCT

AAAGGACATGGCCCCACTTACAACACCTCACTAAA

ATACCCACTCACCCGCTTTTCTTAATCATTGTACCAT

CCGCCCGAGGAGCAATCTCGGGGGGACAGCGGAG

TACTACTTTAGTGTTTATGTGATGAAATAGGTACCT

GCATCAATATCTCATGTCCTGTGGATACCTAGAAAT

GAATGAAAATTATCATTCCGTATTATCCTGCTTTAG

AAGCTTGTAATATCACTGAACTTTGTTATTCTAATG

TCTTAACATGAAAAGAATCTGCATCTTGGTCTGTTT

GGACTTTGGTACTCCTAAACCCTAACGAGTCGGGC

TGATTTATATCTTTGATGCTTTTTGATTGTGTTTGGC

AGGCATATGGGCAATCCTAAGGAATAATGAAATGC

TAACCTGGCCAGAAAAAATCAAGTTTGCCATTGGC

TTGTTGCCTGCTATGGCTGGTGGACAGTCATATGTT

GAAGCACAAGATGGTTTGAGTGTCCAAGAGTGGA

TGAGAAAGCAAGTAGGAGCAGACTTTCGTTTCAGA

TTTTCCTCATTTTGTTAATCTCTTCTGATTCTGTCGAT

TACGATGATTCTAGCTGTAAACTTTGACTTTGTTGG

GACTTCAATGCTGAAATTCTGTTTGCGCATAAATGC

AGGGAGTACCTGATCGTGTAACTGATGAAGTATTT

ATTGCCATGTCAAAGGCACTGAACTTCATAAATCCC

GATGAACTTTCAATGCAGTGCATCTTGATTGCTCTG

AACCGATTCCTGCAGGCATGAGTGCCTTTCAATTTC

TGCTTTAAATTTTTTGTTTTGTACGACACTTCTTATT

GCTTGTTTTTGTGACTATTCTCGAGTAAATTTGGGA

TATAAAATGACCGTGCTGTTTTCCATAAACTGACCT

TGGGTAATGTATATCAACAGGAGAAACATGGTTCT

AAGATGGCCTTCCTTGACGGAAACCCTCCAGAGAG

GCTGTGCATGCCTATTGTTGAGCACATTGAGTCACT

AGGTGGTGAAGTTAAACTTAACTCTCGTATACAAA

AGATTGAGTTGGATCAGAGTGGAAGTGTTAAGAG

TTTTTTGCTAACTAATGGGAGGGAAATAAGAGGAG

ATGCCTATGTATTTGCCACCCCAGGTTTTCTTCTCTC

CCTTTTTTGCCATAAGGTCTCTATCAAACTCCGTAA

AAGCTACATAGTAAAGAAAATGAAGATTCCATTGC

AGATATGGACACACCGTATAGCTTAACTAGTTTTGA

TCTTGTGCAAAGCACTTGTGTTTCCAAATTTGTTAA

TGGGTTATAATTTAAATAGAATACTTATGTTTGTAA

TGTCAAGCGTTGAGCCAAAGTGTTATAACAATGAT

TATATAGTGTAGATCATCGTGTAAAATTGCGGTAA

ATTTTGGT

19

Amaranthus

Genomic
3438
CTCAAAATTGTTGAAAAATAGCCCAAGACCGACCA

rudis

TAATTCTTTTTTTTTTGATTTGCGATTCGCAGGGAG

ATTAGCGAATCATGTGACACTGTGTCTGATATAATT

TTTGAATTTCATTGTCAGTTGACATCTTGAAGCTGT

TACTACCTGATACTTGGAAGGAAATCTCATACTTCA

AAAAGCTTGAGAAATTAGTGGGCGTTCCTGTGATT

AATGTTCACATATGGTTAGTTGATTCTTCATTCTATA

TTAAATATACTCGTTAGATTTTATACCCATTTTCCGT

CTCAGGAAAAATACTATTCGCTGCAATAGAGAACG

ATAAAATGTGGATTATTTAATGCGTTGCTTTACTCC

GGGGCTAATGGTATAATAACGCTTCATGCAGGTTT

GACAGAAAATTAAAGAATACATATGACCATCTACT

CTTCAGCAGGTTGTATTTCGTTTCTTTTATCATCCTA

TTTCTCTTTCGTAACTCTCAAATAATCTCGTTCCTCC

CCTTCCCTCCTTCACTTCAACACTTGTTTCAATTCTTC

ATTTTCGGCCGTAGTCAAATTTGATGAACATTTGAC

AAGAGTTGCATTATAACTAATATGAACATTGGAGA

AGGAGCAACAATCATCATCTATGAAGTATAAGCTA

AGATTCCTTTGAAGAAGGTGAAAGTTAAGTGCGAA

TTTTCTTTCCATTGGGAAATAAGTCTTTTGATTAACG

TCTTGAATAGATGAAGGATGCAAGTTTTTGGAATG

AAGAGAAACTTTTTATGTGATCTAGTTGCGAGTCG

ATGGTGCCTTGAATTTCTTCAAAATTAAACATTTTT

GTTAATGTTCGCTTTATTGTTGCGCTTTCATGTCCTT

TTCCTATAGTTGTATATGGCTTCTCATTCTCAACTTA

GGCTTACCTCAATGCCTAAACCTTTACAAAACACAT

CATATAAGAATGAGAGTGTTGAATTGTTGATATTTA

CCTCTCCATCTCAGCACAAGTTTCCTTTACTTTTGCA

CAAATCTTAGGAATGTGTAAGTTGGTGAATAGAAA

TTACTGTTAGGGAATCTTGTGGGGCTCAAACAAAT

GAGAACCGCAAATAACTTTCTAAATATAGAAATGG

GTCACTCGTGGTGAAAAGATCCAATATGAAAATTA

GACACTTGTGCTGAGATGGAGGAAGTATCATACTT

GTAAAAACATAATACTTGAGGCTGATGTGACTTTG

GTAGTAACTAGTAACCATAGTGCAAAAATGCGGTA

ACCGGTTGCAATCACGGTAACGACACGATGATGCG

GTTATCATAACGCCAAATATCGGCCAAAAGCGTGA

GATATTCCTTCTAACAACCCAAAAACGCAGTTTTTT

TACACCTTTATATCGCAAGAAATATATGTTCGTTTTT

TGAAAATCTTTAGAACGCGGCCGTTGCGATGTGAT

GCTATGCGGCCTTATTTTTTCACTATGGTAATGACA

AAACATTTGCGGATGCACACATTGGCTACCGTTTCT

GATCCCCTTTTCATTTGTACACATCAATGTAACGTA

ATTCCCCAGCTAATTCGCCTTTTGAATTCGGAATTCT

CTCAAAATTGTGGAAAAATAGCCCAACTCCTACCAT

AATTCGCTTTTTTCGATTTGCAATTCGCGGGGAGAT

TAGCGGATCACATGACAATGATACAAATCCTATGG

ATTTATGTATGTTACTGATTTAAAGACTTCAACCCCT

TAGATTAAATGTTGAAACCATATAAGAATGGAATTT

TTAAGATTTTTTTTATCTAAATTCTTTCCTGAACCCT

ATTATTAAGTAGCTATGGCCTACTAGAGGTGGTTA

CGATTCATCATCCTTTTCATCGGCTTCATGAATTTGT

ACATATCTTGGACTTCTCCAGTTCTCCTTTAATTTTG

TTTATCTTTGTTATTTCAGGAGTCCTCTTTTGAGTGT

CTATGCTGATATGTCGGAGACATGCAAGGTGAGCA

TATTCCCATTTTTTTTATTTCCGACTTATATGTTCGTG

TTCTCCGTTTGTCTCTTTTTCGCGCATATAATATCGA

ATGTTAGCCACTCCCCGTTACTCCTTCTATTCTGCTA

ACACCGGGATTTTAACTATGAGGGTCCTCAGAATT

AATTATAAAAATTCGACAAAAACAAAAAAAAGAAA

TAAAATTGATGGGTCATAACAATTTTACTTGAGATA

TTCAACATTTATTTTACAATTTTTCTTAAGAAATTCA

GTACATCTACACTCCCGAGCCACTGCATGTGAGCG

CCGCGGCTTGCTGTTTAAGAAACCTTTCTTAGAAGT

GTCGACTATATGCAGTTTCTTCCATTCTTACGATCAT

TTACAGGAATATAAGGATCCAAATAGATCCATGCT

GGAATTGGTTTTCGCACCCGCGGAGGAATGGATTT

CACGAAGCGACACCGATATTATCGAGGCAACAATG

AAAGAGCTTGCCAAGCTTTTCCCGGATGAAATCGC

TGCCGATGGGAGCAAGGCCAAGATCCTTAAATATC

ATGTCGTCAAAACTCCAAGGTGATCGATAAACTTG

TGAAATTAAAATTGGATAATATCATGCTACCGCTAG

AAACAGCATTAATGTTGTGCCCGCGGGCTCTTTTAT

AGGTCGGTTTATAAGACAGTGCCGGATTGTGAACC

TTGTCGGCCGCTGCAAAGATCACCGATAGAGGGTT

TCTATTTAGCTGGTGATTACACAAAACAAAAATATT

TGGCTTCAATGGAAGGTGCTGTTTTATCTGGGAAG

CTTTGTGCTCAGGCTATTGTACAGGTAATCAAAGTT

TGATTAAACACCGCGGGCATGCTGATTAGACTTTTC

GTATTTTGATTCGATCCGAAATTGACCCAAAACCGA

CCGGAAATCGGTGGGTTATAATTTAGAAAATATGA

CCCGTAACCAAAAAATGACTCAAACCCACCGTAGC

CCAAATCCAATCGTTTTGACTTGTTTACCTAATTTTG

TCAACTTTTCTTGTTCCACGTCGTTAGTTTTCTGTCG

GGAGTCGGGACCCACTATCTTTCTAGTCTGTTTTTG

TATTTCTTTTTTCTTTGTTGATGCTTTTATTCGTTTTT

ACCTAGTTATGTTTATATATTTATGTGTTTTATTTAT

TTATATGTTTTTGACTACCGAGGTATGATGATTGTT

TCTATGAGCGGATATACTGAGTATGATGATGATGA

TTTATTCTTTTTTATAAAAAAAAAGTTAAAGGTCTTT

TTTTGAAAATATTTTAGTGATTTTTTTGACCTGATCA

AATTTCAATTCGAACCAAAAATAACCCAAGCGAAA

GTGACTCAACCCGAAACCTACCCTGATCTAATTGTA

ATGATAGCTTTGAAATTTTTATCGTTTTAGTTAACA

AGTTCTGTTGACGAATCTTCTTTAAATTTTTACAAGT

TAATATAAATCTCGAAAGTTCCTATA

20

Amaranthus

Genomic
2037
CAGGGAGATTAGCGAATCATGTGACACTGTGTCTG

rudis

ATATAATTTTTGAATTTCATTGTCAGTTGACATCTTG

AAGCTGTTACTACCTGATACTTGGAAGGAAATCTC

ATACTTCAAAAAGCTTGAGAAATTAGTGGGCGTTC

CTGTGATTAATGTTCACATATGGTTAGTTGATTCTT

CATTCTATATTAAATATACTCGTTAGATTTTATACCC

ATTTTCCGTCTCAGGAAAAATACTATTCGCTGCAAT

AGAGAACGATAAAATGTGGATTATTTAATGCGTTG

CTTTACTCCGGGGCTAATGGTATAATAACGCTTCAT

GCAGGTTTGACAGAAAATTAAAGAATACATATGAC

CATCTACTCTTCAGCAGGTTGTATTTCGTTTCTTTTA

TCATCCTATTTCTCTTTCGTAACTCTCAAATAATCTC

GTTCCTCCCCTTCCCTCCTTCACTTCAACACTTGTTTC

AATTCTTCATTTTCGGCCGTAGTCAAATTTGATGAA

CATTTGACAAGAGTTGCATTATAACTAATATGAACA

TTGGAGAAGGAGCAACAATCATCATCTATGAAGTA

TAAGCTAAGATTCCTTTGAAGAAGGTGAAAGTTAA

GTGCGAATTTTCTTTCCATTGGGAAATAAGTCTTTT

GATTAACGTCTTGAATAGATGAAGGATGCAAGTTT

TTGGAATGAAGAGAAACTTTTTATGTGATCTAGTTG

CGAGTCGATGGTGCCTTGAATTTCTTCAAAATTAAA

CATTTTTGTTAACGTTCGCTTTATTGTTGCGCTTTCA

TGTCCTTTTCCTATAGTTGTATATGGCTTCTCATTCT

CAACTTAGGCTTACCTCAATGCCTAAACCTTTACAA

AACACATCATATAAGAATGAGAGTGTTGAATTGTT

GATATTTACCTCTCCATCTCAGCACAAGTGTCTCCTT

TACTTTTGCACTAAATTTTAGGAACATGTAAGTTAA

TGGATAGAAATTAAAGTTAGGGAATCTTGTAGGGC

TCAAACAAATGAGAACTGCAAATAACTTTCTAAATA

TAGAAATGGGTCACTTGTGGTGACTTGATCCTATAT

GAAAATCTGACACTTGTGCTGAGATGGAGCAAGTA

TTATACTTATGAAAACATAATACTTGAGGTAGATAT

ACCTTTGGTAGGAACTAGGAACCATAGTGCAAAAA

TGTGGTAACGGTTGCAATCGTGGTCACGACATGCG

ATTATCATAACGCCTAATATGAGCCAAAAGCGTGA

GATATTCCTTGTAACGGCCCAAAACACGGTTTTTTT

TACACCTTTACATCGCGAGAAATTTCGGTTTGTTTTT

TTAGAATCTTTAAAATACGGCCGATGCTATGCGAT

GCGATGCGGCCTTATTTTTGCACTATGGTAGGGAC

AAAACATTTGCGGATGATGGATGCACACATTGGTT

ACCATGTCTGGTCCCCTTTTCACTTATACAGATCCCA

AGGGCATATGTATGTTACTGATTCAAAGACTTCAAT

CTCTAGGATTAAATGTAGAAACCATATAAAAATGG

ATCTTTAAAATACTTTTATCTTTGTTATTTCAGGAGT

CCTCTTTTGAGTGTCTATGCTGATATGTCGGAGACA

TGCAAGGTGATCATATTCCCATTCTTTTATTTCCGAC

TTATATGTTCTAGTTCTCCATTTGTCTCTTTTTCGCG

CATATAATTTCGAATGTTAGCCACTCCCCATTACTCC

TTCTATTTCTGCTAACACCGGGATTTTAACTATGAG

GGTCCTCAGAATTGATTATAAAAATTCGACAAAAA

CAAAAAAAAAGAAATAAAATTGATGGGGGCCATA

ACAATTTTACTCAAGATATTCAACATTTATTTTACAA

TTTTTCTTAAGAAATTCAGTACATCTACACTCCCGA

GCCACTGCATATGTGCGCCACGGCTTGCTGTTTAA

GAAACCTTTCTTAGAAGTGTCGACTATATGCAGTTT

GTTCCATTCTTACGATCATTTACAGGAATATAAGGA

TCCCAATAGATCCATGCTGGAATTGGT

21

Amaranthus

Genomic
1502
TGAATGTGAGAACCGACTTCTCATACTTTATTTTAC

rudis

TTACAGGTTTGGCTGGTCTATCCACAGCAAAGTATT

TAGCTGATGCAGGTCACAAACCCATATTGCTGGAA

GCACGAGATGTTTTAGGAGGAAAGGTGTGTGCTAT

ACTTTTCTTGTAGCTTATGAAACAACTCCATTGTGCT

TACTCTCTAATTAGTTTACTTCAGACTATCAGATGAT

TTTTGAACTTTTTCCTCCCTCTGTTCGGCTGTATAAT

TATATATGAGAAACATGTTTAAAAATGGGTGCATT

AACATATATGAAGTTTTTTTTATCAAGGCGAGATTT

TGTCATCCAAAAACTTTACTTCTGAACATGCTGTCT

GATCCTGTTTCTTTATCTTCATTTGTTGGGATTTTCT

TGAGGTTCATGACTACTTTCAGTTATTATAGTTACC

CATCCTGCATAAATCTGAGTTTACAGTTATAGTAAT

GAAAATAAATAGGCTAATTATATTCTCGTCGGTCAT

CACAGTATGATGAATCTTGGGCTAATATGAAGATG

AGGTAGGAAGAAGAATTTGTGTTAGTATGATAATA

TGTGCCCGCCCTAAGCAAGTGCAAGCCTTGCCTAC

GCCTAGGGCCCCCCAAAAATTTTAGTTTTCAACTAG

TGCTAACGTTCGAACTTTTCTATATATATACAATAG

TTTAGGGGCCCAAATTAGTTTAGGGGCCCAAATAA

TCTTAGGGGCCCAAATAATCTTTCGGGCCCAAATA

ATCTTTCGCCCCGGGCCCCTAAAAACCTAGGGTCG

GCTAGTGCCAAGAGAAATATTGTTGTGCAAAGTTT

CTTGGTATTTTTTCTTGTGCTTACAATTCTTGCTCCA

CAGATTGCAGCGTGGAAGGATGAGGATGGTGACT

GGTATGAGACTGGGCTACATATATTCTGTGAGTGA

TCTTTTAATTTTCTGCTTAGTTGGGTAGTTACCCGTG

TACTTATTATGTGCACTCTAGTCATGTTTATTGGAA

AAATTTACTGCATATTTATCAGTCCGATGTACTGAA

CATCTTCATATTTTCTTGAAGTTGGGGCATATCCAA

ATATCCAAAATCTATTTGGAGAACTTGGTATAAATG

ACCGATTGCAATGGAAGGAGCACTCTATGATTTTT

GCAATGCCTAGCAAACCCGGTGAATTCAGTCGCTT

TGATTTTCCCGAAGTCCTGCCTGCACCATTAAATGG

TTAGTATATCGGTGATGGTTTTTGTTGGCTGCCAAA

TTACTTGATGCAATGCATTACCTTGTAAAATACTCC

TTCCGTCCCCCTGATTTTGCCCCATATACTATTTTAG

TCCGTTCAATTGAATTTGCCCATTATTATTTTTGGAC

GTGATTCCACCTATAATACTTGCTATAACCTACAAT

TTATTTCTCTTTCCTACATCAAAAACTATAATTATCC

CGCTAAAGGACATGGCCCCACTTACAACACCTCACT

AAAATACCCACTCACCCGCTTTTCTTAATCAT

22

Amaranthus

Genomic
680
GATATTATCGAGGCAACAATGAAAGAGCTTGCCAA

rudis

GCTTTTCCCGGATGAAATCGCTGCCGATGGGAGCA

AGGCCAAGATCCTTAAATATCATGTCGTCAAAACTC

CAAGGTGATCGATAAACTTGTGAAATTAAAATTGG

ATAATTTCATGCTACCGCTAGAAACAGCATTAATGT

TGTACCCGTGGGCTCTTTTATAGGTCTGTTTATAAG

ACAGTGCCGGATTGTGAACCTTGTCGGCCGCTGCA

AAGATCACCGATAGAGGGTTTCTATTTAGCTGGTG

ATTACACAAAACAAAAATATTTGGCTTCAATGGAA

GGTGCTGTTTTATCTGGGAAGCTTTGTGCTCAGGCT

ATTGTACAGGTAATCAAAGTTTGATTAAACACCGC

GGGCATGCTGATTAGACTTTTCGTATTTTGATTCGA

TCCGAAATTGACCCAAAACCGACCGGAAATCGGTG

GGTTATAATTTAGAAAATATGACCCGTAACCAAAA

AATGACTCAAACCCACCGTAGCCCAAATCCAATCGT

TTTGACTTGTTTACCTAATTTTGTCAACTTTTCTTGTT

CCACGTCGTTAGTTTTCTGTCGGGAGTCGGGACCC

ACTATCTTTCTAGTCTGTTTTTGTATTTCTTTTTTCTT

TGTTGATGCTTTTATTCGTTTTTACCTAGTTATGTTTA

23

Amaranthus

Genomic
433
AGTTCATATTTTGTATATATGCAGGATTATGATCTG

rudis

CTGAGTTCTCGAGCACAAAGAGAATTGGCGGCGAC

AAGCAATGTATAACCCTGGATTGCTTCGACATCCGC

CATCGATTTTCATTCGGGATCATCTGATCGGTCATC

GAATAATGATCAGCTGTAAACACAAAATTATGGGG

GTTGCATACTGGTGTTCTTCAAGTTCTTAATGTATA

AATTCTCCAGAAAGAAGATTTATTTGTAATGATATA

TCAATTAAATTTATGTTGTGATAGAAATATGTATAG

CTTACTTCTAGGGAAAATTATGTTTGTACACCAGTT

AACTTGATTGAAATGTGAAGAAAGTATCAACTTTG

TCACTTGATTTACTTGTAAGTATAACATAATATCAA

TTTATACCAATACATTTATTTCCCTTTTCTGTTTAATT

AT

24

Amaranthus

Genomic
210
CAATTCGAACCAAAAATAACCCAAGCGAAAGTGAC

rudis

TCAACCCGAAACCTACCCTGATCTAATTGTAATGAT

AGCTTTGAAATTTTTATCGTTTTAGTTAACAAGTTCT

GTTGACGAATCTTCTTTAAATTTTTACAAGTTAATAT

AAATCTCGAAAGTTCCTATAAACTTATTTTACAGAT

TGTCAAGATTAGTTGTATAAAAGTGAAGT

25

Amaranthus

cDNA
951
CAATCCTAAGGAATAATGAAATGCTAACCTGGCCA

spinosus

GAAAAAATCAAGTTTGCCATTGGCTTGTTGCCTGCT

ATGGCGGGCGGACAGTCATATGTTGAAGCACAAG

ATGGTTTGAGTGTCCAAGAGTGGATGAGAAAACAA

GGAGTACCCGATCGTGTAACTGATGAAGTATTTAT

TGCCATGTCAAAGGCACTGAACTTCATAAATCCCGA

TGAACTTTCAATGCAGTGCATCTTGATTGCTCTGAA

CCGATTCCTGCAGGAGAAACATGGTTCTAAGATGG

CCTTCCTAGACGGAAACCCTCCAGAGAGGCTGTGC

ATGCCTATTGTTAAGCACATTGAGTCACTAGGTGGT

GAAGTTAAACTTAATTCTCGTATACAAAAGATTCAG

TTGGATCAGAGTGGAAGCGTGAAGAGTTTTTTGCT

AAATAACGGGAGGGAAATACGAGGAGATGCCTAT

GTTTTTGCCACCCCAGTTGACATTTTGAAGCTGTTA

CTACCCGATACTTGGAAGGAAATCTCATACTTCAAA

AAGCTTGAGAAATTAGTGGGCGTTCCTGTGATTAA

TGTTCACATATGGTTTGACAGAAAATTAAAGAATAC

ATATGACCATCTACTCTTCAGCAGGAGTCCTCTTTT

GAGTGTCTATGCTGATATGTCGGAGACATGCAAGG

AATATAAGGATCCAAATAGATCCATGCTGGAACTG

GTTTTTGCACCCGCGGAGGAATGGATTTCTCGAAG

TGACACTGATATTATCGAGGCTACAATGACAGAGC

TTGCCAAGCTTTTCCCGGATGAAATCGCTGCCGATG

GAAGCAAGGCCAAGATCCTCAAATATCATGTCGTC

AAAACTCCAAGGTCGGTTTATAAGACTGTACCAGA

TTGTGAACCTTGTCGGCCGCTGCAAAGATCACCAA

TAGAGGGTTTCTATTTAGCTGGTGATTACTACA

26

Amaranthus

cDNA
568
GGATATGCTTGTGCCACTCAATCCACATCAAGATAT

spinosus

GTTCTTTTAGGAAATTCAAATAACCCCACTTCAATTT

CATCTATTGGAAGTGACTTTTTGGGTCATTCTGTAA

GAAATTTCAGTGTTAGTAAAGTTTATGGGGGAAAG

CAAAGAAATGGGCATTGCCCTTTAAAGGTTGTTTG

TATAGATTATCCTAGGCCAGAGCTTGAAAGTACAT

CAAATTTCTTGGAAGCCGCCTACTTATCTTCTACTTT

TCGGAATTCGCCTCGTCCTCAGAAGCCATTAGAAG

TTGTAATTGCTGGAGCAGGTTTGGCTGGTCTATCCA

CGGCAAAGTATTTAGCTGATGCAGGTCACAAACCC

ATATTGTTGGAAGCACGAGATGTTTTAGGAGGAAA

GGTTGCAGCGTGGAAGGATGAGGATGGTGACTGG

TATGAGACTGGGCTACATATATTCTTTGGGGCATAT

CCAAATATCCAAAATCTATTTGGAGAACTTGGTATA

AATGACCGACTGCAATGGAAGGAGCACTCTATGAT

TTTTGCAATGCCTAGCAAGCCCGGTGAATTCAGTC

27

Amaranthus

cDNA
2070
AAAACTTTTGATTGAAGAACAAACTTTGGGGTTTTG

viridis

GAAAATGAGTCATTTTGGATATGCTTGTGCTACTCA

ATCCACATCAAGATATGTTCTTTTGGGAAATTCAAA

TAACCCCACTTCAATTTCATCTATTGGAAGTGATTTT

TTGGGTCATTCTGTGAGAAATTTCAGTGTTAGTAAA

GTTTATGGGGCAAAGCAAAGAAATGGGCACTGCCC

TTTAAAGGTTGTTTGTATAGATTATCCTAGGCCTGA

GCTTGAAAGTACATCCAATTTCTTGGAAGCCGCCTA

CTTATCTTCTACTTTTCGGAATTCGCCTCGTCCTCAG

AAGCCATTAGAAGTTGTAATTGCTGGAGCAGGTTT

GGCTGGTCTATCCACGGCAAAGTATTTAGCTGATG

CAGGTCACAAACCCATATTGTTGGAAGCACGAGAT

GTTTTAGGAGGAAAGGTTGCAGCGTGGAAGGATG

AGGATGGTGACTGGTATGAGACTGGGCTACATATA

TTCTTTGGGGCATATCCAAATATCCAAAATCTATTT

GGAGAACTTGGTATAAATGACCGACTGCAATGGAA

GGAGCACTCTATGATTTTTGCAATGCCTAGCAAGCC

CGGTGAATTCAGTCGCTTTGATTTTCCAGAAATCCT

GCCTGCACCATTAAATGGCATATGGGCAATCCTAA

GGAATAATGAAATGCTAACCTGGCCAGAAAAAATC

AAGTTTGCCATTGGCTTGTTGCCTGCTATGGCGGG

CGGACAGTCATATGTTGAAGCACAAGATGGTTTGA

GTGTCCAAGAGTGGATGAGAAAACAAGGAGTACC

TGATCGTGTAACTGATGAAGTGTTTATTGCCATGTC

AAAGGCACTGAACTTCATAAATCCCGATGAACTTTC

AATGCAGTGCATCTTGATTGCTCTGAACCGATTCCT

GCAGGAGAAACATGGTTCTAAGATGGCCTTCCTAG

ACGGAAACCCTCCAGAGAGGCTGTGCATGCCTATT

GTTAAGCACATTGAGTCACTAGGTGGTGAAGTTAA

ACTTAATTCTCGTATACAAAAGATTCAGTTGGATCA

GAGTGGAAGCGTGAAGAGTTTTTTGCTAAATAACG

GGAGGGAAATACGAGGAGATGCCTATGTTTTTGCC

ACCCCAGTTGACATTTTGAAGCTGTTACTACCCGAT

ACTTGGAAGGAAATCTCATACTTCAAAAAGCTTGA

GAAATTAGTGGGCGTTCCTGTGATTAATGTTCACAT

ATGGTTTGACAGAAAATTAAAGAATACATATGACC

ATCTACTCTTCAGCAGGAGTCCTCTTTTGAGTGTCT

ACGCTGATATGTCGGAGACATGCAAGGAATATAAG

GATCCTAATAGATCCATGCTGGAACTGGTTTTTGCA

CCCGCGGAGGAATGGATTTCACGAAGCGACACTGA

TATTATCGAGGCAACAATGAAAGAGCTTGCCAAGC

TTTTCCCGGATGAAATCGCTGCCGATGGAAGCAAG

GCCAAGATCCTTAAGTATCATGTTGTGAAAACACCA

AGGTCGGTTTATAAGACTGTACCGGATTGTGAACC

TTGTCGGCCGCTGCAAAGATCACCAATAGAGGGTT

TCTATTTAGCTGGTGATTACACAAAACAAAAATATT

TGGCTTCTATGGAAGGTGCTGTCTTATCTGGGAAG

CTTTGTGCACAGGCTATCGTACAGGATTATGATCTG

CTGAGTTCTCGAGCACAAAGAGAATTGGCGGCGAC

AAGCAATGTATAACCCTAAATTGCTTCGACATCCGC

CATCGACTTTCATTCGAGATCTGGATTGGGAATCTG

ATCATCGAATAATGATCAGCTGTAAAGAAAATTGT

GGGGGTTGCATACTGGTGCTGTTCAAGTTCTTGAT

GTACAAATTCTCCTGAAAGAAGATTTATTTGTAATG

ATATATCAATTGATAGAAATATGTATAGCTTACTTC

TAGGGAATTATGTATGTGCACCATTTGTAACTTGAT

TGAAATGTAAGTATCAACTTGGTCTCTTGATTGAAA

TGTAAGTATCAACATAATACAAATTTATACCAATAC

ATTTATTTCCC

28

Ambrosia

Genomic
1388
ATCCATACGCTCAGGTAATCTATCTTCACTTAATCCT

artemisiifolia

TAGGGTTTATATTTCCTGCTTAAGAAGGTGAGTTTA

TGTTACAATGCTTTGCTTTATTTTAACTTTATGTGTT

CGATTTCATGTTAAATCTTCACATGTTAATTGATTA

GGATTATTTTTATTCTTTTTTATTTGAATTAGCGTTA

AAATCATTTATGGATTTTTTATTTGAACCATTTATTG

TGTGGACTTCCATTTCTATAATTATCATTCAAATAGT

AAGAAAAAGGAATGAAAAGTCTAGCTTTATTTTGA

TATATATATTTTTTATCATTTCTGTAGGGCATACCAG

ATCGAGTTACTACTGAGGTGTTTATTGCCATGTCAA

AGGCATTAAACTTCATCAATCCAGATGAACTTTCAA

TGCAGTGCATTCTCATTGCTCTCAACCGCTTTCTTCA

GGTAAACTCATTTATTATACCTTGACGCTTATTGATT

TAAGTATTTTGGAATAAACTAATATCACTACAATTT

AGTTTCATTTATGTTTTCTGTATATAAAAGATGAGT

CATAAATCATTATTGTTGTTGTCTAAAGACACTGCA

ACTCCTGACTGTATTTTCAGTTATTGACTGGTATAA

AATGAATCAACAGGAAAAGCATGGCTCTAAGATGG

CATTTTTAGATGGCAGCCCACCTGAAAGACTTTGCA

TGCCAATTGTTGACCATATTGAATCACTAGGTGGCC

AAGTCAGACTTAATTCGCGGATACAAAAGATCGAG

TTAAACAAAGATGGGACTGTTAAAAACTTTTTACTG

AATGATGGGACTGTCATCAAAGGTGATGCTTATGT

GTTTGCTACTCCAGGTATGTTAATTCAAACCACTAT

TTGGCTTTGAACTTTGAAGTCTCCACATATATCTCTC

TCTGGAGTGCACAAGCTTTATTGTCTGTTTTGTATC

AAGCAGTTGACATTCTGAAGCTTCTTTTGCCTGAAG

ATTGGAAACCGGTTCCATACTTCAAAAAGTTGGAA

AAATTAGTTGGTGTTCCAGTTATAAACGTTCATATA

TGGTTAGATGGACCCTTTCAATATAATGCTAATCCT

TATAACGATAGTAGTTATGCCCTTTCACTTGTTTTAT

TGTTACCCCAATTTTCTAGGTTTGTACTAGGAAGCT

CAAAAACACTTATGATCACCTACTTTTCAGCAGGTC

ACCTCTTATTTCTTGCGTAAACATTTAATTATTTTCT

CACAAAGAATGTTGGCTTTTTTACTTTCGGCATGTG

ACCTCTTATCATTGCTGCTACTGTTGATTTATATTTT

TCTTCCATCTTTTCCAGGAGCCCTCTTCTTAGTGTAT

ATGCTGACATGTCTGTTACATGTAAGGTATACTTGT

ATGGCAATTGAC

29

Ambrosia

Genomic
268
CAATTGGACTCTTGCCTGCCATGATGGGTGGACAG

artemisiifolia

GCTGTTGAGGCTCAAGATGGACTTAGTGTCCAAGA

TTGGATGAGAAAGCAAGTATGTAATCATTTAACTT

ACTTTCTACCCTGCTATAATCATTTAATTCAGGTAAA

ACAGACTGCATATATATATATTTTTTTTATCATTTCT

GTAGGGCATACCAGATCGAGTTACTACTGAGGTGT

TTATTGCCATGTCAAAGGCATTAAACTTCATCAATC

CAGATGAACTTTCAATGC

30

Ambrosia trifida

cDNA
2016
ATTCGAAACAAGGGCCGACCAAGTTCCAACAACGA

AACAAGCCAAAAACCGTTCCAACCAACTACTACTAC

TTCATCTTCTTAATCATCATCATCTTCTCCTCCTCTTT

TAAATTAATAAAAATTAGAGCAGCAGCAGCAGCAG

CAGCAGCAATTGAGTTGATCGAGTCTCTTAGGTCA

TGTCTCTGGTTGGAAATTCTGTAGTAACGAGTCATG

TATTGTCGTTTAGTCAGGCGGGTGCTCATCGACTG

AAATTCCCGGCTGTCCGATTAAGAACCAACAACACT

GTCTACTGCCCTTTCAAGGTGGTCTGCGTCGACTAT

CCAAGACCAGACCTTGACAACACTTCTAACTTCTTA

GAGGCTGCCTACTTGTCTTCTACCTTCCGAGCTTCC

CCTCGTCCAGCTAAGCCCTTAAACGTTGTTATTGCT

GGTGCAGGTTTGGCTGGTCTATCCACTGCTAAGTA

TTTGGCTGATGCCGGTCATAAGCCCCTTTTGCTTGA

AGCAAGAGACGTTCTTGGTGGAAAGGTTGCGGCTT

GGAAAGATGATGACGGAGATTGGTACGAGACAGG

CTTACACATTTTCTTTGGAGCTTACCCAAATGTACA

GAACCTCTTTGGAGAGTTAGGGATTAATGATAGAC

TACAATGGAAGGAGCATTCTATGATTTTTGCAATGC

CAAACAAGCCTGGTGAATTTAGTCGCTTCGACTTCC

CAGATGTTTTGCCTGCACCACTAAATGGAATTTGG

GCTATCTTGAGGAACAATGAAATGTTGACATGGCC

CGAGAAAGTCAAATTCGCAATCGGACTCTTGCCTG

CAATGTTGGGTGGACAAGCTTATGTTGAGGCTCAA

GATGGACTTAGTGTTCAAGATTGGATGAGAAAGCA

AGGCATACCAGATCGAGTTACTACTGAGGTTTTTAT

TGCCATGTCAAAGGCATTAAACTTCATCAATCCAGA

TGAACTTTCAATGCAATGCATTCTCATTGCTCTGAA

CCGCTTTCTTCAGGAAAAGCATGGCTCTAAGATGG

CATTTTTAGATGGCAGCCCACCTGAAAGACTTTGCA

TGCCAATTGTTGACCATATTGAATCACTAGGTGGCC

AAGTCAGACTTAATTCACGGATACAAAAGATTGAG

TTAAACAAAGATGGAACTGTTAAAAACTTTTTACTC

AATGACGGGACTATCATCAAAGGTGATGCTTATGT

GTTTGCTACTCCAGTTGACATTCTGAAGCTTCTTTTG

CCTGAAGATTGGAAACCGGTTCCATACTTCAAAAA

GTTGGAAAAATTAGTTGGTGTTCCAGTTATAAACG

TTCATATATGGTTTGACAGGAAGCTCAAAAACACTT

ATGATCACCTACTTTTCAGCAGAAGCCCTCTTCTTA

GTGTATATGCTGACATGTCTGTTACATGTAAGGAAT

ATTATGATCCAAATCGGTCAATGTTGGAATTGGTTT

TTGCACCCGCAGAAGAATGGATTGCACGCAGCGAC

TCTGACATTATTGATGCCACCATGAGTGAACTTTCA

AGACTCTTTCCTGATGAAATTGCAGCAGATGGGAG

CAAAGCAAAAATATTGAAATATCATGTAGTAAAAA

CACCAAGGTCGGTTTATAAAACTGTGCCAGACTGT

GAACCTTGCCGTCCCTTGCAAAGATCTCCAATAGAA

GGATTTTATTTAGCTGGTGATTACACGAAACAAAA

GTATTTGGCTTCAATGGAGGGTGCTGTTTTGTCAG

GAAAATTTTGTGCCCAGGCTATTGTACAGGATTAC

GAGTTGCTTGCTGCGAGGGGGGAGGTGATGGCTG

AAGCAAGCCTGGTCTAAGATGACGTGGCAAGTTGA

AAATTGATAAAACACCCATCCATCCATAGAACTTAT

CTTGTATCTGTTACTTTATACATGCATTGATTAATCA

GTATTTGAAATAGCAATTGCTTGTGAAAAAGTTTG

GGTGATGAACACAGTTTTGACTTGTTTATAGTTTTT

TTGCTAATAACTAGTAAAGATGATCG

31

Ambrosia trifida

Genomic
2399
ACTTGTATGGCAATTGACATGTTAACTACATTACCT

TTTTTACCCCACAGACGAAAGACTGTTAAACAAGTT

GCTCATATTATTCAGGAATATTATGATCCAAATCGG

TCAATGTTGGAATTGGTTTTTGCACCCGCAGAAGA

ATGGATTGCACGCAGCGACTCTGACATTATTGATG

CCACCATGAGTGAACTTTCAAGACTCTTTCCTGATG

AAATTGCAGCAGATGGGAGCAAAGCAAAAATATT

GAAATATCATGTAGTAAAAACACCAAGGCTAGTAT

TCACATGTGCAAACCGAAGACAAATTTGTTTATTCT

GATGAAGTATTAATTAATTATTGGGTTGTGGTGCTT

CAGGTCGGTTTATAAACTGTGCCAGACTGTGAACC

TTGCCGTCCCTTGCAAAGATCTCCAATAGAAGGATT

TTATTTAGCTGGTGATTACACGAACAAAAGTATTTG

GCTTCAATGGAGGGTGCTGTTTTGTCAGGAAAATT

TTGTGCCCAGGCTATTGTACAGGTAATAAATAATTG

AGTAAGCATAAAACACAAACAAGGCGAGATTTTGT

GTGATCTCATGCATCATCTTGTTATGTTACACAGGA

TTACGAGTTGCTTGCTGCGAGGGGGGAGGTGATG

GCTGAAGCAAGCCTGGTCTAAGATGACGTGGCAA

GTTGAAAAGTAAAAAAGCCAACATTTTTTATGAGA

AAATAATTAACTGTTTTGCAAGAAGTAAGAGATGA

CGACCTGCTGAAAAGTAGGTGATCATAAGTGTTTT

TGAGCTTCCTGTCAAACCTGAAAATTGGCTGAATTA

TTATTACCTTATAAGGAAGGATTAGCATTATATTGA

AAGGGTCGGTCCATCTAACCAACCATATATGAACG

TTTATAACTGGAACACCAACTAATTTTTCCAACTTTT

TGAAGTATGGAACCGGTTTCCAATCTTCAGGCAAA

AGAAGCTTCAGAATGTCAACTGCTTGATACAACAC

AGCCAGTAAAGTAAAGCTTGTGGCCCCCAGAGAGA

AATATGTGGAGACTTCAGCCAAATGGCGGTTTAAT

TAACATACCTGGAGTAGCAAACACATAAGCATCAC

CTTTGATGATAGTCCCGTCATTGAGTAAAAAGTTTT

TAACAGTTCCATCTTTGTTTAACTCAATCTTTTGTAT

CCGTGAATTAAGTCTGACTTGGCCACCTAGTGATTC

AATATGGTCAACAATTGGCATGCAAAGTCTTTCAG

GTGGGCTGCCATCTAAAAATGCCATCTTAGAGCCA

TGCTTTTCCTATTGATTCATTGTACAGCGGTCAATA

ATTGAAAGAAAATACAGTCGCGAGTTGCAGTGTCT

TTAGACAACAACAATAATGAGCCATCTTTTTCTTTT

ATATACATAAAACATAAATGAAACTAAACTCTTGTG

ACATTAATTTATTCCAAATTACTTAATCAGTAGTAA

GCTTGAAGATAATAATAATAATAATAATGAGTTTAC

CTGAAGAAAGCGGTTCAGAGCAATGAGAATGCATT

GCATTGAAAGTTCATCTGGATTGATGAAGTTTAAT

GCCTTTGACATGGCAATAAAACCTCAGTAGTAACTC

GATCTGGTATGCCCTACAGAAATGATAAAAATATA

TATATATGCAGCTGTTTTACTTAAAAATCAACTTAT

AGCAACTTAAATGACTACATACTTGCTTTCTCATCC

AATCTTGAACACTAAGTCCATCTTGAGCCTCAACAT

AAGCTTGTCCACCCAACATTGCAGGCAAGAGTCCG

ATTGCGAATTTGACTTTCTCGGGCCATGTCAACATT

TCATTGTTCCTCAAGATAGCCCAAATTCCTATAATA

GGATGCAAATTAGAAAGATAAGATTCATAGTAGTG

GTCGGTCTGAGGTAGTTGTAGTTAGTAGATAACTT

GCCATTTAGTGGTGCAGGCAAAACATCTGGGAAGT

CGAAGCGACTAAATTCACCAGGCTTGTTTGGCATT

GCAAAAATCATAGAATGCTCCTTCCATTGTAGTCTA

TCATTAATCCCTAACTCTCCAAAGAGGTTCTGTACA

TTTGGGTAAGCTCCAACTGTGAAGCAAAGGGAAGA

GTTAGTTAAAGCAGCTGATTTTCCATCCATTATTAG

TTAGTTAGTTGAGTAAAGTAAAAACTTACAGAAAA

TGTGTAAGCCTGTCTCGTACCAATCTCCGTCATCAT

CTTTCCAAGCCGCAACCTTTCCACCAAGAACGTCTC

TTGCTTCAAGCAAAAGGGGCTTATGACCGGCATCA

GCCAAATACTTAGCAGTGGATAGACCAGCCAAACC

TGCATAATAATAATAATAATAAGCAAATGAAAGTG

AGGAGAAAGAAAGAAAGAAAGAAAAGGGGTGGG

TACCTGCGCCAGCAATAACAACGTT

32

Ambrosia trifida

Genomic
2377
AAATATTAATGGTTGGTGCATATGCGCCTCGAGTG

AAGGCAAAGGAAGCAACACCAACAATGTCAAAGT

CTTATTTCCAGGTAATATGAAAAGCAAAGGAAGCA

ATCAAAAGAAATTTCTTGGACGAGCTGATGCAAAT

TATCCCAACATTAAAAAAATTTTGTATACTGCCGAA

CATGTAGCCATCCATCACAAACACGTAGTCCTAGAT

CTTCATATGTGATCAACCTCGTGCAAGAATAAACTT

CAAAGACAAAGAAAAATCAAATGATAGAACCCAAA

ATAAGAGGATACGAATTTTTCATTTGATTAGACAAA

TGAGGAAGATCCAAATCCAACTTGGACAAAGATGA

AGAATGTTATCACCCGCACAACTAGGGGAATTCAA

GGTTAAGCGGATTGTGGTATGAGGTAAGAAAGAA

TACAATATAGGGGAATTAGGAAGTAAAGGAATAA

GAAAAAAAAGAATGATATATAGCTTTAGGAAAATC

TAGGAGTGAGGAGAATATAGCAAAATATGAGGAA

GTTAAAACCAAGACGAAGCAAGCGATATGTGAGA

CAAAGTTAAAAGAGTATTAAGAGATATACAATAAG

CTGACTCAAGAGAAGAGGATAATGATCTTTGTAGG

ATAGCCTGAAGGAGACAAATGATTATAAAAGATAC

TAGTTGAATGAACTATGAAGTGTGTCTTGGATAAA

TAACAAAATAATATTCTCCAAGATGAATAGATATAC

GATAAATGGAAGGAGTTTTTTGACGAGTTGTGCAA

TGGATGTCAAGGGGCACGATAGAATACATCTTGAA

GGAATTCTGAAAAGGTGCTTTTCTAGGAATGTAAA

TTGTGAGAAAAGGAAGAAGGCGATCATCGGTAAA

TCAATTGTCTTTGCTCACAAAATGTGACACCAACAT

GTTGGATGGGGGAGAGAAGTTTTCAATGTTAACTA

CTCTTTCGGTTATGTACGTAAGTATGTTTTTTTATGA

GGCATCTTGTTCAAGAGCTCATCATTAATATAGAG

GAGCAAAAACTTACAGATACCATCTTATGGACCAA

GCATATATTGTTCACAAATAGATTCAAAACCTTTTA

TATCTTCAAATATGAATGTGAGAAATGACTTCTCTT

ACTTTTTTTACTTCCAGGTTTGGCTGGTCTATCCACG

GCAAAGTATTTAGCTGATGCAGGTCATAAGCCCCT

TTTGCTTGAAGCAAGAGACGTTCTTGGTGGAAAGG

TTGCGGCTTGGAAAGATGATGACGGAGATTGGTAC

GAGACAGGCTTACACATTTTCTGTAAGTTTTTACTT

TACTCAACTAACTAACTAATAATGGATGGAAAATCA

GCTGCTTTAACTAACTCTTTCCTTTGCTTCACAGTTG

GAGCTTACCCAAATGTACAGAACCTCTTTGGAGAG

TTAGGGATTAATGATAGACTACAATGGAAGGAGCA

TTCTATGATTTTTGCAATGCCAAACAAGCCTGGTGA

ATTTAGTCGCTTCGACTTCCCAGATGTTTTGCCTGC

ACCACTAAATGGCAAGTTATCTACTAACTACAACTA

CCTCAGACCGACCGACCACTACTATGAATCTTATCT

TTCTAATTTGCATCCTATTATAGGAATTTGGGCTAT

CTTGAGGAACAATGAAATGTTGACATGGCCCGAGA

AAGTCAAATTCGCAATCGGACTCTTGCCTGCAATGT

TGGGTGGACAAGCTTATGTTGAGGCTCAAGATGGA

CTTAGTGTTCAAGATTGGATGAGAAAGCAAGTATG

TAGTCATTTAAGTTTTTTTATCATTTCTGTAGGGCAT

ACCAGATCGAGTTACTACTGAGGTTTTTATTGCCAT

GTCAAAGGCATTAAACTTCATCAATCCAGATGAACT

TTCAATGCAATGCATTCTCATTGCTCTGAACCGCTTT

CTTCAGGTAAACATTTTCTTTCAATTATTGACCGCTG

TACAATGAATCAATAGGAAAAGCATGGCTCTAAGA

TGGCATTTTTAGATGGCAGCCCACCTGAAAGACTTT

GCATGCCAATTGTTGACCATATTGAATCACTAGGTG

GCCAAGTCAGACTTAATTCACGGATACAAAAGATT

GAGTTAAACAAAGATGGAACTGTTAAAAACTTTTT

ACTCAATGACGGGACTATCATCAAAGGTGATGCTT

ATGTGTTTGCTACTCCAGGTATGTTAATTAAACCGC

CATTTGCCTGAAGTCTCCACATATTTCTCTCTGGGG

GCCACAAGCTTTACTTTACTGGCTGTTTTGTATCAA

GCAGTTGACATTCTGAAGCTTCTTTTGCCTGAAGAT

TGGAAACCGGTTCCATACTTCAAAAAGTTGGAAAA

ATTAGTTGGTGTTCCAGTTATAAACGTTCATATATGG

33

Ambrosia trifida

Genomic
2057
GTCATCTCTTACTTCTTGCAAAACAGTTAATTATTTT

CTCATAAAAAATGTTGGCTTTTTTACTTTTCAACATG

TCACCTCTTATCATTGCATTGCTGCTACTGTCGATTT

ATATTTTTCTTCCATCTTTTCCAGAAGCCCTCTTCTTA

GTGTATATGCTGACATGTCTGTTACATGTAAGGTAA

TACTTGTATGGCAATTGACATGTTAACTACATTACC

TTTTTTAACCCACAGACGAAAGACTGTTAAACAAGT

TGCTCATATTATTCAGGAATATTATGATCCAAATCG

GTCAATGTTGGAATTGGTTTTTGCACCCGCAGAAG

AATGGATTGCACGCAGTGACTCTGAAATTATTGAT

GCCACCATGAGTGAACTTGCCAAGACTCTTTCCTGA

TGAAATTGCAGCAGATGGGAGCAAAGCAAAAATA

TTGAAATATCATGTCGTCAAAACTCCAAGGTGATC

GATAAACTTGTGAAATTAAAATCGGATAATATCAT

GCTACTGCTAGAAACAGCATTAATGTTGTGCCCGC

GGGCTCTTTTATAGGTCGGTTTATAAGACAGTGCC

GGATTGTGAACCTTGTCGGCCGCTGCAAAGATCAC

CGATAGAGGGTTTCTATTTAGCTGGTGATTACACA

AAACAAAAATATTTGGCTTCAATGGAAGGTGCTGT

TTTATCTGGGAAGCTTTGTGCTCAGGCTATTGTACA

GGTAATAAATAATTGAGTAAGCATAAAACACAAAC

AAGGCGAGATTTTGTGTGATCTCATGCATCATCTTG

TTATGTTACACAGGATTACGAGTTGCTTGCTGCGA

GGGGGGAGGTGATGGCTGAAGCAAGCCTGGTCTA

AGATGACGTGGCAAGTTGAAAATTGATAAAAACAC

CCATCCATCCATAGAACTTATCTTGTATCTGTTACTT

TATACATGCATTGATTAATCAGTATTTGAAATAGCA

ATTGCTTGTGAAAAAGTTTGGGTGATGAACACAGT

TTTGACTTGTTTATAGTTTTTTTGCTAATAACTAGTA

AAGATGATCGATTTAATGAGAGAAGATCTACTATG

GTATGACGGCTTTAATAAACAACTTCAGTCCTAACC

ATAACTAGGTATCAAATTTATGAATAAACATCACAG

CTCACAGCTAAACATTCAGCTTTGATATCTATATGA

AATCTCAGATGCTTTCTAATTAACTTCTCCAGGACC

AATTGGATTCTTTAAGTTTGTAGGAGTGTAGTTGA

GTTGGCGGTTCAAATTGATATCCCAACCATATTAGC

AGGTCCACATGTATTTATTTATATGTTTCATTTTCCA

TTCAAACAGTTGCTGTTGAAGGTACTAGTTAAGTCT

GCTGTTAAACAAGTAGATTGCAGATAACTTTGAGC

ATCATCAAGTTATATATACCGAATAGGATGCTTTTG

AAAGACATGAGCCGGAAAAAACGCTATGAGGTTG

ATCATACATTTTGTACGCACGTAAAACACAAATACA

AGGCAAAATAATAGTGTCTACAGACGACTGACTGA

TTACAGGTACACTAACCACATCTGTATTTCAAGGCT

GTGTGTTTTTATGTTTGCCCTTGTATCCGTAAATTAC

GGAGCCAATTGACCACTTCCTTAATCGTTGGCCGCT

TGGCGGGGTTAACATTTATACACATGCAGGCAACA

TCCCTTCTTGAAGCCCATTGCCCGGGTCAAATACTT

GATACTGTTTCCCTTCGGCTCTCAGTTGAAGCATCC

ACACAACCAGTTCTCATGAATGCTTGGACCTGAGC

CTAAATATCTCTATCTTGTAGGTAGCTCTAGCATCA

CAATCCCAAAACTATTCATTATCCCCTTTTAAGGTG

GCTATCAATAGACTGGCTGTACTCTGCTGGGATAT

ACCACCCATTAGTGGTGACATAGGTATTATAGTGTT

AGATCAGTCTAGACAACCCAAAATTGGCAAAACTA

CGCTTCAAACTGTGATGTATCTGATACTTAGTAGCT

ACTAACTATCTGGTCAGGAAACGGACGGTTTGCGG

TGTCAAGGAGCCAAAGGTATCAAA

34

Ambrosia trifida

Genomic
1401
TGTTTGTATCAAGCAGTTGACATTCTGAAGCTTCTT

TTGCCTGAAGATTGGAAACCGGTTCCATACTTCAAA

AAGTTGGAAAAATTAGTTGGTGTTCCAGTTATAAA

CGTTCATATATGGTTGGTTAGATGGACCGACCCTTT

CAATATAATGCTAATCCTTCCTTATAAGGTAATAAT

AATTCAGCCAATTTTCAGGTTTGACAGGAAGCTCA

AAAACACTTATGATCACCTACTTTTCAGCAGGTCGT

CATCTCTTACTTCTTGCAAAACAGTTAATTATTTTCT

CATAAAAAATGTTGGCTTTTTTACTTTTCAACATGTC

ACCTCTTATCATTGCATTGCTGCTACTGTCGATTTAT

ATTTTTCTTCCATCTTTTCCAGAAGCCCTCTTCTTAG

TGTATATGCTGACATGTCTGTTACATGTAAGGTAAT

ACTTGTATGGCAATTGACATGTTAACTACATTACCT

TTTTTACCCCACAGACGAAAGACTGTTAAACAAGTT

GCTCATATTATTCAGGAATATTATGATCCAAATCGG

TCAATGTTGGAATTGGTTTTTGCACCCGCAGAAGA

ATGGATTGCACGCAGCGACTCTGACATTATTGATG

CCACCATGAGTGAACTTTCAAGACTCTTTCCTGATG

AAATTGCAGCAGATGGGAGCAAAGCAAAAATATT

GAAATATCATGTAGTAAAAACACCAAGGCTAGTAT

TCACATGTGCAAACCGAAGACAAATTTGTTTATTCT

GATGAAGTATTAATTAATTATTGGGTTGTGGTGCTT

CAGGTCGGTTTATAAAACTGTGCCAGACTGTGAAC

CTTGCCGTCCCTTGCAAAGATCTCCAATAGAAGGAT

TTTATTTAGCTGGTGATTACACGAAACAAAAGTATT

TGGCTTCAATGGAGGGTGCTGTTTTGTCAGGAAAA

TTTTGTGCCCAGGCTATTGTACAGGTAATAAATAAT

TGAGTAAGCATAAAACACAAACAAGGCGAGATTTT

GTGTGATCTCATGCATCATCTTGTTATGTTACACAG

GATTACGAGTTGCTTGCTGCGAGGGGGGAGGTGA

TGGCTGAAGCAAGCCTGGTCTAAGATGACGTGGCA

AGTTGAAAATTGATAAAAACACCCATCCATCCATAG

AACTTATCTTGTATCTGTTACTTTATACATGCATTGA

TTAATCAGTATTTGAAATAGCAATTGCTTGTGAAAA

AGTTTGGGTGATGAACACAGTTTTGACTTGTTTATA

GTTTTTTTGCTAATAACTAGTAAAGATGATCGATTT

AATGAGAGAAGATCTACTATGGTATGACGGCTTTA

ATAAACAACTTCAGTCCTAACCATAACTAGGTATCA

AATTTATGAATAAACATCACAGCTCACAGCTAAACA

TTCAGC

35

Ambrosia trifida

Genomic
649
TGCCAATTGTTGACCATATTGAATCACTAGGTGGC

GAAGTCAGACTTAATTCACAGATACAAAAGATTGA

GTTAAACAAAGATGGGACTGTTAAAAACTTTTTACT

CAATGATGGGACTATCATCAAAGGTGATGCTTATG

TGTTTGCTACTCCAGGTATGTTAATTAAACCACCAT

TTGGCTTTGAACTTTGAAGTCTCCACATATTTCTCTC

TGGGGTCCATAAGCTTTGCTGGCTGTTTGTATCAAG

CAGTTGACATTCTGAAGCTTCTTTTGCCTGAAAATT

GGAAACCGGTTCCATACTTCAAAAAGTTGGAAAAA

TTAGTTGGTTTTTCAGTTATAAATGTTCATATATGGT

TAGATGGACCCTTTCAATATAATGCTAATCCTTATA

AGATAATAATAATTCAGCCCTTTCACATTTTTTATTG

TGAACCCAATTTTAAGATAATGAATTACTACTCTTT

CGCTTGTGTACAACCATTCCAGATGATGTTTTTGAG

GATTATGAATCACAAGCAATGTATGCATCTACTGAT

ATAATGTGGTTAATCAAGGTAATGTCAACTTTCTCC

AAATTTCATTGTGGCTAATAAGTCAAAATGGGTTC

GCGCTGGTTGAGTCAAATTAAACCAGGTTGGATTA

AGTC

36

Ambrosia trifida

Genomic
631
TTTCTTTTCTGTCTTTCTCCTCACTTTCTTTTGCTTATT

ATTATTATTATTATGCAGGTTTGGCTGGTCTATCCA

CTGCTAAGTATTTGGCTGATGCCGGTCATAAGCCCC

TTTTGCTTGAAGCAAGAGACGTTCTTGGTGGAAAG

GTTGCGGCTTGGAAAGATGATGACGGAGATTGGT

ACGAGACAGGCTTACACATTTTCTGTAAGTTTTTAC

TTTACTCAACTAACTAACTAATAATGGATGGAAAAT

CAGCTGCTTTAACTAACTCTTCCCTTTGCTTCACAGT

TGGAGCTTACCCAAATGTACAGAACCTCTTTGGAG

AGTTAGGGATTAATGATAGACTACAATGGAAGGA

GCATTCTATGATTTTTGCAATGCCAAACAAGCCTGG

TGAATTTAGTCGCTTCGACTTCCCAGATGTTTTGCC

TGCACCACTAAATGGCAAGTATGCTATTATTTACTA

ACTACCTCATGCTATTACTTACTATGAATCTTATCTT

CATTCTAATTTGCATGTTATTATAGGAATTTGGGCT

ATCTTGAGGAACAATGAAATGTTGACATGGCCCGA

GAAAGTCAAATTCGCAATCGGACTCTTGCCTGCAA

TGTTGGGTGGACAAGCTTATGT

37

Ambrosia trifida

Genomic
540
CAACGAAACAAGCCAAAAACCGTTCCAACCAACTA

CTACTACTTCATCTTCTTAATCATCATCATCTTCTCCT

CTTTTAAATTAAATAAAAATTGAGCAGCAGCAGCA

GCAGCAATTGAGTTGATCGAGTCTCTTAGGTCATG

TCTCTGGTTGGAAATTCTGTAGTAACGAGTCATGTA

TTGTCGTTTAGTCAGGCGGGTGCTCATCGACTGAA

ATTCCCGGCTGTCCGATTAAGAACCAACAACACTGT

CTACTGCCCTTTCAAGGTTATTTTCTTCTTCTTCTTCT

GTCTGTAATTCTGTATATATAATATGGTAATGGTAA

TTTCCCCCCTCCCCTCCCCTCTCTTATTGCTTATTCTA

TTCTATTTATGTGAAATTAATATATAATAATAATAAT

AGGTGGTCTGCGTCGACTATCCAAGACCAGACCTT

GACAACACTTCTAACTTCTTAGAGGCTGCCTACTTG

TCTTCTACCTTCCGAGCTTCCCCTCGTCCAGCTAAGC

CCTTAAACGTTGTTATTGCTGGTGCAGGTACCC

38

Conyza

cDNA
2432
CGGAGAGACTTGCCTAACACACGAACTCCAAGTAC

canadensis

AAATTCATCACCATATAAAAGTGTCACATATGCTTC

TTCTTCTTCTTTTGATGATCCAGCTGGAGCTCCTTCC

ACAATTATCTCATTTAATAATAATAATAATAATCCTA

CTAACCCAAACCCTAATCTCCTCAATTTCATTTTTTA

ATCTAATAGTCTGATTATTAAGAGATTATAAGGAG

ATTAGAAATGAGGTTTTTGTTATACAATAAGATATT

ATTGTATTTTTAATCTTTTTTAAGTTTTTTGGAATTAT

TTTGGGGGTTTATGATAGAAATTGTGGCAACTGAA

TTTTTGGTGGGTTTTTTGAGAATTTGATTTTAAGGG

CTGGTGTTTGTCTGATCATCTGCAGCGAGCTGATA

GTATTATTATTATGTCTCTTTTTGGAAATGTCTCTGC

CATTAACCTAACTGGAAACTGTCTGCTATCAATCAC

TAGTTCCAGAGATGTTTTGTCATTTCGGCACGGTGA

TACTATGGGTTATCGCTTGCAATCCCCCCCTTCTTTT

ATTACCAAAACTAACAAAAATGTCTCCCCTTTGAAG

GTAGTTTGTGTCGACTATCCAAGACCAGACCTCGAT

AACACCTCTAATTTCTTGGAAGCTGCTTATTTGTCTT

CTACCTTCCGAGCTTCTCCACGCCCACCTAAGCCAT

TGAAGGTTGTAATTGCTGGTGCAGGTCTCGCTGGT

TTATCAACTGCAAAGTACTTGGCTGATGCCGGTCAC

AAGCCAATTTTGCTAGAAGCAAGAGATGTTCTTGG

TGGAAAGGTAGCTGCCTGGAAAGATGATGATGGA

GATTGGTACGAGACTGGTTTACACATATTTTTTGGA

GCTTACCCGAATATACAGAATCTGTTTGGAGAGTT

AGGCATTAATGATAGATTGCAGTGGAAGGAGCATT

CAATGATATTTGCGATGCCAAACAAACCTGGAGAA

TTTAGTCGGTTTGATTTCCCAGATGTTCTGCCGGCA

CCATTGAATGGAATTTGGGCTATCTTGAGGAACAA

TGAAATGCTGACATGGCCTGAGAAAGTAAAATTTG

CTATCGGGCTCTTGCCTGCAATGTTAGGTGGACAG

GCTTATGTTGAGGCACAAGATGGTCTGAGTGTTCA

AGACTGGATGAGACAACGGGGCATACCAGATCGA

GTTACTACAGAGGTGTTTATTGCCATGTCAAAGGC

ATTAAACTTCATCAATCCAGATGAACTTTCAATGCA

ATGTATTCTGATTGCTCTGAACCGATTTCTTCAGGA

GAAGCATGGTTCTAAGATGGCATTTTTAGATGGCA

GCCCACCTGAAAGACTTTGCATGCCAATTGTTGAG

CATATTGAGTCACTAGGTGGCCAAGTCAGGCTTAA

TTCACGAATACAAAAGATCGAGTTGAACAAAGATG

GAACAGTTAGGAACTTTTTACTTTATGATGGAAATA

TTATTGAAGGTGATGCTTATGTATTTGCTACTCCAG

TTGATATTCTGAAGCTTCTGTTGCCTGAAGATTGGA

AAGCAATTCCTTACTTCAAGAAGTTGGATAAATTAG

TTGGTGTCCCAGTTATAAACGTTCATATATGGTTTG

ACAGGAAACTCAAAAACACCTATGATCACCTACTCT

TCAGCAGGAGCCCTCTTCTCAGTGTATATGCCGACA

TGTCTGTAACATGCAAGGAATACTATGATCCTAACC

GGTCCATGTTAGAGTTGGTTTTTGCACCTGCAGAA

GAATGGATTTCACGCAGTGACTCTGATATTATTGAC

GCTACGATGAGTGAACTTTCAAGACTATTTCCGGAT

GAAATTGCAGCAGATCAGAGCAAAGCAAAAATATT

GAAATACCATGTAGTTAAAACCCCAAGGTCAGTTT

ACAAAACTGTACCTGACTGTGAACCTTGCCGTCCAT

TACAAAGATCTCCATTAGAGGGATTCTATTTAGCTG

GCGACTACACGAAACAAAAGTATCTGGCTTCAATG

GAGGGTGCTGTTCTATCAGGAAAATTTTGCGCCCA

AGCGATTGTAAAGGATTATGAGTTGCTTGCTGCCA

GGAGGGAAGTGGTTGCTGAGGCAAGCCTTGTCTA

ACTGTATAGATGCAAGATAACTTGGTAAGTTAAAA

ATCAGTTGAAGACAAGAGCACGTGGTTCTTTGCAT

ATTTGACTTTTTATGGTCCTTGGCTGAAGTGGTAGG

CTTAAGGAGGTGGCAGAATTTCTGGGAGGAGCTTT

TACAAGTTCAGAAGAAGCTAAACATAAATACACCC

ATAGCAATTCATTGTTCTAACTGAAACTTATTTCATA

TTTGTCAAAGAAAAAAATACATATTCCTGTTATGTA

CATAGTTGGTTATTTTCCCTTGTTTTATACGTCATGT

GTGGCATCGAATCTATTGATTATCTATACGTATTAT

ATGTGGCA

39

Conyza

cDNA
2206
ACAACATCCCTTGTTTCCTCTTCTTCTTGTTTTCTTTT

canadensis

TCTTTCTTTTTGCTAAAAAACTCACACACGCAGAAG

AAGAAGACGAAGACAAAGTCAGAGAGTTGAGTTT

GGACTGATTGATTGATTTGTTATTAAGGGCTGGTG

TTTGTCTGATCATCTGCAGCGAGCTGATAGTATTAT

TATTATGTCTCTTTTTGGAAATGTCTCTGCCATTAAC

CTAACTGGAAACTGTCTGCTATCAATCACTAGTTCC

AGAGATGTTTTGTCATTTCGGCACGGTGATACTATG

GGTTATCGCTTGCAATCCCCCCCTTCTTTTATTACCA

AAACTAACAAAAATGTCTCCCCTTTGAAGGTAGTTT

GTGTCGACTATCCAAGACCAGACCTCGATAACACCT

CTAATTTCTTGGAAGCTGCTTATTTGTCTTCTACCTT

CCGAGCTTCTCCACGCCCACCTAAGCCATTGAAGGT

TGTAATTGCTGGTGCAGGTCTCGCTGGTTTATCAAC

TGCAAAGTACTTGGCTGATGCCGGTCACAAGCCAA

TTTTGCTAGAAGCAAGAGATGTTCTTGGTGGAAAG

GTAGCTGCCTGGAAAGATGATGATGGAGATTGGT

ACGAGACTGGTTTACACATATTTTTTGGAGCTTACC

CGAATATACAGAATCTGTTTGGAGAGTTAGGCATT

AATGATAGATTGCAGTGGAAGGAGCATTCAATGAT

ATTTGCGATGCCAAACAAACCTGGAGAATTTAGTC

GGTTTGATTTCCCAGATGTTCTGCCGGCACCATTGA

ATGGAATTTGGGCTATCTTGAGGAACAATGAAATG

CTGACATGGCCTGAGAAAGTAAAATTTGCTATCGG

GCTCTTGCCTGCAATGTTAGGTGGACAGGCTTATG

TTGAGGCACAAGATGGTCTGAGTGTTCAAGACTGG

ATGAGACAACGGGGCATACCAGATCGAGTTACTAC

AGAGGTGTTTATTGCCATGTCAAAGGCATTAAACTT

CATCAATCCAGATGAACTTTCAATGCAATGTATTCT

GATTGCTCTGAACCGATTTCTTCAGGAGAAGCATG

GTTCTAAGATGGCATTTTTAGATGGCAGCCCACCTG

AAAGACTTTGCATGCCAATTGTTGAGCATATTGAGT

CACTAGGTGGCCAAGTCAGGCTTAATTCACGAATA

CAAAAGATCGAGTTGAACAAAGATGGAACAGTTA

GGAACTTTTTACTTTATGATGGAAATATTATTGAAG

GTGATGCTTATGTATTTGCTACTCCAGTTGATATTCT

GAAGCTTCTGTTGCCTGAAGATTGGAAAGCAATTC

CTTACTTCAAGAAGTTGGATAAATTAGTTGGTGTCC

CAGTTATAAACGTTCATATATGGTTTGACAGGAAA

CTCAAAAACACCTATGATCACCTACTCTTCAGCAGG

AGCCCTCTTCTCAGTGTATATGCCGACATGTCTGTA

ACATGCAAGGAATACTATGATCCTAACCGGTCCAT

GTTAGAGTTGGTTTTTGCACCTGCAGAAGAATGGA

TTTCACGCAGTGACTCTGATATTATTGACGCTACGA

TGAGTGAACTTTCAAGACTATTTCCGGATGAAATTG

CAGCAGATCAGAGCAAAGCAAAAATATTGAAATAC

CATGTAGTTAAAACCCCAAGGTCAGTTTACAAAACT

GTACCTGACTGTGAACCTTGCCGTCCATTACAAAGA

TCTCCATTAGAGGGATTCTATTTAGCTGGCGACTAC

ACGAAACAAAAGTATCTGGCTTCAATGGAGGGTGC

TGTTCTATCAGGAAAATTTTGCGCCCAAGCGATTGT

AAAGGATTATGAGTTGCTTGCTGCCAGGAGGGAA

GTGGTTGCTGAGGCAAGCCTTGTCTAACTGTATAG

ATGCAAGATAACTTGGTAAGTTAAAAATCAGTTGA

AGACAAGAGCACGTGGTTCTTTGCATATTTGACTTT

TTATGGTCCTTGGCTGAAGTGGTAGGCTTAAGGAG

GTGGCAGAATTTCTGGGAGGAGCTTTTACAAGTTC

AGAAGAAGCTAAACATAAATACACCCATAGCAATT

CATTGTTCTAACTGAAACTTATTTCATATTTGTCAAA

GAAAAAATACATATTCCTGTTATGTACATAGTTGGT

TATTTTCCCTTGTTTTATACGTCATGTGTGGCATCGA

ATCTATTGATTATCTATACGTATTATATGTGGCA

40

Conyza

Genomic
15961
TAGTGTAATTTAATTATTAATATTAAGAGAATAGTG

canadensis

TATGTGAAAATCTTTTAAAGGTTTGTAGGCTTGTAG

CCTTGTAGGTGAAAATATTACATAGGAGGGCATTT

TAGACATTTCCCCATGTAACTTTCAACATGGAGGGT

ATTTTCTTTAATATAGAGTATAAATAATGGAGATAT

TTTAAAAAAATAAAGGACTGATAGTGTAATTTAATT

ATTAATATTAAGAGAATAGTGTATGTGAAAATGTTT

TAAAGGGTTGTAGGTTTGTAGCCTTGTAGGTGAAA

ATATTACATAGGAGGACATTTTAGACATTTACCCCA

TGTAACTTTCAACATGGGGGGTATTTTCTTTAATAT

AGAGTATAAATATAGATAAATAATATATATTTTGTA

AATTTTTTAAACTAATAAATTATTTTAAAATAATAAT

TTTTATAAAATATATTTTATTTGATAAATAATAACTC

TAAATTACACAGATGGTACCTATAATTTGTATTATA

TTACATGTTTCATACCTCACATACAAGACACGTTGG

CTACTTAATGATACAACTAACGACCGTCAGCGTGA

GGTATCTTCTAAGTGTAAAATTGTAAACATGATATA

ATTGACGTAATTTAAATCTAACAGGTATGAAATTAA

TAATTTCGACCAAACCAAAGGTACTTAATTCACTCT

TAATATACTGTATCTAATACTACTCGTGGTAGTATT

ATGTAGATTCCTAGCAATGGACGACAATATTCCAAC

AACATAAGAAGCCAAAACCCACTTCCTTCCTTTTTTT

TTTTTGTTGTTGAATAATTTAATCAGTTTTTAGGAAC

GAACAACCTCCTCCATTTCCAGATAAATTATTATTCA

GCCAAGCAAAAAACACAACATCCCTTGTTTCCTCTT

CTTCTTGTTTTCTTTTTCTTTCTTTTTGCTAAAAAACT

CACACACGCAGAAGAAGAAGACGAAGACAAAGTC

AGAGAGTTGAGTTTGGACTGATTGATTGATTTGTT

ATTAAGGTAAAAATACCACTTACTACTCCATCCATC

CATCCATAGTAGACTGGTAGTTGTATTAGTAGTAGT

TAGCTGCTGCTTTGGTTATTAGGATTAGGATGAAG

AAACTAGCAGATTGTTAAGTATTCTTCATGTGACTT

TGTTATCTTCCTTTGTAAACAATCTCCCCCAAATATA

ATAGCATATCGACTAAGTGGTAATATACTTATTTTT

TTTTTAAGTTGATGGTGAACTATTGTATATGGCAGG

GCTGGTGTTTGTCTGATCATCTGCAGCGAGCTGAT

AGTATTATTATTATGTCTCTTTTTGGAAATGTCTCTG

CCATTAACCTAACTGGAAACTGTCTGCTATCAATCA

CTAGTTCCAGAGATGTTTTGTCATTTCGGCACGGTG

ATACTATGGGTTATCGCTTGCAATCCCCCCCTTCTTT

TATTACCAAAACTAACAAAAATGTCTCCCCTTTGAA

GGTACAACCTCTGCCACATGTATTTCATTATCACTC

ACAAAATCAATTCTAATGTCTTTGTTTATCTGTGCTA

AACAGGTAGTTTGTGTCGACTATCCAAGACCAGAC

CTCGATAACACCTCTAATTTCTTGGAAGCTGCTTAT

TTGTCTTCTACCTTCCGAGCTTCTCCACGCCCACCTA

AGCCATTGAAGGTTGTAATTGCTGGTGCAGGTAAA

ACCTTCATACGTCATTATATTGTCTTTTAAGTCGCTT

TTGTTTGAGAATTTGATACTGCCACATCTGATAGAT

AACCAAATGATACTTCTAGTGTATCCCCAATGATGC

TTTTTATGCCACATACTAACATCTGCTTTAATTTGCT

ATCCCACTTACTTTTGCAAACTTCGCATATGCAGGT

CTCGCTGGTTTATCAACTGCAAAGTACTTGGCTGAT

GCCGGTCACAAGCCAATTTTGCTAGAAGCAAGAGA

TGTTCTTGGTGGAAAGGTAAACGATTTATAAGAAA

TTACAATAGGATCGGAAGTCCTAGGATCCCCCCTCC

CTCTTACCTTCTTCTATATAACAGAGCAAGCTTGGT

AATAAAACAAGGATTTTGGGTCTAATTATTCTCTTC

TTTACTTGCTTTCTGTTTTCGTCTCTTTCACTGATAAC

CAAAGGCAATATCAGTTAGGGTTCTAGGATGGGTC

GAAGCAAATTTTAGGGATACCAATGCCTAACCAAG

TTCGATCAAGACTAGGGATATAGAGGGTATTCAAT

CAGCTTCTGGTGGGATTATAGCTCGCGACTTTGAA

GCTAGAGTTAGGGTTCTTTAAAGCCTAACATAGTTC

AAATACGGCTGGGGTGTTGGGGGTTCCTTTCTGTA

CGAATTTAAAGCTGGACAAGGCAGCAAAAGAGTTC

GACTTGTGTGGATTTTTATCTAGGTTTGGCTGGGGT

TTCAAACAACCGAAGGTGTGTTTGGGGTTCTTGGG

ATAGTCGATCAACATTGGAGTGTCTTTTTCCTGTTTT

ACAAGTTAGAATACGTGAAATGCATCTTCGTTCATT

ATTTTGCTTTTGACCTTTATGTGATGGGTACAAGTT

TAACAACCTACTGCATGCGGTTTCTCTTTGTGCTCA

CATTTCACTTTCTCTCTTTTCTCTTTTGCATTGTTGGG

GTGGGATGGCTGTTTTTGCTAGTAACATTTATACAA

ACCTGGACCTAATGTTAGGTCAATCCGGGCTGGGT

TCACAACTGGATGGAGGAATAAGGGTCGGAGGGA

AATATTGAATGGCTCCTCAAACCCAAAGTAACCCA

GATCCAAACACTTCCAATCTAAACAACCCAGACCCC

GTGGCTGCTCAATCAACAGCCATAGCATCATCTATG

AAATCACTGCAGCAAAGAGGTAGCAATGATCAAGA

CACAGTAAGCCAAACAAAAACAGAAATCAAGCGG

CAATTTAAATCAATTTGAAGATGAAGGTTCATCTGG

TGGTAACCACCGTCACTACAGACCTTATAATAATAT

CGATTTCCCAACTTTTAGTATTGGAGAACTGTTTAC

AAGGCTATGAGTATTGCTATCGAGTTTGAATCCAA

GGTTCACATGAAATTTAGGAAAAGTTTTTCGTCTTC

AGCCAAAACAGAATCAGTACCTTCGAAACCAATAG

AAACTTCCAACCTGTTGCCCTCGATTGCTGCTGCCC

AGAAACCAACTGAAGCCCGTCTTTTTGATGTTAAAA

AATAGGGCAGATTCATACGAGAAGTTGTGTCTAAG

TTTCTGATCTACTCAAAATTTCTATCAATTTGCCTTG

GGGGAAAGCCGATGTGGTACTCGGTATTCAATAAT

TAGGAACACTTACAAAGTTTAGGCAAAATGGAAGG

AGATAGTCATGAAGTTCACTATGGATGTTAAGGAG

TACAAGCTACATGGACTTCCACCAGATCGTCAACCA

TCAGCAACATTTAGCGACCTCACTACTGAACCATTC

GAGTTACAGGCAAGTGGACTAGCAGCTCATTTTTT

CACAACTGGCTAGTGGACAAGTCAGATTTTGGGGC

CGGATGTATTGATACAAACCTGGACCCAATGTTGG

GTCAAACCAGGTCGGGTCAGCAGCTGGATGGAGG

GAAAAGGGGTGGAGGGAAATCAAGTAGTGAAGG

AATTCAAGTTAGGAAGTGGACCATGCGCCCACTAC

ATATAATTGCTCCACTAATTTTAGTATTATATATGTG

TGTTTTTCTGTTTTTTAAGCTGGTCAAGATACTAAGT

TTGTGATTGTTCTTGTATTCGGAGATTTGCCATCTG

AATTTTGCTAATATTGTGTTAGACTCAGTAATCTAA

ATTAGTAGATTTCCAGTTTCTATCAAATGTTCGTTTG

GCGAAAATGAATAATTGAAGTTCATATGACGACCT

TATTTGAGCAGGATCTGTTCTATAGGCTCGTACCTC

TGTATCCTTGATTCCTATCAAGACAGAAAAGTAGTT

TCATATGAAATTTCTATTTTTAAACTTTTGTATATCA

TAAGTAGTCAAGCTTAGCTTAATTTCAAATCTAGGT

TGTCTTAGTATGTTGTTACTTATCGTGAGTGTTTTTA

TCCACATTGCTCTTCTCACATAGGTAGCTGCCTGGA

AAGATGATGATGGAGATTGGTACGAGACTGGTTTA

CACATATTTTGTAAGTTTTAACTTCTTATATCCTTTC

AAGTGTCGAAAAAGAGAGCTGATGTGTGCATAAA

AAGTTATTCCCATAATATAATTCTCAACAGGGTTGT

TGTCGTCTTTTTGTGCACTATCTATCTGCTCTAAGTT

ATTGTTTCTCCACGTACCTTTCCTTTTGGACATTTGT

CACTAGACACCTAATGTGCAATAAACTTCTTCATTT

GCTTGAAGTTGGAGCTTACCCGAATATACAGAATC

TGTTTGGAGAGTTAGGCATTAATGATAGATTGCAG

TGGAAGGAGCATTCAATGATATTTGCGATGCCAAA

CAAACCTGGAGAATTTAGTCGGTTTGATTTCCCAGA

TGTTCTGCCGGCACCATTGAATGGTAAGTATGCTAT

TATTAGCCTATTTTTTTTGGTGTATATATTTTATTTA

AATGATTTGGTGGTGAGCATTTTCTGCATCACCAAC

ATGACAAAAAAGATCTAAAACAAGATCAGTCAGGG

AATGCTAGATTACTAACAAATGTGACTCTGCATACC

ATCTCAGGAATTTGGGCTATCTTGAGGAACAATGA

AATGCTGACATGGCCTGAGAAAGTAAAATTTGCTA

TCGGGCTCTTGCCTGCAATGTTAGGTGGACAGGCT

TATGTTGAGGCACAAGATGGTCTGAGTGTTCAAGA

CTGGATGAGACAACGGGTATGTAGTCGTTTATGTA

AATATTTCTTTTACCATTTTTTAGTTTAATACATAAG

AAACAATGGCCATGATACCTGGTATATTTGATAAT

GGTAACGTTTCTAAGTGGAAGATCCAGAGGTCAAA

CCTTAGCAGGGGCTTTTTTTAGGAAGATTGTTGGCT

AATTAAACCCCCTGCTTAATAATTCGAGTTCTTGTTT

CTTTTGTTATGAATTTTATTTAATAATTAATGCACAT

TTTTCATTTTTCCAGGGCATACCAGATCGAGTTACT

ACAGAGGTGTTTATTGCCATGTCAAAGGCATTAAA

CTTCATCAATCCAGATGAACTTTCAATGCAATGTAT

TCTGATTGCTCTGAACCGATTTCTTCAGGTGAAGGC

ATCATTCTCTTAGAGCTTACTGGTTAAATAATGATG

AAAAATTAATCTCATGACTTTTAATTCCATCTTCCGT

CTGTCATATATGATAAGTTGGTCACGGACTCAAGTC

ACTAATATATTATATGGATTGATTTTACGCTTGTGA

TTGGTCAAGTAGACAAAGCATGCAAAGTTATATGG

GTTTAGTGTAATTAGTGTCTGTTGCATTGCTCACTG

TATGTCTGTATTGGTTGCTATAAGCCAGCGTGCTAC

CTTGAAAGCAACTCTATTTCCTTTTCCATGATCAAGT

ATTATTACATATATATTGTGCTTCTAGAATCCAGAT

ACAGAGATTTGGGTTATTTTTGTGGTTTTGAAATAG

GAGGGCGGCCTCTATAGTTAATCTCGAAGTGCTTA

TTGTACACCATGGATTTTTGAAACAAAGAGTTGATC

GCTCTTATCTGTAGCTTCTTAACACTTCAATATTGGC

TTGGTTGCAATACTACATGGCATAGACATTGGACA

CCATAGATAATACAACTTGTAAATTGTTTGTAATAA

ATCAACAGGAGAAGCATGGTTCTAAGATGGCATTT

TTAGATGGCAGCCCACCTGAAAGACTTTGCATGCC

AATTGTTGAGCATATTGAGTCACTAGGTGGCCAAG

TCAGGCTTAATTCACGAATACAAAAGATCGAGTTG

AACAAAGATGGAACAGTTAGGAACTTTTTACTTTAT

GATGGAAATATTATTGAAGGTGATGCTTATGTATTT

GCTACTCCAGGTACATTTAGAGAACGACTATTTGA

ATCTGTAGCTTTCACATGTCTGTTGGGGTTGTAGCT

TTATTGATTATTTTGTGTCAAACAGTTGATATTCTGA

AGCTTCTGTTGCCTGAAGATTGGAAAGCAATTCCTT

ACTTCAAGAAGTTGGATAAATTAGTTGGTGTCCCA

GTTATAAACGTTCATATATGGTTAGTTGGATCCTTC

AATATAATTCTAAACATGGCACAGTAATCATTCACC

TTAATTTAATAGAGTCTGGCTTCTGTCTTGACCATT

AATCTGACTTAGTAAAACCCCTATATGTATTCTTTGT

AATTGTTAAACACCACTTTCAGGTTTGACAGGAAAC

TCAAAAACACCTATGATCACCTACTCTTCAGCAGGT

CACCTCTCAACTCTTATTCTTGCAACACTATTACTTA

ATTTTTAGTAGACAAGGCTGTTGAGCTTTTTATTTG

TATGTTATTCATGCCACTGCTACCTAAACGGATCTT

TTACTTCCATTTCAAATGTCTGGGGCGTGTCGTCCA

TAAAGGTTCTCTACAGTTCATAGAGTAACTTAGAGT

AAGCTTACACCCCACCTATTAACTAAACAAAGCAAC

ACAAGTTAGGCTATATGGTACATGCTAAAGTGATG

GTCAAGATTGCACCATTTGCTACCGCCTTGAGATAC

CAGTGTCCCAGCTTCTGCTTACACTTCATAGTTTATA

CTCAAATTTAATATTGGTACAAAAAAGAGTACTGA

ACCTATCAGTTTAGTCTTTTGTATTAATTATTTAGTT

TGCATGCAGGAGCCCTCTTCTCAGTGTATATGCCGA

CATGTCTGTAACATGCAAGGTAAAGACAAGACAAA

CATATATGAAACAAACCATTTTCTTCCAGACAAACC

TGCTTTGCTGTTTTCATATGGTTCCTTGTCATGCAAA

CAATGAGGAGATGGATGTCTATTGGCCTCTCCTCTC

ATTCCTATTTTCCCGGAAAATGGGTTAAATCTGTCT

TTGTAATTTTATCTTTGTCGCATGCATGGGACATAA

CTTCTCACAATGCACATAACTCAAATATTTACCAAA

ACCTCCCGCATTTTTAAAACCAGGCTATATATAAGT

TGTAAATTACATGATGTGAACCCATACCTCCCATCA

AGGTTGTTCTGATAATAGTGCTCCCATTTTATACAG

GAATACTATGATCCTAACCGGTCCATGTTAGAGTTG

GTTTTTGCACCTGCAGAAGAATGGATTTCACGCAG

TGACTCTGATATTATTGACGCTACGATGAGTGAACT

TTCAAGACTATTTCCGGATGAAATTGCAGCAGATC

AGAGCAAAGCAAAAATATTGAAATACCATGTAGTT

AAAACCCCAAGGTTAGAAATATCTTACCAGTAAGG

GGTTTTCAACGATTCGGTTTACGAGCTCTTCGCTTT

GGTTTCCTTGATTTGACAATCCTTGAAGCTCAAACC

AAAAACCAAATCAAACCGAATTAATCAGAAACAAG

CCAAACCAAATAAGATGGTTTGGTTTTGGTTCGAAT

GCGATTGAAACCAAACCATTTTCAAATAATGCAGAT

TTTATGCTGGCAAATGTTATCTAAACTTTTTGGCAA

ATGAAAATTTGCTGAGATTCATTTACCACCAAAAAC

TTACTATATGAAAAGAAATATATAATGTATTATAAA

CTTACATTATAAGTTATTTTAAATTAATTTGATAGG

AAATATATATATATATATATACACACACATGTATAT

ATATATAGACCAATTCGGTTTTCGAATTGGTTTTGT

TTAAAAAGCAACAACTCGTAAATCAAATTATCAAAC

CATAAACCGAATTTCAAAATCAATTTGTTGTCAAAC

CAAACTAAAAACTCAAAAAAACCAAATGAATTTCA

ATAAATTTTTATTTCAATTTGGTTTGATAATTGGTTT

CATCGACTTGGATCCGTACACTGAACACCCCTACTT

ACATGTACTAGTACTTTCTGTAGATTACTTAGCATG

TGAACACCTTCATGTTTCACCCATCTGTGAACGTTG

TAAACTTAATTTTTGTACAGTTGTATCTGCGATATAT

ACTAGTTTGTGACCCAATAGATAGATTTATTAATTA

TCATATAGTTATGTAATTATATTTCCATGTATTGTTT

ATTCTATTTCATAATTGTGTAACAGGTCAGTTTACA

AAACTGTACCTGACTGTGAACCTTGCCGTCCATTAC

AAAGATCTCCATTAGAGGGATTCTATTTAGCTGGC

GACTACACGAAACAAAAGTATCTGGCTTCAATGGA

GGGTGCTGTTCTATCAGGAAAATTTTGCGCCCAAG

CGATTGTAAAGGTAATGTTAAAGCAACTCGTAGCT

GGTAGTTTTAGAATTATTTAGCAAGTGAAAGTATTT

TTCTCTGCTGCTTTTTAGAGTAGTGCAATTTGCAGC

AGACGAATTTTGGGTATGTGTTTATAAGTGACCAT

AAAAAGACAAAGTAGCCTACATATTCTGTTGCTCAT

CTTCTGATGCATCATGTAACACAGGATTATGAGTTG

CTTGCTGCCAGGAGGGAAGTGGTTGCTGAGGCAA

GCCTTGTCTAACTGTATAGATGCAAGATAACTTGGT

AAGTTAAAAATCAGTTGAAGACAAGAGCACGTGGT

TCTTTGCATATTTGACTTTTTATGGTCCTTGGCTGAA

GTGGTAGGCTTAAGGAGGTGGCAGAATTTCTGGG

AGGAGCTTTTACAAGTTCAGAAGAAGCTAAACATA

AATACACCCATAGCAATTCATTGTTCTAACTGAAAC

TTATTTCATATTTGTCAAAGAAAAAAATACATATTC

CTGTTATGTACATAGTTGGTTATTTTCCCTTGTTTTA

TACGTCATGTGTGGCATCGAATCTATTGATTATCTA

TACGTATTATATGTGGCATGTTTTTTTTTAATTTTGC

ATCCTGATCTTTGATTACACTTTTCAAGATTTATTCA

CTTTGCTTCCATGGCATACAAGAAAACAATATCAAT

ACAGCGAGCTATCTATTATCTAACTTGGGAGATGC

AGGTGCATGAGAAGTGCTCAAAACTTCAACTACTT

GGTGGGATTAAGTTGAAGTGACACTAACCCAGGTA

CCAACCTCATCCCGAAAATCTGTGAATATTTTCTTTT

TATTCGTCTTAGTTAAAAAAAGAAAAAAAAGAAAC

AGATGATGCACCAGTTCAATACTTTTTGTTCGATAC

CTTGATTATTTACCAAATGAGACACACTGTATGTCT

GTATGTGCTTTCATCTTGTTTCATTTTGTGGGAATGT

GGAGTAACAGGTATAAGAATAGCAATAACACAAGT

CTAGTTGCTGAAGAGTGTGAGCAGAGTAAGATTTT

GGTATGATACCAAGTAAAGTAAATGCGTAGAGAGT

AAGGTTTAGGTGATTCCTTAATGAAATGGGAACCT

TGTGATTGTCAATGAGTTATTAATCCATTGAATTTG

AAATTTCACAACGTGAAATAACTTGTGCTCTTACAA

AATGTTTTGTGGTCATATATTTACCAATACATGTGT

CTTCTTGGACACTAAAAAAAATAGATAGCTGGTGA

AGATACTATATAATTTAATAATAAGATAAGATAGC

GTCTACTTTGCTGAAAAGTCAAAACTGGATTACCAA

ATCTCATTCTCACGTGTCAAAATTTGACAGGATCTT

TTGAAATTCACTTGTTGGACATTGGCACTGGATCAT

GCAAAGGGATCACATTTCTCTTCAAGCCTTATCCCA

TTCCCAGCTATAGATACCATAAATATAAACGCTGGA

AGTGCAGTATTGAATTACCTGATTTATGTTTTTGGA

TGTGGGGGGTTTTAGGAGGTGATATGTAATCAAAA

ACTTAACCCAATCCATTCAAAGATTGTGTGTTGTGA

TATGACCTAAAGAAAGTGAGAGAGAGAGAGATTA

TTCTTAATTCTAAAGTAATAAATTGTGAAGGCAAAT

AAGCCGACAGCATGTTCCTGATACACATATCCATCA

CAACATCCCCTCCCAACTTTGTCACTTCCATTTTACT

CCACACTATATATACGCACACCTCTTTCAACAATGG

CTTCTACTGTACAGAACATCCCCACTTTTTTGAGCTT

TTTCACGGTGTCTGCATGAAGTTAAGAGTTTGACAT

CTGCTCGCATTCACCCCCCCTTTGGCCTTGATTTCTT

CCCACATATAACTTCAAACTTAATTAATGAATTGAA

TGCGACCCGACTCTTTTCCATGCAAATCAGTGGTCA

CTTATCAATGTTGATTGTTGACTCGATCCCATCTATA

AATACCCCTTCTTACCATTTTCTCTCTCAGGGTCCCA

GCTCCACATCTGTGAGGCTTTTTTTCTTTTGGTCCCA

AATCTTTCAAAAAAACACAAACAGAAAATGGCAAC

AGCTTTACAAACAAAGATAGAAGGGAATCGTATTA

CAACAAAGTGTGCTTCCTTAGTAAAGAAACAGCGA

GCTCGTATATATATCCTACGTCGTTGTGCCACCATG

CTTCTCTGCTGGTACATTCAAGGAGATGAATAAATA

GTTGATGCTATGACACAAACAACAGACATGTTTTTA

TCCTCGATTCTTATAGTCTCTATATCCCTTTTTTCACA

TCAACTCATGTGGCTCCCGTTTTCGGTTCTTTTCTTT

GGCTTATACATATTCTTAAATATGCATGCCCTAAAC

TTCCATCTTTTTAACACCAACGGTCCGTTGCATTTAA

AGGCTGTTGGGTCTTGTCTCATTTTCTACTCCCTAGT

TTTTGTCATGTCTTGTTTATCTTGACCTCTCTTCATTT

GTCCTGTTTAAAACACTTTTTTTATCCAAATGGTTTT

CATTTGGGTTTTTTGGGCATCTGCATCAGAGGACA

ATTTCAACTTTAGACATGGACCAGAAACGGGGATA

TGACCAGCATGAAGGAAGCAATCTTGCATCAAGTT

GGCAGCTTGAAATGAAGGTTCTACAATAACATCTT

GCGTTGTGTCATGGTTTGTAGATAATTGTCTCCGCT

GAAAATAAATGACGGTTCCTCACTTCCTTGATATGT

AAAGCACTCATAAAATGATTAATAATTCGGTGCTGC

TACAAATATATATGTTGAAGCGCACTAAATCTGAA

GTTGTGATTTATTCATCGGGATGTTTTTTTCTTTTTA

ATAATGACTTTTTCATCATTTAAGTTGACATATACA

GCACCCACTAATGCTAATATCTTAAATCTCCACATTT

CCCTTGCAATCACCAAGACAACTTGCTGTTAGCATA

ACCAGACACTGCTACTAACTTTAACCATCAAAAGCA

CATAATCCCGCAGGTCTTCAAATCCAAATGAGGCC

GGACATCATAGAACTTGTAATTTTAACTCACATAGA

AGTTTGATAGTGTGATATATGACAAGGGCAGATGG

TAATAAGTAGAGCTAGCAAATCCTTTTCATATTGTT

AATCCTCTCTCAAAATGGACGAGGAAGCTCTAAAA

CTGCAGAAAACAAACTTTTACAAACGAATTTAAAG

CTTTAAGAGGGAATAAGGAACAGGCATGTCATTGA

AGAATGCTATCTATTTATTATGGAAGATCTGTGACC

TTAAAATCCCATAAATATGATATGTGTCGGATCGTC

CAGAATGAAAAGTAGCTCAAGTTGTTAGAAATGTT

AAGTAGACACAGATGTTGTATGGAACTATGGAAGT

TCACTTATCTACTGTAATGAGCTTCCATCTCTCCCAA

TGAATTCCAAAACCCTGACTCACCTTCAAATTAATT

CCAGCTCGTGAACCAAATTTGTGATTCTGGACACCA

ACCCTTATCAAAGAATTTAATTAAATTGGCAATTGA

CTTGAGATGTTTGAAATTCAATTTTAGAGAATAGAA

GTTTCATACAATCAACGAATGAACTTTATTACATCT

GTGTATTTTAACAGCGTACGTTTCCTGCTTAACTCG

AGTGCTGGATCCAACCCATATCAAAATACGCATGTT

ACCGGCGCATCTGGTCTAGTCTGATTCCATGGATAC

ATGTTCCGTGTTCCGTTCAGAAGGTTATGTTTCTAC

CAGAAGACAGTTACAGGTACTGGTTAACAAGTCTA

TTGTAAATCATATACTTTTACAATGGCATTGATGTA

TCTGTTAACATAGTGGAAGATGCGGTACAAAGGAA

TATGAACAGGCTTCTTTGTGAAAGATGTATCTATTC

AACAGCCAGCCATAGCTGGAAAAAGTGTCTCTATA

GTCTATATACATTAATGCACGGTCATCAGGTAAAAA

TTCCTTTGCAAAAAGGAACCACAAACAAAAAGCAA

AGGCGAGTAAAAAAAAAAAAGAACCTAAGTGAGA

GATTGCCTGCACAGACAACTAATTACAATGTACATT

GACTCGCACACTTCGCAATGACACAATACTCTGATT

TCTATATATATGTGTATGTGCATTTACATTTGCCCTT

TATTTTGGTATCCGATGGTTGGGCCCAACATTATGG

AGCCAATCAACCACTTCATTAATGGTTGGCCTCTTG

ACGGGGTTTACGTTCACACACATACAGGCGACATC

AAGAACCTGCAGCATCTCTTCTTCAAATCCCTTGTC

TCTCAGGATCTCATCAAATATTTGATCCTGTTTCCCT

TCTATTCTAAGTTGTTGCACCCACACAACCAATTCTC

TAGACGCCTTTGGCCGGAATACCTCCATGGGCCTCT

TTCCTGTAAGCAGCTCAAGCATGACAACCCCAAAA

CTGTATATGTCCCCTCTCAAGGTGGCTATCCATGAC

TGGCTGTACTCCGGTGGAATATACCCCAGGGTGCC

CACCAACTCAGTCGTGACGTGTGTATTGTATGGAT

GAATCAATCTAGACAATCCAAAATCGGCCACGTAT

GCTTCAAATTGGTCATCCAGAAGGATGTTACTTGAT

TTGATGTCACGATGCACGATATGTGGTTCGCATACT

TGGTGCATATAAGCCAGTCCACAACTTGCTCCCCG

GGCGATCTTCAATCTCGTTGGCCAATCGAGCCTGG

ATGCTCCGTCAGCCTTCTCATGTAGCCAGTAGTCCA

AGCTTCCATTTTCCATATACGAATAAATCAGCAGCT

GACATCCATCATGTACACAGTACCCTTGTAAAGAAA

CCAGATTTTTGTGATGGGCAGTTGATAATGCCTCCA

CTTCTGCTTTAAACTCCCTTGCAATGAGGCCCATAT

CTCCTGAAAGTTTCTTGACAGCCAGTTTTGTTCCGT

TCGCCAAAGTTGCTTTGTAAACCAATCCAAAGCCCC

CACATCCAATGATGTTTGCTTGACTGAAATCTTCGG

TTGCTTTCAAAATATCAGTTATGGTTAGATGTTTGA

TGTCTTTTGCATTGTGCGGGAACAATATGACTCCGC

TGGTATCCTTGGGAACCTCTACGGCCGACGTAGAA

TTGAAGGACACCGTGTCCATATGGAAGACTTCCGG

GTCACCTCTGGGGAGAATCCTTCTTTTGGACAATAT

CCACAGTGCCAGACAAGCCAGAGTGATGCCAACCC

CAAAACAGATGCCCAGGATGAGGCCGACGATGAG

TTTCTTGTTTGGGCCTTTTTCATGTGGCGAGGAAGC

GTCTGTTTTGGGTGATAGAGGATTATTTTCATCGTT

GCAAAGGTTTTGCATGGGTGGACCGCACAACCCTG

GATTGCCTTCGTAGTTCTGGTTCAAGAAGGTGTCA

AACTGTCCCCCGGTCGGTATGGAACCTTGTAGCTT

GTTGTAAGCGACGTTGAAAGAAGACAGAAAGTAC

AAGCTTTTGAGGGAGGCAGGGATCTGACCAGACA

GATTGTTATGGGAGAGGTCCAGCTTTTCCAAGTTT

GTGAGATTTGAAATGGTAGCGGGAATGGAGCCAG

AGAAATTGTTTAGGCTGAGATCAAGTGTATGAATG

GACTGCATATTACCAATCTCAACAGGTAGGCTGCC

ACCGAGTTGATTGCTTGACAGGTACAATGCTGGAG

GCAGGGTGGCCAGCTGATTGTACTGCAAGTAGGAT

GCATTTTGAGGGGCAACGAATACAGGGAGTTCCA

GGTAACTGCTGTTTACACGGTCCAAAACCTGCTGC

GATGCGAGGGCTGGGAGTCTGGTAAGCTCCACAG

GGAATCCCCCGGATAGAGAATTATTAGACAGGTCC

AGATAGAAGAGGTTCGGAAGCGTGTGTAGCCAGC

CCGGAATGACGCCGTCGATATTATTCTGGGAGAGG

TCGATGACCTCCAGATTGGTAAGGGAAGAGAGCCA

CGTGGGGATCTGACCGAACAGCTTGCAGCCACCAA

GACCCATGATCTTGAGATTGGAGAAACCAGAGATG

GGTTGAGGGGGGAGGGGTTCGTTGAAGAAGTTCT

TGGAGAGGATGAGGGTGGTGAGTTTCGGATGCCT

GCTCAGGATATTGAATGCGCTTGTGATGTTCCTGA

GGGTGTTGTTTGAAAGGGAGAGGAAGGAGAGAG

CAGGCAGGCCGAGGACATGAGCGGGGATTTCCCC

TCGCAGCCTGTTGGTGGCCAGCCGGATTGCGGTGA

GCGATTTGCAAGAGAAGACGGTGGCCGGCAGCTC

CCCTGCGAATCGGTTTTCGCCAAGGTCAAGGATGG

TGAGCCTGGTGAAACCGGAGAAATCAAAATCCGA

GAGAATGCCGGTGAAGGAGTTGACCCTGAGATTG

AGAAGCTGCAGGGATTTGCAGTTGACGAGGGAAG

GAGGAAGGGTTCCATTGAGACGGTTGATGTGAAG

TTCAAGTTTCTGCAACAAGGGGAGGTTGCCAATGG

CGTGGGGGATGGGCCCGCTAAAGTTGTTGCCAAAC

AAGGCAAGAGTGGTGAGGTTGGTGAGGGTGGTGA

TGGAATCGGGAATGGGGCCGGTGAGAGAGTTCCC

AGGGAACGATAGATGGCGGAGGGAAGGGGTGGT

GGAAACGTGGAAAGGGGCAAGGGCGCCGGTGAG

GTTGTTAAACCCCAGACTCAAAACCTGGAGGGAAG

CACAGGGGCCCGACAAAGGGGGGAAATCCCCGGT

GAAGTCGTTCAAGGAGAGATCGAGGATGGTCAGA

TTAGAGTTGCATATGGTGGAGGTGGGGACGGGGC

CTGTCAAGGTGTTGTTGCTGACATTGAGGGCAATC

AAAGAAGGGAAAGAAGGGAAGAAGGTAGGCGGA

ATCGTGCCATTCAGATAATTACTGGACAGATTCAG

GGTGGAGATGGTGGTCGTGGTGGGTTGTGGCAGG

TTCCCAGAAAGTCTGTTGTAACTTAAGTCAACGGTG

TGGAGATGGTTGAAAAATTGTGGTGGGAGGGGAC

CAGATAGGAAATTACAGGACAGGTTTAGGAAAGA

TAGGGATGTCAGATTTTCAAGAGGGGCATAATAAT

CATTGTAATTGGTCGTAGTAAGGCCTCTATTTGGTA

AGGAAATCCCGACCACACGGTGACCTTGATCATCA

CAACTGATTCCATCCCACAAACAGCAATCTTCTCCT

TCCCCATTGGCAGCAGCCCAGTTGACGACGCTGGG

AAAGTTGTTGCCAAAAAGCAACAGAGAATCCTTAT

CATCAGAGTTACAAGCTGCTGCTGCTGTCGTCCTTG

TACAAGCAGGAAACAACAAAACTAACACTAACACT

AGTATCATCAACAAACCCCTCCCCACATGATCATGC

TCACGATTATGATTGAATGATGAACAACAACACGG

GACCAACAGCATCATCAACAACCAAACCAAACCAC

ACCACACCACCCACCCACAAACAAACAAAGATATA

TATATATATATATATATTACTTTTTGTTTCTAAAAAG

AAAGAAGAAAATTATGAAGAGAAAAAGACGACGA

TAATGGTAATAATCCCATTTCAATTCAAAGAAAGAA

AGAAAAAATACAAGTGGATGTTGACGCAGACCATT

AGTAAAAAAAAAAAAAAAGAGAAGGGCATCAAAT

CAAATCAAATCAATTGAATAAATTATATAATTAGAA

AAAATTACAAATAGAGAGGGTGTTTCTATTCATTTA

TCCATTATTATTATTATTATT

41

Conyza

Genomic
9016
ACACACACATGTATATATATATAGACCAATTCGGTT

canadensis

TTCGAATTGGTTTTGTTTAAAAAGCAACAACTCGTA

AATCAAATTATCAAACCATAAACCGAATTTCAAAAT

CAATTTGTTGTCAAACCAAACTAAAAACTCAAAAAA

ACCAAATGAATTTCAATAAATTTTTATTTCAATTTGG

TTTGATAATTGGTTTCATCGACTTGGATCCGTACAC

TGAACACCCCTACTTACATGTACTAGTACTTTCTGT

AGATTACTTAGCATGTGAACACCTTCATGTTTCACC

CATCTGTGAACGTTGTAAACTTAATTTTTGTACAGT

TGTATCTGCGATATATACTAGTTTGTGACCCAATAG

ATAGATTTATTAATTATCATATAGTTATGTAATTATA

TTTCCATGTATTGTTTATTCTATTTCATAATTGTGTA

ACAGGTCAGTTTACAAAACTGTACCTGACTGTGAA

CCTTGCCGTCCATTACAAAGATCTCCATTAGAGGGA

TTCTATTTAGCTGGCGACTACACGAAACAAAAGTAT

CTGGCTTCAATGGAGGGTGCTGTTCTATCAGGAAA

ATTTTGCGCCCAAGCGATTGTAAAGGTAATGTTAA

AGCAACTCGTAGCTGGTAGTTTTAGAATTATTTAGC

AAGTGAAAGTATTTTTCTCTGCTGCTTTTTAGAGTA

GTGCAATTTGCAGCAGACGAATTTTGGGTATGTGT

TTATAAGTGACCATAAAAAGACAAAGTAGCCTACA

TATTCTGTTGCTCATCTTCTGATGCATCATGTAACAC

AGGATTATGAGTTGCTTGCTGCCAGGAGGGAAGT

GGTTGCTGAGGCAAGCCTTGTCTAACTGTATAGAT

GCAAGATAACTTGGTAAGTTAAAAATCAGTTGAAG

ACAAGAGCACGTGGTTCTTTGCATATTTGACTTTTT

ATGGTCCTTGGCTGAAGTGGTAGGCTTAAGGAGGT

GGCAGAATTTCTGGGAGGAGCTTTTACAAGTTCAG

AAGAAGCTAAACATAAATACACCCATAGCAATTCA

TTGTTCTAACTGAAACTTATTTCATATTTGTCAAAGA

AAAAAATACATATTCCTGTTATGTACATAGTTGGTT

ATTTTCCCTTGTTTTATACGTCATGTGTGGCATCGA

ATCTATTGATTATCTATACGTATTATATGTGGCATG

TTTTTTTTTAATTTTGCATCCTGATCTTTGATTACACT

TTTCAAGATTTATTCACTTTGCTTCCATGGCATACAA

GAAAACAATATCAATACAGCGAGCTATCTATTATGT

AACTTGGGAGATGCAGGTGCATGAGAAGTGCTCA

AAACTTCAACTACTTGGTGGGATTAAGTTGAAGTG

ACACTAACCCAGGTACCAACCTCATCCCGAAAATCT

GTGAATATTTTCTTTTTATTCGTCTTAGTTAAAAAAA

GAAAAAAAAGAAACAGATGATGCACCAGTTCAATA

CTTTTTGTTCGATACCTTGATTATTTACCAAATGAGA

CACACTGTATGTCTGTATGTGCTTTCATCTTGTTTCA

TTTTGTGGGAATGTGGAGTAACAGGTATAAGAATA

GCAATAACACAAGTCTAGTTGCTGAAGAGTGTGAG

CAGAGTAAGATTTTGGTATGATACCAAGTAAAGTA

AATGCGTAGAGAGTAAGGTTTAGGTGATTCCTTAA

TGAAATGGGAACCTTGTGATTGTCAATGAGTTATT

AATCCATTGAATTTGAAATTTCACAACGTGAAATAA

CTTGTGCTCTTACAAAATGTTTTGTGGTCATATATTT

ACCAATACATGTGTCTTCTTGGACACTAAAAAAAAT

AGATAGCTGGTGAAGATACTATATAATTTAATAATA

AGATAAGATAGCGTCTACTTTGCTGAAAAGTCAAA

ACTGGATTACCAAATCTCATTCTCACGTGTCAAAAT

TTGACAGGATCTTTTGAAATTCACTTGTTGGACATT

GGCACTGGATCATGCAAAGGGATCACATTTCTCTTC

AAGCCTTATCCCATTCCCAGCTATAGATACCATAAA

TATAAACGCTGGAAGTGCAGTATTGAATTACCTGA

TTTATGTTTTTGGATGTGGGGGGTTTTAGGAGGTG

ATATGTAATCAAAAACTTAACCCAATCCATTCAAAG

ATTGTGTGTTGTGATATGACCTAAAGAAAGTGAGA

GAGAGAGAGATTATTCTTAATTCTAAAGTAATAAAT

TGTGAAGGCAAATAAGCCGACAGCATGTTCCTGAT

ACACATATCCATCACAACATCCCCTCCCAACTTTGTC

ACTTCCATTTTACTCCACACTATATATACGCACACCT

CTTTCAACAATGGCTTCTACTGTACAGAACATCCCC

ACTTTTTTGAGCTTTTTCACGGTGTCTGCATGAAGT

TAAGAGTTTGACATCTGCTCGCATTCACCCCCCCTT

TGGCCTTGATTTCTTCCCACATATAACTTCAAACTTA

ATTAATGAATTGAATGCGACCCGACTCTTTTCCATG

CAAATCAGTGGTCACTTATCAATGTTGATTGTTGAC

TCGATCCCATCTATAAATACCCCTTCTTGCCATTTTC

TCTCTCAGGGTCCCAGCTCCACATCTGTGAGGCTTT

TTTTCTTTTGGTCCCAAATCTTTCAAAAAAACACAAA

CAGAAAATGGCAACAGCTTTACAAACAAAGATAGA

AGGGAATCGTATTACAACAAAGTGTGCTTCCTTAG

TAAAGAAACAGCGAGCTCGTATATATATCCTACGTC

GTTGTGCCACCATGCTTCTCTGCTGGTACATTCAAG

GAGATGAATAAATAGTTGATGCTATGACACAAACA

ACAGACATGTTTTTATCCTCGATTCTTATAGTCTCTA

TATCCCTTTTTTCACATCAACTCATGTGGCTCCCGTT

TTCGGTTCTTTTCTTTGGCTTATACATATTCTTAAAT

ATGCATGCCCTAAACTTCCATCTTTTTAACACCAAC

GGTCCGTTGCATTTAAAGGCTGTTAGGTCTTGTCTC

ATTTTCTACTCCCTAGTTTTTGTCATGTCTTGTTTATC

TTGACCTCTCTTCATTTGTCCTGTTTAAAACACTTTT

TTTATCCAAATGGTTTTCATTTGGGTTTTTTGGGCAT

CTGCATCAGAGGACAATTTCAACTTTAGACATGGA

CCAGAAACGGGGATATGACCAGCATGAAGGAAGC

AATCTTGCATCAAGTTGGCAGCTTGAAATGAAGGT

TCTACAATAACATCTTGCGTTGTGTCATGGTTTGTA

GATAATTGTCTCCGCTGAAAATAAATGACGGTTCCT

CACTTCCTTGATATGTAAAGCACTCATAAAATGATT

AATAATTCGGTGCTGCTACAAATATATATGTTGAAG

CGCACTAAATCTGAAGTTGTGATTTATTCATCGGGA

TGTTTTTTTCTTTTTAATAATGACTTTTTCATCATTTA

AGTTGACATATACAGCACCCACTAATGCTAATATCT

TAAATCTCCACATTTCCCTTGCAATCACCAAGACAA

CTTGCTGTTAGCATAACCAGACACTGCTACTAACTT

TAACCATCAAAAGCACATAATCCCGCAGGTCTTCAA

ATCCAAATGAGGCCGGACATCATAGAACTTGTAAT

TTTAACTCACATAGAAGTTTGATAGTGTGATATATG

ACAAGGGCAGATGGTAATAAGTAGAGCTAGCAAA

TCCTTTTCATATTGTTAATCCTCTCTCAAAATGGACG

AGGAAGCTCTAAAACTGCAGAAAACAAACTTTTAC

AAACGAATTTAAAGCTTTAAGAGGGAATAAGGAAC

AGGCATGTCATTGAAGAATGCTATCTATTTATTATG

GAAGATCTGTGACCTTAAAATCCCATAAATATGATA

TGTGTCGGATCGTCCAGAATGAAAAGTAGCTCAAG

TTGTTAGAAATGTTAAGTAGACACAGATGTTGTAT

GGAACTATGGAAGTTCACTTATCTACTGTAATGAG

CTTCCATCTCTCCCAATGAATTCCAAAACCCTGACTC

ACCTTCAAATTAATTCCAGCTCGTGAACCAAATTTG

TGATTCTGGACACCAACCCTTATCAAAGAATTTAAT

TAAATTGGCAATTGACTTGAGATGTTTGAAATTCAA

TTTTAGAGAATAGAAGTTTCATACAATCAACGAATG

AACTTTATTACATCTGTGTATTTTAACAGCGTACGTT

TCCTGCTTAACTCGAGTGCTGGATCCAACCCATATC

AAAATACGCATGTTACCGGCGCATCTGGTCTAGTCT

TATTCCATGGATACATGTTCCGTGTTCCGTTCAGAA

GGTTATGTTTCTACCAGAAGACAGTTACAGGTACT

GGTTAACAAGTCTATTGTAAATCATATACTTTTACA

ATGGCATTGATGTATCTGTTAACATAGTGGAAGAT

GCGGTACAAAGGAATATGAACAGGCTTCTTTGTGA

AAGATGTATCTATTCAACAGCCAGCCATAGCTGGA

AAAAGTGTCTCTATAGTCTATATACATTAATGCACG

GTCATCAGGTAAAAATTCCTTTGCAAAAAGGAACC

ACAAACAAAAAGCAAAGGCGAGTAAAAAAAAAAA

AAGAACCTAAGTGAGAGATTGCCTGCACAGACAAC

TAATTACAATGTACATTGACTCGCACACTTCGCAAT

GACACAATACTCTGATTTCTATATATATGTGTATGT

GCATTTACATTTGCCCTTTATTTTGGTATCCGATGGT

TGGGCCCAACATTATGGAGCCAATCAACCACTTCAT

TAATGGTTGGCCTCTTGACGGGGTTTACGTTCACAC

ACATACAGGCGACATCAAGAACCTGCAGCATCTCT

TCTTCAAATCCCTTGTCTCTCAGGATCTCATCAAATA

TTTGATCCTGTTTCCCTTCTATTCTAAGTTGTTGCAC

CCACACAACCAATTCTCTAGACGCCTTTGGCCGGAA

TACCTCCATGGGCCTCTTTCCTGTAAGCAGCTCAAG

CATGACAACCCCAAAACTGTATATGTCCCCTCTCAA

GGTGGCTATCCATGACTGGCTGTACTCCGGTGGAA

TATACCCCAGGGTGCCCACCAACTCAGTCGTGACG

TGTGTATTGTATGGATGAATCAATCTAGACAATCCA

AAATCGGCCACGTATGCTTCAAATTGGTCATCCAG

AAGGATGTTACTTGATTTGATGTCACGATGCACGA

TATGTGGTTCGCATACTTGGTGCATATAAGCCAGTC

CACAACTTGCTCCCCGGGCGATCTTCAATCTCGTTG

GCCAATCGAGCCTGGATGCTCCGTCAGCCTTCTCAT

GTAGCCAGTAGTCCAAGCTTCCATTTTCCATATACG

AATAAATCAGCAGCTGACATCCATCATGTACACAGT

ACCCTTGTAAAGAAACCAGATTTTTGTGATGGGCA

GTTGATAATGCCTCCACTTCTGCTTTAAACTCCCTTG

CAATGAGGCCCATATCTCCTGAAAGTTTCTTGACAG

CCAGTTTTGTTCCGTTCGCCAAAGTTGCTTTGTAAA

CCAATCCAAAGCCCCCACATCCAATGATGTTTGCTT

GACTGAAATCTTCGGTTGCTTTCAAAATATCAGTTA

TGGTTAGATGTTTGATGTCTTTTGCATTGTGCGGGA

ACAATATGACTCCGCTGGTATCCTTGGGAACCTCTA

CGGCCGACGTAGAATTGAAGGACACCGTGTCCATA

TGGAAGACTTCCGGGTCACCTCTGGGGAGAATCCT

TCTTTTGGACAATATCCACAGTGCCAGACAAGCCA

GAGTGATGCCAACCCCAAAACAGATGCCCAGGATG

AGGCCGACGATGAGTTTCTTGTTTGGGCCTTTTTCA

TGTGGCGAGGAAGCGTCTGTTTTGGGTGATAGAG

GATTATTTTCATCGTTGCAAAGGTTTTGCATGGGTG

GACCGCACAACCCTGGATTGCCTTCGTAGTTCTGGT

TCAAGAAGGTGTCAAACTGTCCCCCGGTCGGTATG

GAACCTTGTAGCTTGTTGTAAGCGACGTTGAAAGA

AGACAGAAAGTGCAAGCTTTTGAGGGAGGCAGGG

ATCTGACCAGACAGATTGTTATGGGAGAGGTCCAG

CTTTTCCAAGTTTGTGAGATTTGAAATGGTAGCGG

GAATGGAGCCAGAGAAATTGTTTAGGCTGAGATCA

AGTGTATGAATGGACTGCATATTACCAATCTCAACA

GGTAGGCTGCCACCGAGTTGATTGCTTGACAGGTA

CAATGCTGGAGGCAGGGTGGCCAGCTGATTGTACT

GCAAATAGGATGCATTTTGAGGGGCAACGAATACA

GGGAGTTCCAGGTAACTGCTGTTTACACGGTCCAA

AACCTGCTGCGATGCGAGGGCTGGGAGTCTGGTA

AGCTCCACAGGGAATCCCCCGGATAGAGAATTATT

AGACAGGTCCAGATAGAAGAGGTTCGGAAGCGTG

TGTAGCCAGCCCGGAATGACGCCGTCGATATTATT

CTGGGAGAGGTCGATGACCTCCAGATTGGTAAGG

GAAGAGAGCCACGTGGGGATCTGACCGAACAGCT

TGCAGCCACCAAGACCCATGATCTTGAGATTGGAG

AAACCAGAGATGGGTTGAGGGGGGAGGGGTTCGT

TGAAGAAGTTCTTGGAGAGGATGAGGGTGGTGAG

TTTCGGATGCCTGCTCAGGATATTGAATGCGCTTGT

GATGTTCCTGAGGGTGTTGTTTGAAAGGGAGAGG

AAGGAGAGAGCAGGCAGGCCGAGGACATGAGCG

GGGATTTCCCCTCGCAGCCTGTTGGTGGCCAGCCG

GATTGCGGTGAGCGATTTGCAAGAGAAGACGGTG

GCCGGCAGCTCCCCTGCGAATCGGTTTTCGCCAAG

GTCAAGGATGGTGAGCCTGGTGAAACCGGAGAAA

TCAAAATCCGAGAGAATGCCGGTGAAGGAGTTGA

CCCTGAGATTGAGAAGCTGCAGGGATTTGCAGTTG

ACGAGGGAAGGAGGAAGGGTTCCATTGAGACGGT

TGATGTGAAGTTCAAGTTTCTGCAACAAGGGGAGG

TTGCCAATGGCGTGGGGGATGGGCCCGCTAAAGTT

GTTGCCAAACAAGGCAAGAGTGGTGAGGTTGGTG

AGGGTGGTGATGGAATCGGGAATGGGGCCGGTGA

GAGAGTTCCCAGGGAACGATAGATGGCGGAGGGA

AGGGGTGGTGGAAACGTGGAAAGGGGCAAGGGC

GCCGGTGAGGTTGTTAAACCCCAGACTCAAAACCT

GGAGGGAAGCACAGGGGCCCGACAAAGGGGGGA

AATCCCCGGTGAAGTCGTTCAAGGAGAGATCGAG

GATGGTCAGATTAGAGTTGCATATGGTGGAGGTG

GGGACGGGGCCTGTCAAGGTGTTGTTGCTGACATT

GAGGGCAATCAAAGAAGGGAAAGAAGGGAAGAA

GGTAGGCGGAATCGTGCCATTCAGATAATTACTGG

ACAGATTCAGGGTGGAGATGGTGGTCGTGGTGGG

TTGTGGCAGGTTCCCAGAAAGTCTGTTGTAACTTAA

GTCAACGGTGTGGAGATGGTTGAAAAATTGTGGT

GGGAGGGGACCAGATAGGAAATTACAGGACAGGT

TTAGGAAAGATAGGGATGTCAGATTTTCAAGAGG

GGCATAATAATCATTGTAATTGGTCGTAGTAAGGC

CTCTATTTGGTAAGGAAATCCCGACCACACGGTGA

CCTTGATCATCACAACTGATTCCATCCCACAAACAG

CAATCTTCTCCTTCCCCATTGGCAGCAGCCCAGTTG

ACGACGCTGGGAAAGTTGTTGCCAAAAAGCAACA

GAGAATCCTTATCATCAGAGTTACAAGCTGCTGCT

GCTGTCGTCCTTGTACAAGCAGGAAACAACAAAAC

TAACACTAACACTAGTATCATCAACAAACCCCTCCC

CACATGATCATGCTCACGATTATGATTGAATGATGA

ACAACAACACGGGACCAACAGCATCATCAACAACC

AAACCAAACCACACCACACCACCCACCCACAAACA

AACAAAGATATATATATATATATATATATATATATA

TTACTTTTTGTTTCTAAAAAGAAAGAAGAAAATTAT

GAAGAGAAAAAGACGACGATAATGGTAATAATCC

CATTTCAATTCAAAGAAAGAAAGAAAAAATACAAG

TGGATGTTGACGCAGACCATTAGTAAAAAAAAAAA

AAAGAGAAGGGCATCAAATCAAATCAAATCAATTG

AATAAATTATATAATTAGAAAAAATTACAAATAGA

GAGGGTGTTTCTATTCATTTATCCATTATTATTATTA

TTATTATTATTATTATTATATTATTACTACTTGCTACT

ATTCTATTTTAATTACATTATTATTATTAATTATGTAT

GATATAATGAGAGAGTTGAAGAACAACTAGATATT

AATCAAATCCATCCATCCATCCATCATGACGACGAC

CAATAGAGAGAGAGAGAGAGCGCGCGTTTACTTT

GTTTATTTTATATGAGTAGTAAGTATTTGATGTTTTT

ATTTTAATCAAGGAAATTACTGTAATTAAATTCAAT

TGACTTGAATTGGTGGAAGGAGGGAGGGTGGGG

GCGGCTGTTCGCTCATCAGTCATCACCATCCATCTC

TCATCGTGTCATGATGTATATATATATATTATATATA

TATAGAGAGAGAGAGGGAGATTAATAAAATACAA

ATGGACAAATGCAAATGGGAATTATTATTATTATTA

TTATTTATTTAGCTTTATATGGATATGGAAATGGAT

GGTGTGGGCATCTCATCAAATCAAATAGAATCCAA

CCATTACAAGTGCGCCTTTTTCCTTTTCTTTCTAAAG

TGGAGAGACGGATTGAGTGAGGGAGGGACTATTA

CCAATACCAATTATACCATGGTTAGTGGCGGTGGT

GGTACGACTATTACCAAAACTAATTATACCATCAAT

ATATAATCACTAATATATATATATATATATATGGTA

ACACTCCGATAAGAACACTTTTAAAATAAGAACGG

TGAAAACACCTTAAAAACATCATTTTGAT

42

Conyza

Genomic
8264
TTAAAGATATTTTCCTCCCACTTTTGGGATAATTTG

canadensis

GAAGGAAGGAAACTCCACTCCTTCTCTTCTTTCCCC

TTCCTTTACATATAAACTCGAGAACACAGGCTAAGG

TTCAAGTTTCAAGTCTTACATTTGATTACTAGCCAA

AACATTAATTAGTTATTGTTATGCAAAAAAAAAAAA

AAAAAATTATAAAAATTGAATTGATTGTTAATCAAT

ATCATTTTATGTTGAGTTATTTGTTTTAGTATTATAT

TAAAAGTAAAATAATGCTACATGAATTTTTCTTTTTT

TCTTTCTTAAGCATTCAATGCGATTTTAATTAAAATA

AAATAAAATAGACTATCATTTGTAGCTAATTATGTA

ACATATCAACTATGTTTTATACAATACTAGCATTATA

TTCGTGCGATGCGGCGGTGGTCGTGACGACGAAA

GTGTGGTGGTGGAGGCGAGTGTTGGTGGTGAATG

CGACGTCGAGTGCCGTAGATAATTCATATAAAAGT

AATTGATTTAAAAGGTTAATGGAGATATTTTAGAA

AAATAAAGGATTGATAGTGTAATTTAATTATTAATA

TTAAGAGAATAGTGTATGTGAAAATCTTTTAAAGG

TTTGTAGGCTTGTAGCCTTGTAGGTGAAAATATTAC

ATAGGAGGGCATTTTAGACATTTCCCCATGTAACTT

TCAACATGGAGGGTATTTTCTTTAATATAGAGTATA

AATAATGGAGATATTTAAAAAAAATAAAGGACTGA

TAGTGTAATTTAATTATTAATATTAAGAAAATAGTG

TATGTGAAAATATTTTAAAGGGTTGTAGGCTTGTA

GCCTTGTAGGTGAAAATATTACATAGGAGGACATT

TTAGACATTTCCCCCATGTAACTTTCAACATGGGGG

GTATTTTCTTTAATATAGAGTATAAATATAGATAAA

TAATATATATTTTGTAAATTTTTTAAACTAATAAATT

ATTTTAAAATAATAATTTTTATAAAATATATTTTATT

TGATAAATAATAACTCTAAATTACACAGATGGTACC

TATAATTTGTATTATATTACATGTTTCATACCTCACA

TGCAAGACACGTTGGCTACTTAATGATACAACTAAC

GACCGTCAGCGTGAGGTATCTTCTAAGTGTAAAAT

TATAAACATGATATAATTGACGTAATTTAAATCTAA

CAGGTATGAAATTAATAATTTCGACCAAACCAAAG

GTACTTAATTCACTCTTAATATACTGTATCTAATACT

ACTCGTGGTAGTATTATGTAGATTCCTAGCAATGG

ACGACAATATTCCAACAACATAAGAAGCCAAAACC

CACTTCCTTCCTTTTTTTTTTTGTTGTTGAATAATTTA

ATCAGTTTTTAGGAACGAACAACCTCCTCCATTTCC

AGATAAATTATTATTCAGCCAAGCAAAAAACACAA

CATCCCTTGTTTCCTCTTCTTCTTGTTTTCTTTTTCTTT

CTTTTTGCTAAAAAACTCACACACGCAGAAGAAGA

AGACGAAGACAAAGTCAGAGAGTTGAGTTTGGAC

TGATTGATTGATTTGTTATTAAGGTAAAAATACCAC

TTACTACTCCATCCATCCATCCATCCATAGTAGACT

GGTAGTTGTATTAGTAGTAGTTAGCTGCTGCTTTGG

TTATTAGGATTAGGATGAAGAAACTAGCAGATTGT

TAAGTATTCTTCATGTGACTTTGTTATCTTCCTTTGT

AAACAATCTCCCCCAAATATAATAGCATATCGACTA

AGTGGTAATATACTTATTTTTTTTTTAAGTTGATGGT

GAACTATTGTATATGGCAGGGCTGGTGTTTGTCTG

ATCATCTGCAGCGAGCTGATAGTATTATTATTATGT

CTCTTTTTGGAAATGTCTCTGCCATTAACCTAACTG

GAAACTGTCTGCTATCAATCACTAGTTCCAGAGATG

TTTTGTCATTTCGGCACGGTGATACTATGGGTTATC

GCTTGCAATCCCCCCCTTCTTTTATTACCAAAACTAA

CAAAAATGTCTCCCCTTTGAAGGTACAACCTCTGCC

ACATGTATTTCATTATCACTCACAAAATCAATTCTAA

TGTCTTTGTTTATCTGTGCTAAACAGGTAGTTTGTG

TCGACTATCCAAGACCAGACCTCGATAACACCTCTA

ATTTCTTGGAAGCTGCTTATTTGTCTTCTACCTTCCG

AGCTTCTCCACGCCCACCTAAGCCATTGAAGGTTGT

AATTGCTGGTGCAGGTAAAACCTTCATACGTCATTA

TATTGTCTTTTAAGTCGCTTTTGTTTGAGAATTTGAT

ACTGCCACATCTGATAGATAACCAAATGATACTTCT

AGTGTATCCCCAATGATGCTTTTTATGCCACATACT

AACATCTGCTTTAATTTGCTATCCCACTTACTTTTGC

AAACTTCGCATATGCAGGTCTCGCTGGTTTATCAAC

TGCAAAGTACTTGGCTGATGCCGGTCACAAGCCAA

TTTTGCTAGAAGCAAGAGATGTTCTTGGTGGAAAG

GTAAACGATTTATAAGAAATTACAATAGGATCGGA

AGTCCTAGGATCCCCCCTCCCTCTTACCTTCTTCTAT

ATAACAGAGCAAGCTTGGTAATAAAACAAGGATTT

TGGGTCTAATTATTCTCTTCTTTACTTGCTTTCTGTTT

TCGTCTCTTTCACTGATAACCAAAGGCAATATCAGT

TAGGGTTCTAGGATGGGTCGAAGCAAATTTTAGGG

ATACCAATGCCTAACCAAGTTCGATCAAGACTAGG

GATATAGAGGGTATTCAATCAGCTTCTGGTGGGAT

TATAGCTCGCGACTTTGAAGCTAGAGTTAGGGTTC

TTTAAAGCCTAACATAGTTCAAATACGGCTGGGGT

GTTGGGGGTTCCTTTCTGTACGAATTTAAAGCTGG

ACAAGGCAGCAAAAGAGTTCGACTTGTGTGGATTT

TTATCTAGGTTTGGCTGGGGTTTCAAACAACCGAA

GGTGTGTTTGGGGTTCTTGGGATAGTCGATCAACA

TTGGAGTGTCTTTTTCCTGTTTTACAAGTTAGAATA

CGTGAAATGCATCTTCGTTCATTATTTTGCTTTTGAC

CTTTATGTGATGGGTACAAGTTTAACAACCTACTGC

ATGCGGTTTCTCTTTGTGCTCACATTTCACTTTCTCT

CTTTTCTCTTTTGCATTGTTGGGGTGGGATGGCTGT

TTTTGCTAGTAACATTTATACAAACCTGGACCTAAT

GTTAGGTCAATCCGGGCTGGGTTCACAACTGGATG

GAGGAATAAGGGTCGGAGGGAAATATTGAATGGC

TCCTCAAACCCAAAGTAACCCAGATCCAAACACTTC

CAATCTAAACAACCCAGACCCCGTGGCTGCTCAATC

AACAGCCATAGCATCATCTATGAAATCACTGCAGC

AAAGAGGTAGCAATGATCAAGACACAGTAAGCCA

AACAAAAACAGAAATCAAGCGGCAATTTAAATCAA

TTTGAAGATGAAGGTTCATCTGGTGGTAACCACCG

TCACTACAGACCTTATAATAATATCGATTTCCCAACT

TTTAGTATTGGAGAACTGTTTACAAGGCTATGAGT

ATTGCTATCGAGTTTGAATCCAAGGTTCACATGAAA

TTTAGGAAAAGTTTTTCGTCTTCAGCCAAAACAGAA

TCAGTACCTTCGAAACCAATAGAAACTTCCAACCTG

TTGCCCTCGATTGCTGCTGCCCAGAAACCAACTGAA

GCCCGTCTTTTTGATGTTAAAAAATAGGGCAGATTC

ATACGAGAAGTTGTGTCTAAGTTTCTGATCTACTCA

AAATTTCTATCAATTTGCCTTGGGGGAAAGCCGAT

GTGGTACTCGGTATTCAATAATTAGGAACACTTACA

AAGTTTAGGCAAAATGGAAGGAGATAGTCATGAA

GTTCACTATGGATGTTAAGGAGTACAAGCTACATG

GACTTCCACCAGATCGTCAACCATCAGCAACATTTA

GCGACCTCACTACTGAACCATTCGAGTTACAGGCA

AGTGGACTAGCAGCTCATTTTTTCACAACTGGCTAG

TGGACAAGTCAGATTTTGGGGCCGGATGTATTGAT

ACAAACCTGGACCCAATGTTGGGTCAAACCAGGTC

GGGTCAGCAGCTGGATGGAGGGAAAAGGGGTGG

AGGGAAATCAAGTAGTGAAGGAATTCAAGTTAGG

AAGTGGACCATGCGCCCACTACATATAATTGCTCCA

CTAATTTTAGTATTATATATGTGTGTTTTTCTGTTTT

TTAAGCTGGTCAAGATACTAAGTTTGTGATTGTTCT

TGTATTCGGAGATTTGCCATCTGAATTTTGCTAATA

TTGTGTTAGACTCAGTAATCTAAATTAGTAGATTTC

CAGTTTCTATCAAATGTTCGTTTGGTGAAAATGAAT

AATTGAAGTTCATATGACGACCTTATTTGAGCAGG

ATCTGTTCTATAGGCTCGTACCTCTGTATCCTTGATT

CCTATCAAGACAGAAAAGTAGTTTCATATGAAATTT

CTATTTTTAAACTTTTGTATATCATAAGTAGTCAAGC

TTAGCTTAATTTCAAATCTAGGTTGTCTTAGTATGTT

GTTACTTATCGTGAGTGTTTTTATCCACATTGCTCTT

CTCACATAGGTAGCTGCCTGGAAAGATGATGATGG

AGATTGGTACGAGACTGGTTTACACATATTTTGTAA

GTTTTAACTTCTTATATCCTTTCAAGTGTCGAAAAA

GAGAGCTGATGTGTGCATAAAAAGTTATTCCCATA

ATATAATTCTCAACAGGGTTGTTGTCGTCTTTTTGT

GCACTATCTATCTGCTCTAAGTTATTGTTTCTCCACG

TACCTTTCCTTTTGGACATTTGTCACTAGACACCTAA

TGTGCAATAAACTTCTTCATTTGCTTGAAGTTGGAG

CTTACCCGAATATACAGAATCTGTTTGGAGAGTTA

GGCATTAGTGATAGATTGCAGTGGAAGGAGCATTC

AATGATATTTGCGATGCCAAACAAACCTGGAGAAT

TTAGTCGGTTTGATTTCCCAGATGTTCTGCCGGCAC

CATTGAATGGTAAGTATGCTATTATTAGCCTATTTT

TTTTGGTGTATATATTTTATTTAAATGATTTGGTGGT

GAGCATTTTCTGCATCACCAACATGACAAAAAAGA

TCTAAAACAAGATCAGTCAGGGAATGCTAGATTAC

TAACAAATGTGACTCTGCATACCATCTCAGGAATTT

GGGCTATCTTGAGGAACAATGAAATGCTGACATGG

CCTGAGAAAGTAAAATTTGCTATCGGGCTCTTGCCT

GCAATGTTAGGTGGACAGGCTTATGTTGAGGCACA

AGATGGTCTGAGTGTTCAAGACTGGATGAGACAAC

GGGTATGTAGTCGTTTATGTAAATATTTCTTTTACC

ATTTTTTAGTTTAATACATAAGAAACAATGGCCATG

ATACCTGGTATATTTGATAATGGTAACGTTTCTAAG

TGGAAGATCCAGAGGTCAAACCTTAGCAGGGGCTT

TTTTTAGGAAGATTGTTGGCTAATTAAACCCCCTGC

TTAATAATTCGAGTTCTTGTTTCTTTTGTTATGAATT

TTATTTAATAATTAATGCACATTTTTCATTTTTCCAG

GGCATACCAGATCGAGTTACTACAGAGGTGTTTAT

TGCCATGTCAAAGGCATTAAACTTCATCAATCCAGA

TGAACTTTCAATGCAATGTATTCTGATTGCTCTGAA

CCGATTTCTTCAGGTGAAGGCATCATTCTCTTAGAG

CTTACTGGTTAAATAATGATGAAAAATTAATCTCAT

GACTTTTAATTCCATCTTCCGTCTGTCATATATGATA

AGTTGGTCACGGACTCAAGTCACTAATATATTATAT

GGATTGATTTTACGCTTGTGATTGGTCAAGTAGAC

AAAGCATGCAAAGTTATATGGGTTTAGTGTAATTA

GTGTCTGTTGCATTGCTCACTGTATGTCTGTATTGG

TTGCTATAAGCCAGCGTGCTACCTTGAAAGCAACTC

TATTTCCTTTTCCATGATCAAGTATTATTACATATAT

ATTGTGCTTCTAGAATCCAGATACAGAGATTTGGG

TTATTTTTGTGGTTTTGAAATAGGAGGGCGGCCTCT

ATAGTTAATCTCGAAGTGCTTATTGTACACCATGGA

TTTTTGAAACAAAGAGTTGATCGCTCTTATCTGTAG

CTTCTTAACACTTCAATATTGGCTTGGTTGCAATACT

ACATGGCATAGACATTGGACACCATAGATAATACA

ACTTGTAAATTGTTTGTAATAAATCAACAGGAGAA

GCATGGTTCTAAGATGGCATTTTTAGATGGCAGCC

CACCTGAAAGACTTTGCATGCCAATTGTTGAGCATA

TTGAGTCACTAGGTGGCCAAGTCAGGCTTAATTCG

CGAATACAAAAGATCGAGTTGAACAAAGATGGAA

CAGTTAGGAACTTTTTACTTTATGATGGAAATATTA

TTGAAGGTGATGCTTATGTATTTGCTACTCCAGGTA

CATTTAGAGAACGACTATTTGAATCTGTAGCTTTCA

CATGTCTGTTGGGGTTGTAGCTTTATTGATTATTTT

GTGTCAAACAGTTGATATTCTGAAGCTTCTGTTGCC

TGAAGATTGGAAAGCAATTCCTTACTTCAAGAAGT

TGGATAAATTAGTTGGTGTCCCAGTTATAAACGTTC

ATATATGGTTAGTTGGATCCTTCAATATAATTCTAA

ACATGGCACAGTAATCATTCACCTTAATTTAATAGA

GTCTGGCTTCTGTCTTGACCATTAATCTGACTTAGT

AAAACCCCTATATGTATTCTTTGTAATTGTTAAACA

CCACTTTCAGGTTTGACAGGAAACTCAAAAACACCT

ATGATCACCTACTCTTCAGCAGGTCACCTCTCAACT

CTTATTCTTGCAACACTATTACTTAATTTTTAGTAGA

CAAGGCTGTTGAGCTTTTTATTTGTATGTTATTCAT

GCCACTGCTACCTAAACGGATCTTTTACTTCCATTTC

AAATGTCTGGGGCGTGTCGTCCATAAAGGTTCTCT

ACAGTTCATAGAGTAACTTAGAGTAAGCTTACACCC

CACCTATTAACTAAACAAAGCAACACAAGTTAGGC

TATATGGTACATGCTAAAGTGATGGTCAAGATTGC

ACCATTTGCTACCGCCTTGAGATACCAGTGTCCCAG

CTTCTGCTTACACTTCATAGTTTATACTCAAATTTAA

TATTGGTACAAAAAAGAGTACTGAACCTATCAGTTT

AGTCTTTTGTATTAATTATTTAGTTTGCATGCAGGA

GCCCTCTTCTCAGTGTATATGCCGACATGTCTGTAA

CATGCAAGGTAAAGACAAGACAAACATATATGAAA

CAAACCATTTTCTTCCAGACAAACCTGCTTTGCTGTT

TTCATATGGTTCCTTGTCATGCAAACAATGAGGAG

ATGGATGTCTATTGGCCTCTCCTCTCATTCCTATTTT

CCCGGAAAATGGGTTAAATCTGTCTTTGTAATTTTA

TCTTTGTCGCATGCATGGGACATAACTTCTCACAAT

GCACATAACTCAAATATTTACCAAAACCTCCCGCAT

TTTTAAAACCAGGCTATATATAAGTTGTAAATTACA

TGATGTGAACCCATACCTCCCATCAAGGTTGTTCTG

ATAATAGTGCTCCCATTTTATACAGGAATACTATGA

TCCTAACCGGTCCATGTTAGAGTTGGTTTTTGCACC

TGCAGAAGAATGGATTTCACGCAGTGACTCTGATA

TTATTGACGCTACGATGAGTGAACTTTCAAGACTAT

TTCCGGATGAAATTGCAGCAGATCAGAGCAAAGCA

AAAATATTGAAATACCATGTAGTTAAAACCCCAAG

GTTAGAAATATCTTACCAGTAAGGGGTTTTCAACG

ATTCGGTTTACGAGCTCTTCGCTTTGGTTTCCTTGAT

TTGACAATCCTTGAAGCTCAAACCAAAAACCAAATC

AAACCGAATTAATCAGAAACAAGCCAAACCAAATA

AGATGGTTTGGTTTTGGTTCGAATGCGATTGAAAC

CAAACCATTTTCAAATAATGCAGATTTTATGCTGGC

AAATGTTATCTAAACTTTTTGGCAAATGAAAATTTG

CTGAGATTCATTTACCACCAAAAACTTACTATATGA

AAAGAAATATATAATGTATTATAAACTTACATTATA

AGTTATTTTAAATTAATTTGATAGGAAATATATATA

TATATATATACACACACATGTATATAT

43

Conyza

Genomic
667
TTATTATTATTATTATATTATTACTACTTGCTACTATT

canadensis

CTATTTTAATTACATTATTATTATTAATTATGTATGA

TATAATGAGAGAGTTGAAGAACAACTAGATATTAA

TCAAATCCATCCATCCATCCATCATGACGACGACCA

ATAGAGAGAGAGAGAGAGCGCGCGTTTACTTTGTT

TATTTTATATGAGTAGTAAGTATTTGATGTTTTTATT

TTAATCAAGGAAATTACTGTAATTAAATTCAATTGA

CTTGAATTGGTGGAAGGAGGGAGGGTGGGGGCG

GCTGTTCGCTCATCAGTCATCACCATCCATCTCTCAT

CGTGTCATGATGTATATATATATATTATATATATAT

AGAGAGAGAGAGGGAGATTAATAAAATACAAATG

GACAAATGCAAATGGGAATTATTATTATTATTATTA

TTTATTTAGCTTTATATGGATATGGAAATGGATGGT

GTGGGCATCTCATCAAATCAAATAGAATCCAACCAT

TACAAGTGCGCCTTTTTCCTTTTCTTTCTAAAGTGGA

GAGACGGATTGAGTGAGGGAGGGACTATTACCAA

TACCAATTATACCATGGTTAGTGGCGGTGGTGGTA

CGACTATTACCAAAACTAATTATACCATCAATATCA

TCACTAATATATATATATATATA

44

Conyza

Genomic
97
TGTGGTGGTGGAGGCGAGTGTTGGTGGTGGATGC

canadensis

GACGTCGAGTGCCGTAGATAATTCATATAAAAGTN

NNTGATTTAAAAGGTTAATGGAGATATT

45

Conyza

Genomic
33
TTTATTTGAGAGAAGAAGAGAAAAGAAGGGAAA

canadensis

46

Euphorbia

cDNA
484
GGCAGAAGTCCCCTTCTTAGTGTTTATGCTGACATG

heterophylla

TCTCTTACATGCAAGGAATATTATAATCCAAATCAA

TCAATGCTGGAGTTGGTATTTGCACCTGCAGAAGA

ATGGATCTCACGCACGGACACCGAGATCATAGATG

CCACTATGAAAGAACTCGCAAAACTCTTTCCCGATG

AAATAGCTGCAGACCAAAGCAAAGCCAAAATTCTC

AAGTATCATGTTGTAAAGACTCCCCGGTCGGTTTAC

AAGACTATCCCAAACTGTGAACCATGCCGCCCTTTG

CAAAGATCACCCGTGGAGGGGTTCTATTTAGCCGG

TGACTACACAAAGCAGAAGTATTTGGCTTCAATGG

AGGGTGCTGTCCTATCTGGCAAGTTTTGCGCTCAA

GCCATTGTACAGGATTATGAGTTGCTTGCTGCTCG

GGAGCAGACAAAATTGGCTGAGGCAACCGTTAGTT

AACAATGTAAATACTGTTTAAGGT

47

Euphorbia

cDNA
347
TATTGGACTTTTGCCAGCAATGCTTGGTGGACAGG

heterophylla

CATATGTTGAGGCTCAAGATGGTTTGAGTGTTCAA

GAGTGGATGAGAAAGCAGGGTGTTCCTGATCGAG

TCACTAAAGAGGTGTTCATTGCCATGTCAAAGGCA

CTAAACTTTATTAACCCTGATGAGCTTTCAATGCAA

TGTATATTGATAGCATTGAACAGATTTCTTCAGGAA

AAGCATGGTTCTAAGATGGCTTTCTTGGATGGAAA

TCCCCCAGAGAGGCTTTGCAAGCCAATTGTTGATC

ACATTCAGTCCTTGGGTGGTGAAGTACGGCTAAAT

TCACGAATAAAAAATTGATTTAAATAATGAT

48

Euphorbia

Genomic
5622
AATGTTTATGGAAGGGAAAAAATGTGAAATATTCT

heterophylla

GACAGACAACTAAAATTCAATACCAATCATAAAAA

ATTTAATGAATGATTGAGATTGACCGAAATTTACAA

ATGTATCAAAGTTCAAATTTAGAGAATCCTTTTACA

AACTCTTATACAAGTCACAAATTGTTAGGATGAAAA

ATTATGACTTCAAACATCAATCGATACATTTAAAAA

ATTATCACTCACATCATCAATCTATACATGTATGAA

ATGGAAAAATATCACTCCTTATGTTAACCGATACAA

CTTCACAGTGGTTGTTATATGAAAAGATACCTTTGA

AGCTCAATTTAAGAGTAACCGGTAATCCTTGCTGG

CAGAATATTCTCAACGGAGACCATACAAAATCCAA

CGCTCAATAATCCAAAAATCCATTTCCACTTTTCCG

ACCTACTCCTCTTCCTCTTTGTTATCTTCTTCTTCGTC

TTGCAATTTCCAATTTCTTTGTTTCCAATTTCTGAGT

TCACTGATTTCTGCCCTCTTCTTCTTCTTCTTCTTCTT

CTTCTTCAATTGATTTTGAGCTTCAATTGATATATTA

CTATGACACTTTATGGGGGCGTTTCTCCATTGAACT

TGACCTTTCATTCTGATATCTCAGAAGCTAGAAATT

TGCTATCCTCTTTCAGATGTCAAAATCATCTGCTCTC

TTTTAAAAGCAGCGAATCTTTGGGTTCTCCTCTGAG

AACTTCTATTGGAAATGCTACCAAAACACGATCAA

GGACTGCTGGTTCGTCTTTGAAGGTTCGATTTATTC

TTTTTCGTATCTTTCGCCCTCGTTTTTCCTTTGTTCTT

GTTACAGTATGTTTGCCTACTTGATTGATGATACAG

GTGGTTTGTGTGGACTACCCTAGACCTGATATTGAC

AATACTGCAAATTTTCTCGAAGCTGCTTACTTGTCTT

CAACCTTTCGTGCTTCTCCTCGTCCGGATAAACCTTT

GAAGGTTGTAATTGCCGGTGCAGGTGATCAATTTC

TTATCCTAATTGGTTTTCTTGCTTATTTCAGTTCAGT

GCTTTTTGAAGTATGCTTGCTTCAATTTTGATTTATG

GGTAGGCAGGGACTACAATTGATTGATTTTTATTTT

AGTTTTAGCGTTTAAACATTTTATTTCTGGAAGCTG

TTGTCCAAGTCAATAACTTAGCATCTTGAATAAAAT

CTGCAAACTTTTGTGGTTATTTATATACCTCTTCTGA

TTTGGTTACAATGGATTAACAACTTTTACATCATGC

TGCAGGGTTGGCTGGTTTATCAACGGCAAAATATT

TAGCAGATGCAGGGCACAAGCCTTTATTACTTGAA

GCAAGAGATGTTCTTGGAGGAAAGGTTATGCTTTA

CCTAGACTTCAAGAAAATTATGCATTGAGTTACCAA

TTATTAAACAATATGAATAACAATTGGTGCAAGCA

AATGAATTGGATTATAGACTCTGTTTGTTTGATTAT

TGATCTTATATAGTATATTTATTTCTTATTTCTTAAG

ACTAATTCATGGGAGTCTAAGAGTTCCATTTGCTAA

TGAATATCTGGCATGTGCTTTTCGAAATCAATGTCG

CAATTATTATTATGATTTAGCTATCTAGTAGGTGCC

TTTGGTGCACGTTATGCACACCATGGACATTATTTA

GTTGATAAGCTTCTGATTCTCTTGTTTCAAAGTCATT

ACCATGAATTAACTTTCTCTTATGCTTGGTTCGTATT

TTATTTTCTATTCATATACTAGTTTTAATAATTGACA

TTGCTGCTTAAATGCTGTTCTGGGTGGGCATCACTG

ACATTTAATATGACAAGTTGAAGTTCTTCATTGCCG

CATATATGGTTGAGTTCCTTCACAGTTCATGCAAAT

GGTCAAGACAATTGACTTTCTCTTAGAAGAAAGTTT

TCCTATTTTTTAACTTGAAAGGTTATAATCTATGTCC

TGTTTATATGTGCTATAGTCTCATAGTTGTTTTCATT

AAATAGGTGGCTGCATGGAAAGATAAAGATGGGG

ACTGGTATGAGACAGGCTTGCATATATTCTGTAAG

TTTCAGAACCCTTTTGGAGTCATTGTAATGCCACTT

CCATACTCGATGTGTTGTTGTTACTTTCCACCTTTTT

TGTCAAATCAATTTCATAGTTTCCTTTGACATGAAG

ATGCAGGAAATATTTTGTATATTAATTTTTTTTTAAA

ATATTTTGCTGGTTGTTGTGAATAGACATTGTTAAT

TTTATGCTGGACAGAGTTTTCTTTTTCCTTATTTGTT

TCAGATGCTTAAACTTTTGTGGTATATTGCTGTTCTT

ATTGAACCTGTCTTCTTTGGTTTACAAGTTGGAGCA

TATCCAAATGTGCAGAACCTGTTTGGAGAGCTAAA

CATCAATGATAGGCTGCAGTGGAAGGAGCATTCTA

TGATATTTGCAATGCCAAGCAAGCCAGGGGAGTTC

AGTCGATTTGACTTTCCTGATGTTCTTCCAGCACCTT

TAAACGGTATACAAGTTAAACACTTCCTGAAAATTG

ATTTCTCATGTGCAACTTTTTAGGAGCTAGCGAGAC

CTATAAAAATTGTTGGTAAGCATAGGAATTGTATAT

TTGGCTTAAATTTTATGAATGGAAACAATTGTATTT

TAGTTGAAAACCAGATTGAATCATTGAACTCTTATC

ATGTAACTCTTATATTTCATTGATTTTTTTTGTATTTT

TCATATTTCTGCTCACATTGTTGATTTTTTGACTAAG

CACCCCTTTGTTTTCTCAGCAGTCACCTCCTGATTGT

TGTCCTCTACGTGAGACAGCTCTTGTTGTAGACATA

TCCATATATTTGTATATCAGCCAAACATATACCTTAA

ATGTATGATTTTTAATTGATTCTGTCTAGGCTTCAA

GGGATAGCTAAAAAAGGACACATTTCTCTGTTTTCT

TGTGGGTTTTGTTATTGTGATCTAGGATATAACTAG

AGGAGTAGAGGTTGTCATATTATAATACAACCTTC

ACAAATTCATGATTTGTGGCAATGGAGAAGTTTAG

AATGGTGAGTTAAACCGTATTTTGGCCTTCAGAAG

TACCCAAGATTTACAATATGCGTATTAATTAATGAT

AAATGGAAATCAATTTCCCAATGTATATATCTTAAA

TAATTGCTCTATATGCTTCTATTTTTTTTGTGATCTTA

CAATTTCCTGTCATGCCTAAATTTTTTTATGGTTATT

CAACTTATTTATCTATAGAACTATCATTTTTTTTTTCA

ATTTTTGCTTATTTTATTGCATACTTTGGTATTACCT

GCAAAATATTGCTTAAAATTAATGTATATTTTCTAT

GGTTGTGCTTGACAGGGATATGGGCCATTTTAAAA

AACAATGAGATGCTGACATGGCCGGAGAAAGTGA

AATTTGCTATTGGACTTTTGCCAGCAATGCTTGGTG

GACAGGCATATGTTGAGGCTCAAGATGGTTTGAGT

GTTCAAGAGTGGATGAGAAAGCAGGTACTTTTGAT

AGATCCAAATCAATAAGAATAACACATGGCTTCTTA

TGGGCACAACTCTCCAGCCAAGGATCATGGAGTCG

CATTGATCATCGTGCAATTTAAACAGAAGAAACCA

GAATACTGAACTAAAATACTCAACATTGCTCGATTA

AAAATTGATTTATTTTCTGAAACTAGTAAAATCTAT

ATATGTATCAAGTATAACAAATAAACTCTGTTCTTG

ATATATATATTTTTTTTGTAATTTTCCGTGTTTGATT

GTCAGGGTGTTCCTGATCGAGTCACTAAAGAGGTG

TTCATTGCCATGTCAAAGGCACTAAACTTTATAAAC

CCTGATGAGCTTTCAATGCAATGTATATTGATAGCA

TTGAACAGATTTCTTCAGGTATGATACTTCTTCTTTC

TCTTTCTATTCCTCGATGAGCTTTCCATTAATATTTTT

TGAATGAATGTTTGTTGAACAACATTCATGTGTTTA

GTTGGCTGAAAAGAAGTTTTGCTTTTTCTTTTCCTTT

AAATAAATGAAATTCAAATTTTCTTTTACATTTTTCT

CAGTTACTCTTGAAGATGTTATTGTTGAAAGATTGA

GCATAAGCCTTATATAAACTCATTACAAATTTTTTTA

TACTTTTGTCATTTTTTCTCTATTTTCTAGAAGTTTCT

CAATTTTTTCTTTGCCACTTCACATTAGATCTGTGGA

AGTTTCTTATATAATGAAACTAACTGAATAAGGATC

GATGGTAATATCAACAGGAAAAGCATGGTTCTAAG

ATGGCTTTCTTGGATGGAAATCCCCCAGAGAGGCT

TTGCAAGCCAATTGTTGATCACATTCAGTCCTTGGG

TGGTGAAGTACGGCTAAATTCACGAATAAAAAAAT

TTGATTTAAATAATGATGGAACAATTAAGAGCTTTT

TACTGAGTAATGGGGATGTGATAGAAGGGGATGC

TTATGTTTTTGCCGGTCCAGGTAAACTTGAATTTTG

GATAACAAATAACTTCTATTATTTTCGTGACCCATA

TTTTCTGATACTAGTGTATTTTTCTTTTTCCTTTAGTT

GATATATTGAAGCTTCTTTTGCCTGATAACTGGAAA

GAGATTCCTTACTTCAAGAAATTGGATAAATTAGTT

GGAGTCCCTGTCATTAATGTTCATATATGGTCAGTG

ATGAATTCTTTTATCGAGTGACTGTTTATCTGAGAG

TTCATTTACTAGCACATGGTTCACTAACAGAAATAT

ATTTCTTTTCCAGGTTTGACCGGAAACTAAAGAATA

CATACGATCATCTGCTTTTCAGCAGGTCCTACTCTT

ATGCTTTTCTCTAGCTGTTCTTCGCCCATAGAGATTT

CTACAATCATTTTCATAACTTCCTGAAAAGCTGTTA

ATTTTCATCTTTTATGAAGGAATTCAGTTCATTACAA

ATCATTTTACGTATAAATATTTTGAATCTTGTATGTA

AAATGATTTCAAATGAATTGAATTCCTTCTAAAAGG

AATGTTTTCCAATGGAGGGTTGAGTTGTTGCTATAA

TAAGTTGACCTTCTGAATCTGATTTGTACCAATGAA

GTTTGAAGAAATGCCTTTTCCCGTGCTATTGTACAT

ACTGATTGTATATCTTCTTTTGACTTGCAGAAGTCC

CCTTCTTAGTGTTTATGCTGACATGTCTCTTACATGC

AAGGTAAAACTGGAACTAGTTATTTATTTTACCAAA

ACGACTTGGCTGCTGCTATGCTAATTACTTTTGTTCT

ATGAAATGAAAAGTAATAGTGGTCTGCTTTTTGTCT

CCATACACATAATTTGGGCAAATAATATGATCTTTG

TAGTCTTTGACATGTTAATTACAAACATTGAAGCAT

CTCAAGTATCATCTTGTAAAAACTCCCCGGTTAGCG

ACCTATTGTCTACGAACTTCTTGGCTCTGACCAAAC

GCCTTTTGTCTATGAACTATTGATTTGGGGAATTTG

GTTCTTGACCTATTGTACTCACTCTAGCACGTATAA

CCCACAAATTAGATTTGCAACTTTGCTCAATTTATAT

CAATACATGTAAAATAGTCAACATTATACTGCACAT

CTATTATCAATTGCTTTAGGTATGACCCTAATGTCTC

TGGTCAATAGGTCAGGGAC

49

Euphorbia

Genomic
3393
TCTTGCTTATTTCAGTTCAGCACTTTTTGAAGTATGC

heterophylla

TTGCTTCAATTTTGATTTATGGGTAGGTAGGGACTA

CAATTATTTGATTTTTATTTTAGTTTTAGCGTTTAAA

CATTTTTTCTCGGAAGCTGTTGTCCAAGTCAATAAC

TTAGCATATTGTTTTGGAATAAAATCTGCAGACTTT

TGTGGTTATTTATGTACCTTTTTTTAATTTGGTTACG

ATGGATTAACGCCTTTTACATCATGCTGCAGGGTTG

GCTGGTTTATCAACGGCAAAATATTTAGCAGATGC

AGGGCACAAGCCTTTATTACTTGAAGCAAGAGATG

TTCTTGGAGGAAAGGTTATGCTTTACCTAGACTTCA

AGAAAATTATGCATTGAGTTACCAATTATTACACAA

TATGAATAACAATTGGTGCAAACAAATGAATTGGA

TTATAGACTCTATTTGTATGATTATTTTTCATTTAGC

TAAGACTAATGCATGAGAGTATAAGAGTTTCATTT

GTTAATGAATATCTGGCATGTGTCATTTGAAATCAA

TGTCATCATCATTATTATGATTTGGCTATCTAGTAG

GTGCCTTTGGTGCACATTCTTCCGCCATTGAAATTA

TTTAGTTGACCGGCTTCTAATTCTCTTGTTTCGAATT

CATTACCAAATTTTATTTCTTCTCTATCCATCCATAA

TATAGTTTTCCTATATATTAGTTACATTCCTCCGTTT

CTATTCTATTATTAGCAAGCCCTGTTGTCTTGTATAT

GTCTATTCATATACTAGTTTTATTTATTGGCATTGCT

GCTAAAGTGCTGTTCTGTACGGGCATCACTGACATT

TAATATGACTAGTTGAAGTTCTTCAATGCCGCATCA

ATGGTTGAATTCCTTCACAGTTCAAGCAAATGGTCA

AACCAATTGACTTTCTCTAAGAAAAAAGTTTTTCTTT

TTTTTAACTTGAAAGGTTATAATCTCTTTCCTGTTAT

TATGTGCTCCAGGCTCATAGTTGTTTTCTTTAAATA

GGTGGCTGCATGGAAAGATAAAGATGGGGACTGG

TATGAGACAGGCTTGCATATATTCTGTAAGTTTCAG

AACCCTTTAGGAATGAGTCATTGTAATGCCACTTCC

ATTCTCGTTGTGTATTTGTATGTTAATTTTACTTGTC

ACCATTTTTGTGAAATCACTTTCATAATTTCCCACAG

TGAATTAATTTTTTTTTAAATATTCTTTTGGTTGTTG

TGAACAGGCATTGCTAATTTGATGCTGGATGTAGT

TTTTCCTTTTCCTTATTAGTTTCAGATGCTTAAACTTT

TGTGGTTTATTGCTTTACTTATTGAACCTGTCTTCTT

TGGTTTACAAGTTGGAGCATATCCAAATGTGCAGA

ACCTGTTTGGAGAACTAAACATCAATGATAGGCTG

CAGTGGAAGGAGCATTCTATGATATTTGCAATGCC

AAGCAAGCCAGGGGAGTTCAGTCGATTTGACTTTC

CTGATGTTCTTCCAGCACCTTTAAATGGTATACAAT

TTAAACACTTCCTGAAAATTGATTTTTCATGTGCAA

CTTTTAGGAGCTAGCGAGACCTATAAAAATTGTCT

GTAAGCATAGATATTGTATATTGGCTTAATTTTATG

AATGAAAACAATTGTCTTTTAGTTGAAAACCGGTTT

AAATTCTTATCATGTAATCTCTTATATTTCGTTGATT

TTTTTTGTAATTTTCATATTTCTGCTCACATTGTTGAT

GTTTTGCTAAGCACCCCTTTGTTTTCTCGGCACTCAC

CTCTTTCTGATTGTTGTCTTCTACTTGAGACAACTCT

TGTTGCAGACATATCCATATATTTGTATATCAGCCA

AACATATACGTTAATTGTATGATTTGTAATTGATTC

TGTTTAGGCTTCAAGGGATAGCTAATAAAGGGCAC

ATTTCTCTGTTCTCTTGTGGATTTTATTATTGTGATA

TAGGATATAACTAGAGGAGTAGAGGTTGTCATATA

ACAATACCACCTTCGCAAATACATGCTTTGTAGCAA

TGGAGAAGTTTAGAATGCTGAGTTAAACCGTATTT

TGGCCTTCAGAAGTACCCAAGATTTACAATATGCGT

ATTAACTAATGATAAATGGAAAGCAATTTCCCAATG

TATATATCTTAAATAATTGCTCTATATCTTCTATTTTT

TTTTTTTTGTAATCTTACAATTTTCTGTCATTTCTAAA

ATTTTTTATGGTCATTTAACTTATTTATCTATATAAC

TATTGTTTTTTTCAAATTTTCTTAGTTTATTGCATACT

TCGGTATTGCCTACAAAATATTGTTTAAAAGTAATG

TATATTTTCTATGGTTGTGCTTGACAGGGATATGGG

CCATTTTAAAAAACAATGAGATGCTGACTTGGCCG

GAGAAAGTGAAATTTGCTATTGGACTTTTGCCAGC

AATGCTCGGTGGACAGGCATATGTTGAGGCTCAAG

ATGGTTTGAGTGTTCAAGAGTGGATGAGAAAGCA

GGTACTTTTGATAGATCAAATCAATAAGAATAACAC

ATGGCTTCTTATAGGCATAACTCTCCAGCCAAGGGT

CCTGGAGTCGCATTGATCATCGTGCAATTTAAACA

GAAGAAACCAATACTGAACTAAAATACTCAACATT

GCTCGATTAAAAATTGATTTATTTTCTGAAACTAGT

AAAATCTATAAATGTATCAAGTATAACAAATAAACT

CTGTTTTTGGTATATTTTTTTTGTAATTTTCCCTGTTC

GATTGTCAGGGTGTTCCTGATCGAGTCACTAAAGA

GGTATTCATTGCCATGTCAAAGGCACTAAACTTTAT

AAACCCTGATGAGCTTTCAATGCAATGTATATTGAT

AGCATTGAATAGATTTCTTCAGGTATGATTCTTTTTC

TTTCTCTTTCTATTCCTCGATGAGCTTTCCATTAATA

TTTTTTGAATGAAGGTTTGTTTAACAACTTTCATGT

GTTTAGCTGGCTGAAAAGAAGTTTTGCTTTTCCTTT

TCCTTTAAATAAACGAAATTGAAATTTTCTTTTACAT

TTTCTTGGTTACTCTTGAAGATGTTATTGTTGAATG

ATTGCACATAAGCCTTGAATATACTCATTACAAATT

TTTTATACTTTTGTCATTTTTTCTCTTTTTTCTAAAAG

TTTCTCAATATTATCTTTACCACTTCACATAAGATCT

GTGGAAGTTTCTTATATAATGAAACTAACTGAATAA

CGATCAATGGCAATATCAACAGGAAAAGCATGGTT

CTAAGATGGCTTTCTTAGATGGAAATCCCCCAGAG

AGGCTTTGCATGCCAATTGTTGAACACATTCAGTCC

TTAGGTGGTGAAGTACGACTAAATTCACGAATAAA

AAAATTTGAGTTAAATAATGATGGAACAATTAA

50

Euphorbia

Genomic
2627
GTAAAACTGGAACTAGTTATTTATTTTACCAAAACG

heterophylla

ACTTGGCTGCTGCTATGCTAATTACTTTTGTTCTATG

AAATGAAAAGTAATAGTGGTCTGCTTTTTGTCTCCA

TACACATAATTTGGGCAAATAATATGATCTTTGTAG

TCTTTGACATGTTAATTACAAACATTGAAGCATCTC

AAGTATCATCTTGTAAAAACTCCCCGGTTAGCGACC

TATTGTCTACGAACTTCTTGGCTCTGACCAAACGCC

TTTTGTCTATGAACTATTGATTTGGGGAATTTGGTT

CTTGACCTATTGTACTCACTCTAGCACGTATAACCC

ACAAATTAGATTTGCAACTTTGCTCAATTTATATCA

ATACATGTAAAATAGTCAACATTATACTGCACATCT

ATTATCAATTGCTTTAGGTATGACCCTAATGTCTCT

GGTCAATAGGTCAGGGACCCAAGGGGAACATCTC

GATCAATCAGCGTCCTTAAGTCTAGTTTTTCACTTG

AATTTGTGGTCCCTTGAGCTTGCTTAATTTCTAGGT

TTGAGATGATGTACAAAAACGTCCTCACGGTTGAA

TGGCATTTGGGCTCACTACAGTCCTCAAGTGAATTA

AACTTTTTACACTGTTTATTTAACAAAAAGTACTAA

ATCACAATTTCTTGTGGCACAGGAATATTATAATCC

AAATCAATCAATGCTGGAGTTGGTATTTGCACCTGC

AGAAGAATGGATCTCACGCACGGACACCGAGATCA

TAGATGCCACTATGAAAGAACTCGCAAAACTCTTTC

CCGATGAAATAGCTGCAGACCAAAGCAAAGCCAAA

ATTCTCAAGTATCATGTTGTAAAGACTCCCCGGTTA

GTCTCCTTTGAAAAATTGCATCGTTGATTAGTATCT

CACATGGTTTTGAAAACCAGACCGGACTGGCCAGT

TGGACCAGGTTTGACCAGAACCAGCCACTGGTTCG

GTCGGTGTTTAGTCTAAATCCGGTCAAAAACCAGTT

GTCTGATTATAACTTAAATCCGGTTCGACCACCAAC

TTAATTTAATTGAACCTTAAACCTATGACCGGTCTG

AAAGGTTCAAACTAATTGTAGTTGCGTAATGTTTGT

TTTACCCATATTTGTCAAAAGTGTGCCTCACGAAGG

GCGCGACCCTTGGCGCCTCGCCATACTACAGGCGA

GGTGGTGTTCCTATGGCGTACCCCTAAGGCCTAGG

GGTGAGCATTCCAATAATACCGAACCGAATTACCA

AATTTTCATAAAATTTTTTACTGAACCGAATTTCATG

TGATACCGAAATTTCCAAATGAAATTATTTCGGTTA

TCCGAAAAATTAAATTAATTAAAAAATGCAATTGAC

TTTTCAATAAAAAGGTTTTCAAACTCAACCAGAAAA

TCTTAATTCATCGTATTGTGAACAAAACATAACATT

AGTTATCTAATAGTAATTCAACCATACATATAAAAC

AGATAAAAATATTATATGGATAAACCGAATTATGA

ATTTTCCGAGCCATACTGAACCGAAATGTGAATTAT

CCGAACCGAATTATGAAATATCCGAACCGAAATCC

GAAATATCCGAACCGAATTCGGTTCGGTAAGTTCG

GTAATTCGGATAATACCGAATTCTGCACACCGCTAC

CTAAGGCCCGCTTCAGGATTTTAACTTACTTTAATA

TGTGTTTTCCATTTATTTTTTAAGAGTTCTAATAATT

CAAATATTTATATCTAACATTTCTCTTCTCTTGGTTC

TTTTTGTGGCACTGTTATTGCATTTAAAGTCACCTAT

CAATCAAATTATTTTTTGCGCCTAGTGTACCTGGAG

TGCGCCGTGCCTGGCTCCTTTGCGCCTCTAACAACT

ATGGTTTTACCTTCAGGTCGGTTTACAAGACTATCC

CAAACTGTGAACCATGCCGCCCTTTGCAAAGATCAC

CCGTGGAGGGGTTCTATTTAGCCGGTGACTACACA

AAGCAGAAGTATTTGGCTTCAATGGAGGGTGCTGT

CCTATCTGGCAAGTTTTGCGCTCAAGCCATTGTACA

GGTACTTGTTTTTCACTTTTTCTTGAAACGATTTCCG

ATTTGTATTAGGATATTATAGTTTCTTTTTCTTAAAT

GTCAGCCATCTAGCTTTTATGCATAGTCGATGATAT

TTTATATGACGCAGGATTATGAGTTGCTTGCTGCTC

GGGAGCAGACAAAATTGGCTGAGGCAACCGTTAG

TTAACAATGTAAATACTGTTTAAGGTATAGAGAAA

ATCATCTGATTAGTGATCATAATACACAATTAAAGC

TCAAAGAAACCAATTCTTGTACTAATACCGTTTTGG

TTGTATAATCATATATTTTTTGCCAGCATTTGCTGTT

TTGTGCACATATTTGGGAACAAAATTCAGTGAAAC

CGTGCCAATATGTATAGGGTCGTATACACCTATTTC

TCATTTAACTTCCGAAAATTTCTAACGTGTTTTGCAA

GAACTATAATTTGGTTTTAAATTTCTTTAAAGTTCTA

TTAGTGGTTGAAACTGAATATTTGACTCTAGATTAT

TGCACGGTATGACAAGAGTGTTATATATTATTTTTG

AACTTTTGAGAATCCTAATCCTTTATCTATAGCTTTG

CTAATTT

51

Euphorbia

Genomic
858
GGTAAAACTGGAACTAGTTATTTTATTTTACCAAAA

heterophylla

TGACTTGGCTGCTGCTATGCTAATTACTTTTGGTCT

ATGAAACGAAAAGTAATAGTGGTCTGCTTTTTGTCT

CTATACACGTAATTTGGGCAAATAATATGATTTCGG

TCAATGAGGGTCCTAAAGTGTTTTATTTCACTTGAT

TTTGTGGTCCCTTGAGCATGCTTAATTTCTAGGTTT

GAGATGATGTACAAAAATGTCCTCACGGTTGAATG

GTATTTTTGGCTCACTACAGTCCTCAAGCGAATTAA

ATTTTTACTGTTTATTTAACAAAAAGTACTAAATCAC

AATTTCTTGGGGCACAGGAATATTATAATCCAAACC

AATCAATGCTGGAGTTGGTATTTGCACCTGCAGAA

GAATGGATCTCATGCACAGACACCGAGATCATAGA

TGCCACAATGAAAGAACTCGCTAAACTCTTTCCCGA

TGAAATAGCTGCCGACCAGAGCAAAGCCAAAATTC

TCAAGTATCATGTCGTAAAAACTCCCCGGTTAGTCT

CCTTTAAAAAATTGCATCCTTGATTAGTATCTCACAT

GTTTTGAAAACCGGACCCGACCGGCCCGGTCAGAC

CAGGTTCGACTGGAACCAGCCACTGGCCCGGTCGG

TTTTCAGTTGATTCTTAATCCAGTAAAAAACCAGCT

GTTGTCCGGTTATACCTTAAGTCCAGTTTGACCACC

GATTTGGTTTAATTGAACCTTAAACCTATGACCGGG

TCTAAAGGTTCTGTTCGAGATGTGTGGTGGCATCC

GACATCGGAAATAAACAAGTGAAAAGAGTAGAAT

ATAAGTGGAGTAGATTGGACCTTAACACAAGCCAA

TT

52

Euphorbia

Genomic
768
TCAATTTTGTAAATATTTTGGAAATATTGTATAATTA

heterophylla

TGATAAATTCCCTTTTATCTTCAGGTCGGTTTACAA

GACTGTCCCGAACTGTGAACCATGCCGCCCTTTGCA

AAGATCACCCGTGGAGGGGTTCTATTTAGCCGGTG

ACTACACAAAGCAGAAGTATTTGGCTTCCATGGAG

GGTGCTGTTCTATCTGGCAAGTTTTGTGTTCAAGCC

ATTGTACAGGTACTTGTTTTTCTTGAAACGACTTCC

GATTTGTATTAGGATATTATAATTTCTTTTTCTTAAA

TGTCAGCCATCTAGCTTTTATGCATAGTCAATGATA

TTTTATATGACGCAGGATTATGAGTTACTTGCGGCT

CGGGAGCAGACAAAATTGGCTGAGGCAACCGTTA

GTTAACAATGTAAATACTGTTTAAGGTATAGAGAA

AATCATCTGATTAGTGATCATAATACACAACTAAAG

CTCAAAGAAACCAATTCTTGTACTAATACCGTTTTT

GGTTGTATAATCATATATTTATTACCAGCATTTGCT

ATTTTGTGCACATATATGGGAACGAAATTCAGTGA

AACCGTGCCAATATGTATAGGGTCGAATACACCTA

TTTCTCATTGAACTTCCCAAAATTTCTAAAGTGTTCT

GCAAGAACTATAATTTGGTTTTAAATTTCTTTAAAG

TCCTATTAGTGGTTGAAACTGAATATTTGACTCTAG

ATTATTGCACGGTATGACAAGAGTGTTATATAGTTT

ATCTATAGCTTTGCTA

53

Euphorbia

Genomic
634
TTGCCGGTCCAGGTAAACTTGAAATTTTGGATAAC

heterophylla

AAATAATTCTATTATTTTTGTGATCCAGTGTTTCTAA

TACTAGTATATTTTCTTTTATCATTAGTTGATATATT

GAAGCTTCTTTTGCCTGATAACTGGAAAGAGATTCC

TTACTTCAAGAAATTGGATAAATTAGTTGGAGTTCC

TGTCATTAATGTTCATATTTGGTCAGTGATGAATTC

TTTTATCTAGTGACTGTTTATGTGAGAGTTCAAATA

TCAGCACATGATTCACTAAAATAAATCTATTTCTTTT

TCAGGTTTGATCGGAAACTAAAGAATACATACGAT

CATCTGCTTTTCAGCAGGTCCTGCTCTTACGCTTTTC

TCTAGCTGTTCTTCACCCATAGAGATTTCTACAATC

ATTTTTGTAACTTTTTTAAAAGCTGTTATATTCTGAA

GGGTTCTGTTAGGGGTACGAAAACCTTCTTTCATG

AAGGAAATCAATTCATTACAAATCATTTTATGTATA

AATTGATTTGAATCTTGTATGTAAAATGATTTCAAA

TGAATTTAGGTCCTTGAGAAATAATGTTTCCAAATG

GAGGTTAAGTTGTTGCTATAATAAGTTGACGACCT

GAATCTGATTTGTACCACTGA

54

Euphorbia

Genomic
399
TTGTGTTAGATGGGCTCAACCCTACTTGTATGCTCA

heterophylla

CTCGTCCTATCGAGCCCAACACTCTCCAGGCCCACG

GATTCTCTACAGGTTCAAACAATAGTAACGTCACTT

ATCAAGCAAATTAATTTTTGCGCCTAGTGTACCTCA

AGTGCACGCTGGGCCTGGCCCCTTTGCATCTCCAAC

AACTATGGTTATACCTTGCGGTTTTCATAAAAAGCC

TCAAAATATAATTTCAGCTCATACCAGAAAATATTT

ACAAGTTTACAAAAATAGGGGTAAAATATTGACAA

AAATACAGTCCGCTATTTTTCATATAGTTTTCATCTG

GTGTGCTAGTTTTCATATAGTTTCCATATAGTTTTCA

TTAGGTTTTCATCCAGTTTTTAGACCGTATTCATGTAA

55

Euphorbia

Genomic
283
TTTTTTTGTTGTGGTAAAATTTCCCAGCCCTCTTTCT

heterophylla

ATAGGGAAGTTGAACGGGATTATTTTTTTTTTTACC

GAAGAATCAACATGAAATATCTCCGATTTTTTCTTT

CAAACGATATTTATTTGTTCAATCACTTGTTTTAGCT

CAACATTTTCTCCCACTTTTGTAATATTAAGCTTATT

TTACATTTATCAATCAAAATTTTTATTCTTTTGACAT

GACATGGATTATATATTAAACACATGTCTTTTTACA

TATTTCTCTCAAAACGTGATCTATACT

56

Euphorbia

Genomic
40
AAATTATTTATGGTTGGACAGTAAATTTGTAAATAG

heterophylla

TTTA

57

Commelina

cDNA
378
GGGTGTACCAGACAGGGTCAATGACGAAGTCTTTA

diffusa

TTGCCATGTCTAAGGCACTCAATTTCATAAACCCAG

ACGAGCTTTCCATGCAGTGCATTTTAATTGCTTTAA

ACCGTTTTCTTCAGGAAAAGAATGGCTCCAAGATG

GCCTTCTTAGATGGTAACCCTCCTGAAAGATTATGC

ATGCCAATTGTTGATCATGTCCGCTCCTTAGGTGGT

GAGGTGCAGCTTAATTCACGTATTCAGAAAATTGA

ACTAAACCCTGATGGTACTGTGAAGCACTTCCTGCT

GAGCAATGGAAATATCATTACAGGAGACGTTTATG

TATTTGCAGCTCCTGTTGATATATTGAAGCTTCTTTT

GCCTCAAGAATGGAGGGAAAT

58

Commelina

Genomic
383
CGCCTGTCATCTTAGCATCCTCATAAAGTCAAGAAA

diffusa

TTGTGAGGACAAATATATTTACTAACTGATGGAAA

CTTGATGTTTTTATCGTGGTATCCAGTATCCACTTGT

GAGCTGTTCTGTAGATTGATATATAGGAAGATATA

TGACAAACAAGATTTCTATGATTTTGCTACCACTTA

TAAGCAAAGAACAAAAGAAGTACAATAGATATGTA

TATATATATCTCTCGCATGCTTTTCTTTAAAACTATA

ATGGGTGTACAATGATTATGATTTTTTTTGTGTGTG

TATGCCTACAGGGTGTACCAGACAGGGTCAATGAC

GAAGTCTTTATTGCCATGTCTAAGGCACTCAATTTC

ATAAACCCAGACGAGCTTTCCATGC

59

Commelina

Genomic
293
TAATCGCTCCATGCTAGAGTTAGTATTTGCTCCTGC

diffusa

TGAGCAGTGGATTTCACGGTCTGATAGTGAAATAA

TTGAGGCAACTATGCAAGAACTAGCCAAGTTATTT

CCCGATGAGATTGCTGCGGATCAGAGCAAAGCCAA

AATTCTGAAATATCATGTTGTGAAGACACCAAGGT

AGATCACCTTTGTCTCTTTNCCAGCACTTTTCATTTT

GGTCCTTTGGATATTTAAATCTTGCAGAGAAAGGG

GAAGGGTAGATAATAAATAATTAGCCTACTTACTG

CCATAGCACA

60

Commelina

Genomic
284
CCTATTGGGCCGTTCACTGGTCTATTGTTGAAACAG

diffusa

TTGATATATTGAAGCTTCTTTTGCCTCAAGAATGGA

GGGAAATTCCCTACTTTAAGAAGCTGGAAAAGCTA

GTGGGAGTTCCAGTGATTAATGTCCATATATGGTG

AGTCATTTTTTCTCTAGCAATTTCTGCTACTTCTTAG

TGACAGTCCCTCATATAAATGAATAGTATATGATTT

ATTTATATATTTCTTATGATGTTCTTATTTTTAAGCTT

AATTGTTTGTATACATGGGTTGAGATACTTC

61

Digitaria

cDNA
458
AAAGAAGCCAAAAACAATCTCAACCCAACAACATC

sanguinalis

TTCTTCTTCTTCTAATAATAAGTACCTGCAAGGTCAT

GTCTCTACTTGGAAATTCTATAGTAACCACCCATGT

ACTGTCCTTTAGTCACGCTGATATTATGGGTGCTCA

TCGGTTGCAATTCCCGGCTGTCCGATCAAGAACCA

CCACTACCAAGAATGTCTGCCCTTTCAAGGTGCTCT

GCCTGGATTATCCAAGACCAGACCTTGACAACACTT

CTAACTTCCTGGAAGCTGCCTACTTGTCTTCTACCTT

CCGCACTTCCCCTCCTCCAGCTAAACCCTTAAACGT

TGTAATTGCTGGTGCAGGTTTGGCTGGTCTATCCAC

TGCTAAGTATTTGGCTGATGCCGGTCACAAGCCCCT

TTTGCTTGAAGCAAGAGACGTTCTTGGTGGTAAGG

TAGCCGCTTGGAAAGATGATGATGGAG

62

Digitaria

Genomic
7350
TTTCTTTGATTTTCTATGATTTTCTAAAGTTTTGGAG

sanguinalis

AAAAAACTTTGGCCATCTATGATTTTCCATTTTCTAT

GATTTTTTTTATTTTCTATGATTTTCTAAAGTTTCTAT

GATTTTCTAAAGTTTTGGACAAAAATATTTATGGAG

GACATTTGATAAGACATCTATCTATAAAGCCCACTT

TGACCCATTTAACTAGGATAAGTAGAAATAAGACC

AATTAAAGAATATTTACTTATACATGTTCAACATTTT

TTGTTAAACAAGTTCAACATTTGATAATGAAATGTC

GACATTGATTAACCTAAATGTTGCAATTGGAGAAC

AGCAATATTGAAATCAAAGGGCCGGAATGTTGAAT

GCTCAAATCATAAATGTTGAATGCTAACATCACCAA

TGATGAACTTTATCTCGTCTTCTCCGGGCACGGCGG

AGCAGCAGCGGCGTCTAGGCCAGGCCGCGCGACA

GAGCAGTGGCGGCCTAGGCCAGGGCGCATGCATG

GATAGCGGGAGCGGCGGCGGCGCCGGTGTGGAG

CAGGCCATGGTGCGATCAGACTTGGCCCCATGAGA

GGGCTCCGACACTGTGCGGGTTTGGTCGGTGGTG

GGTGTGGCAGGATGACCCGAGGCTTCCTACATAAT

TTCTATCCATCTGTGATAAGATTTTAATTTCTACATA

TTTAATGTTTGAGATCCGTATAAATAATTACAACTC

TTAAATCTACACCTCTCAAACCCTATCTCCCTTTCTA

ATCCCCTGCTCCCTCTCTCCTACACTACACCTGCCGC

CCACCGTGTTACCAAATACGATACACTTAAATAGGT

GTATTTACAATTTATTTGAAAATATAAATAGATAGA

GTATATAAATATCTATAATTATGCAAAATTTAAAGT

TTAACAAAAATTTGTGCAAAGAGATAAAAAAAAGG

AAAACTCAACACTAAATAGTTGCAGATTGCGGGTT

TCCAATGAAAAGTAAAGCACACAACTATTTATGTGT

TGGTTTCTCTTTTTCATATCTCCTTGCACAATTTTTTG

TTCAACCAGAAACTTTGCATGACGAGAGATGTTTAT

AAGCTTTATCCATCTATACTTTTAGATGAATTTTAGA

CGCACCGATTTAGTGTGCTACCGTGTTTGGTAACAC

AGTAACATTTAAAATCCTCTGTCCCAAAATTTAAGC

ATTAATTAAATATATATGCTAAAGTTCCTCATGCCTT

GTGGCCTCATGTGGGACCTACGTACTGTTTATGTG

GGACCCACGTGTTATTTAGGTGAGCCCTATGTAGG

ACCCACGTGCTATTTATGTGGGACCCACGTGCCATT

TAGGTGGGACCCACACACTATTTAGAGTGGGACAC

ACTCTCTTTGGTGGGGCCTGCTTAGTGGGACCCAC

AACAATATTAAGTGTCTATGTTAAAAATTATCGAGG

ATTGTTTTTCCATTCTTTGCGGTATAAATATATTTAT

TTTTCTATGTATAAAAATAATATCTAACTTTGTATAC

TACATTCATTTGTGATAGTTCTAATATTTTTTCTACT

TTGCTTTAAGATCATAAATTTGGAAAATAAGATCGA

ATTATACATTCATTACTAAATTTATCTTTCCTTCTATA

AAAATTTAAAAATTAGTGTAACATAACACGTCACTT

CATTAGCTATTTCTATTACCACTTAGAAAAAAGTTA

TATAGCTCTTAAATGATCATTATAATTAAAAAATAT

GTAAACTTAATATTGCAATTGAGTATAGTAAGATG

ATAAATTTGTATTGAGTTTAACATTTTTTATATAGAT

GAGCATGGCGCGTCAACCTGACTAGTATGTTATTA

GATTTCCCAATTATAACATTTTTAATAAATTTAGACA

CTTATTCTACTTATCTAGGTTCACCGAAGATTCTATA

AATTTAGTGAAAGGCTAGAAATATTTATATATTTTG

TAAGGGAGGGAGTAGACGGAGATGGCAGGTTACA

CAATGAACGAGCTGCCACGTTGACTCAAATAGTTG

CCACGTGTTATCTAGTTTCTTTAAAAAGAAAGCACC

AAGAGAAAATAAGAGAGATGACGTGGCGGTATAT

ACCGCGGAGACGTAGAGCGCACCAGGCGCCAAAA

GGCATCCTCCTCCTCCACATCCTCCTCACCCCGCGCT

CGTCGTGCTCTTGTCCCTTTCCACCGCCCCAACCAA

GTCAAGTGCGGAGGAGGCCGCCCGCCTCCCCTTAT

CATCGCGCGACACGGCTTCCTCCCCACCTGGGCTCC

TCCGCCTCCACGCCGCTCCCCGCTGCCCCGCCTCCC

CTAGTCCCTCCCTCCTCCTCATCCGGTAAGTCCTCGT

TGCCTGCTCACGCTGCGTTTCCATTTAATCACGCGG

GAGTCAGGTCAGGCGGGATTCGGTTCCCATGGGG

ATGGGGGCGGCTCTCGTGGTACCTGCGACCGGAA

ATTATTAACGGGCTATATAGAAATGGGGGATTTCT

TAGGGTTTGTGCTTTGAAGGCATTGGAAAATTGTG

ACTGGTTTGGGGAATTGGCAGTTACAACTTACATG

GAGTAGTCTGCAGTTGTTGGGCACAGAGTTTTAGC

GGTGTTCTGGTAGTGTTTATAGAGTATGGCACACA

TTGTATAGTATAGGGAGACTTTTGGTTCAAATTTAA

TATTAGACGGTCATGCTACAAAATGGGAGGTCCAA

GTTGTGTATTCTGTTTCCTTTGCATCATTGTTAACTC

ACTGCTTGTTCTCAGCATAGAATAACTAAATCAATG

TGTACCAACCTTGATCAGTTTACTTACATACTTGGA

AGATGCGCGTAAGAAATGATCTCATGAACTGCCAG

TCTAATAGCTCCTCTTGGTTATGCAGTAGTCTGCCT

CTGCGTATTGGTTAATCAGAGCTGACAACAATCAC

CAAAAGTTGCTTCGACATGGATACTGGCTGCCTGT

CATCTATGAACATTTCTGGAGTGAACCAAACGAGA

TCTTTTGCGGGACAGCTTCCTACTCAGAGATGCTTT

TCAAGTAGTCACAACGCGAGCTTTGCTGTGAAATC

TCTAGTTGTAAGGAATAAAGGAAGAAGGTCACACC

GTAGACATTCTGCTTTGCAGGTTCAGTTTTTTGTTC

ATTTTCTTCTCCAATTTTCAGGTCATTTCTTAGTGAA

AATATGATTGATTAGCTTTTCTGCAGATTGTCTGCA

AGGATTTCCCAAGACCTCCACTAGAAAACACAATA

AACTATTTGGAAGCTGGACAACTCTCTTCATTTTTT

AGAAGCAGCCAACGCCCCAGTAAACCATTACAGGT

CGTGATTGCTGGCGCAGGTCCGACGTGATTTGTGA

TTAATGTTTTCACAAATCTTTTTGTCAGTTACTTCCA

GGGTAATAACAGTTGAGTTTTAGCTTTATTAATTTG

TGGTGTAACTTTTGCAGGATTGGCTGGTCTATCAAC

GGCGAAATATCTGGCAGACGCTGGTCATAAACCCA

TATTGCTCGAGGCAAGAGATGTTTTGGGTGGAAAG

GTCTGAAAGATACTTACATGATTGTTTACAATGCTC

TTAATTGCTCGCATCCGGTGTTTTCATCGTTTGTTCC

TTTAATGATTTTTTTTTTGTTTTTTTGTTTATGCACTG

AACAGATAGCTGCTTGGAAGGATGAAGATGGAGA

CTGGTATGAGACTGGGCTTCATATCTTTTGTAAGTT

ACAGTTTCTGGTCCTTAAGGTTGTCTTCATGATATTT

TATTTTCTAGATTATTTCTATTAGAAACATACATTTA

ATGTAGACATGTTAACAAGCTGTTAAGGCGCACCA

GCACACAAACTTCTAAAGCACAGTTGTCTATCGTGC

TTGTTTATTTCCTTTAAGGAATATCTGTTTTAGTTTG

CAAAATTATTATTGAGAAAGGAGTTTTTTTTTAAAT

TACTAATAGCGTGAAAATAGCATGGAAAGTTTGCA

GGCTACTAAAAAAGCGTACATCAGTGCATGTTTTA

ATGTTACGTAAACGTGTTGTATACTCCTTATTATCC

ATAATGGCATAGTTGAATATCTGTTATTCTGTTCAC

AAGAACATTCGATTGCTACCATTCCCTTCATAGCTT

ATATAACACTGCGTGTATGTAACCATGCATTTTTGT

TTTAAGTTGGAGCTTATCCCAACATACAGAATTTGT

TTGGCGAGCTTGGTATTGAGGACCGTTTACAATGG

AAAGAACACTCCATGATATTTGCCATGCCGAACAA

GCCAGGAGAATTCAGCCGGTTTGATTTCCCAGAAA

CTTTGCCAGCACCTGTAAATGGTACGACTATGCGAT

TTTGGAGTTGTTGCAACTGATTTCCTAGATAATCCA

GAAATACATTCTAATCTTAGTCTACTCATTTTGCTTA

TGGACAGCATTAACGCTTCCAATTGATGCTGTACTA

TGATTCACCACTGTACTTTTAACAGGAATTTGGGCC

ATACTGAGAAATAATGAAATGCTTACCTGGCCGGA

AAAGGTGAAGTTTGCTATTGGGCTTCTTCCAGCCAT

GGTCGGCGGTCAACCTTATGTTGAAGCTCAAGATG

GCTTAACAGTTTCAGAGTGGATGAAAAAGCAGGTA

CGAATTCAATTTGTCGATTAGACTAGTCTCTGTGTA

ACAGAAATACTGCCATCTCATCAGTACTAGAGAGC

TTTTAGTTTACCAATAGATTGTTTCCTTTTATTTTCTT

ATCTTCCTGAAGAAGTACAGGTAGCTCCATAAAAT

GCTTTATATGCTCAAATTCTTAACTTATATTTGGTGT

AAATCTTTTTCTGTGAAAATTAAGACAGAGCAATGC

TTATAGATGCATTAACTTGGCCAGTTAAAGGCCAG

CAATGTTCATCATGTTAAGTTCAGCAATGTACCAAA

AAAATGAAAAAAAAAAAACACACAAGAGACATAAT

GGTTTCTTGCTAACTGATACACATGCCGTTTTCTTCA

AAAATTGGTTTCACCTTTGTCGTTTGGAATACAGAT

GGTAATATATCTTTCTATTTTTCTGTGGAGATATGT

GGTGCCTGATACAATTATTTGATCAGCACAGGGTG

TTCCTGACCGAGTGAATGATGAGGTTTTTATTGCAA

TGTCCAAGGCACTCAATTTCATAAATCCTGATGAGC

TATCCATGCAGTGCATTTTGATTGCTTTGAACCGAT

TTCTTCAGGTACATCTGTTGTTGCTCTATGTTATTGT

GTAATATATTACTTGCCTGTTCTGTTTGGAGAAATA

GCTTACATATGTTGATTCTTGCTTTCTTGTCTGTACT

CTGTATTATTTTTGAACTGAGAGAGATGCCAATATG

TATTTGCATGTGGGTATTTTGTGTAAACGTGCAGG

AGAAGCATGGCTCAAAAATGGCATTCTTGGATGGT

AATCCACCTGAAAGGCTGTGCATGCCTATTGTTGAT

CACATTCGGTCTAGGGGTGGTGAAGTTCGCCTGAA

TTCTCGTATTAAAAAGATAGAGCTGAATCCTGATG

GAACTGTAAAACATTTTGCACTTACCGACGGAACTC

AAATAACTGGAGATGCTTATGTTTGTGCTACACCA

GGTGTGATTTATTACCAGTAAACCTTGTTTCCTGTG

CAGCTATACTGCTATACAACTGAAGTACTGAACTGA

CAAGTCTTTGTATTTAGTTGATATCTTCAAGCTTCTT

GTACCTCAAGAGTGGAGTGAAATATCTTATTTCAA

GAAGCTGGAGAAGTTGGTGGGAGTTCCTGTTATCA

ATGTTCATATATGGTTAGTTAATTGAAATATTTGGT

TCTGAATTGGAAATGCTCCATTTCCTTATATGGTTA

TGCTTCTTCCTTGAGGCATTTCTGAAGCTTTGCTGA

GAACTGTTGTTTTGAATGCCTCAGGTTTGACAGAA

AACTAAAAAACACATATGACCACCTTCTTTTCAGCA

GGTACATCTTCTGGCCATATTCTTAGTTCATGCATTT

TTTGTGCAATATTTCTTGATTCATGCACTGTTCAGGT

TGTGCACATTTACTGTTGATGGTATTAAATACCATA

TGGCCCTTGTTGATCTTGTCAGTAACCTGCATTTTTT

TTCAGGAGTTCACTGTTAAGTGTTTATGCAGACATG

TCAGTAACCTGCAAGGTACCGACTATCATCTTCAGG

GCAATATCAGTTTTGTTCAAACACTAGCATACTAAT

ACATTGGCCATGATTTCTTCATTAATTCTAGAGGCT

CAGTGACCTTTACATGCGTCATCTACATAAACGGTC

CTAGGGCTCAGATGATTAAGAAAGAATTCATTATA

AGTGGAAATATAAATATCTTGCACATTAAAAATTTT

GGACATCTGTGCTAGATGTATTGAAGTGTGTGACT

TTGTCATTGCTTACATGTCAGTGGTCACTGTGTTGT

ATTGATGAATCATGATATGTTAAATAGCGAAGGAC

ATGATTGCAGATTGCACACTCACCTTTTTTCTTTCCT

TTTGTTGTCTAATTCTTTACAGGAATACTATGATCCA

AACCGTTCAATGTTGGAGTTGGTCTTTGCTCCTGCA

GAGGAATGGATTGGACGAAGTGAAACTGAAATCA

TTGATGCAACTATGGAAGAGCTAGCCAAGTTATTT

CCTGATGAAATTGCTGCCGATCAGAGTAAAGCAAA

GATCCTTAAGTATCATGTTGTCAAGACACCAAGGT

GAGGATATTTGTCGGACACTTCTGATAGATAAGCA

AGTAGCTCTAGCTCTGACAGTTTTTTGTGTTGTTTCC

TTTTGTTCATATTCTGGCTTGCTTTGACAGATCGGTT

TACAAAACTGTTCCAAACTGTGAACCTTGTCGACCT

CTTCAAAGGTCACCGATCGAAGGGTTCTATTTGGCT

GGTGATTACACAAAGCAGAAATACTTGGCTTCCAT

GGAAGGTGCAGTATTATCTGGGAAGCTTTGCGCCC

AATCTATAGTGCAGGTAAATACACGCCATGTTCCTT

GCTGTACATAAAAGCATCGGATTGCTTATAAGTTTG

ATCGTTTCGATGTGATACATTTTTGCAGCTAATTATT

TAACATCTGCTGCTTTCAGGATTATGGCAGGCTCTC

CCTCAGGAGCCAGAAAAGCCTGCAATCCGAAGAA

GTTCCTGTCGCATCTTAGGCATAGTTCAGGCTCCCA

TTTGGTGTGTCATCTTATCACCTATTTCGTGGGAAC

CCACCAACTGCTCATGTTGAGGGACCTGACCTCTTG

TGCCCCTCTGACAATTCCCTAGAGCTGAAATGTGAC

AGTAGTTGATATCATATTGGGAAACAGGTGATATA

TATGTAAAACGACCTGCATAGCAATTCTTAGACCTT

TGCAAAAGGAAAAGCGAAAAAAGATATCTCAGAT

AGATATTATCTTGT

63

Digitaria

Genomic
2640
GTCTGAAAGATACTTGCGTGATTGTTTGCAATACTC

sanguinalis

TGGTCCTTTTCATCGTTTGCTCCTTTTATAATTAGTT

TTTTCGTTTATGCACTGAACAGATAGCTGCTTGGAA

GGATGAAGATGGAGATTGGTATGAGACCGGGCTT

CATATCTTTTGTAAGTTACAGTTTCTGGTCCTTGAG

GTTCTCTTAATGATATTTGATTTTCTAGATTATCTCT

ATTAGAAACATGCATTTAACGAAGACATGTTAACA

AACTGTTGAGGCATACCAGCACACAAACTTCTAAA

CCACAGTTGTGTCTATCGTGCTTGTTTATTTTTTTTT

ATGGAATATCTGTTTTATTTTGCAAAATCATGATTG

AGAGAGGAGTTTTGTTAAATTACTTAGTGTCAAAA

TAGCCTGAAAAGTTTGCAGGCTACTAAAGCATACA

TCATTTCATGTTTCAATCATGTTGTATACTCCATAGT

ATCCATAATGGCATAGCTGAATATATGTTATTCTGT

TCACAAGAGCATTCGATTGCTACCATCCCTTTATGT

AACAATGCATTTTTTGTTTTAAGTTGGAGCTTATCC

CAACATACAGAATTTGTTTGGCGAGCTTGGTATTG

AGGACCGTTTGCAATGGAAAGAACATTCTATGATA

TTTGCCATGCCGAACAAGCCAGGAGAATTCAGCCG

GTTTGATTTCCCAGAAACTTTGCCCGCACCTGTAAA

TGGTATGATTATACACGATGTTGAAGTCGTTGCAA

CAGATTTCATAGAGAATCCAGAAATGCATTGCTTCA

GGCTGGGGCTGTGTCCCTAAAACTCTAAAAGAAAA

TGCAGAAATGCATTCTAATCTTAGTCCACTCATTTTT

TTCTAATATATGACAGCATTAGAGGGTTTATTAGTG

GCAGTAGTAACACTACATGATTACCATTCAGCTTAC

ACTTCCAATTCATGTTGTACTTATGATTTACCATTGT

ACTTTTAACAGGAATTTGGGCCATACTGAGAAATA

ATGAAATGCTTACCTGGCCAGAGAAGGTGAAGTTT

GCTATTGGGCTTCTTCCAGCAATGGTTGGTGGTCA

ACCTTATGTTGAAGCTCAAGATGGCTTTACGGTTTC

AGAATGGATGAAAAAACAGGTACGAGTTCAATTTG

TTGGTTAGACTTATCTCCATGTACAAGAAATACTGC

CATCTCATCAATACTAGAGAGCCTTTAGTTTGCCAA

AAGATTGTTTCCTTGGCTTTTCTTATCTTCCTGAAGT

ACAGGTAGATGAAAATGCTTCATATGCTCAAATTCT

TATCTTACATTTGGTGTAAATCTCTTTCTGCAAAAAT

TTAGACAAGGCTGCTCATAGACTTGTTAACTTTGCC

AGTTAAAGTCCAGCAATGTTCATCTGTAAATTCAGC

ACTGTAACAAAAAATGGGGAAAAAAAGGACGAGC

ACATAAGAGTTTCTTGCTAACTGATGTACATAAGCA

GCGTTCTTCAAATTTTGGTTTCACCTTTGTAATTTGG

AATACAGATGGTAATATATCTTTCTATTTTTTTATGG

AGCCATTTGGTGCCTGATACAATTATTTGATCAGCA

CAGGGTGTTCCTGATCGAGTGAATGATGAGGTTTT

TATTGCAATGTCCAAGGCACTCAATTTCATAAATCC

TGATGAGCTATCCATGCAGTGCATTTTGATTGCTTT

GAACCGATTTCTTCAGGTACATCTGTTGTTGCTCTA

TGTGATTGTGTAATACGTATACTACTTCTGTTTGAA

GAAATAGTTTACATATGTTGATTCTTGCTTTCTTTTA

TGTATTATTTAGTTACCTGAGAAGGTTGCTAATACG

TATTTGCATGTGGGTATTTTGAAAAGTTTATTTTGT

GTATACGTGCAGGAGAAGCATGGTTCAAAAATGGC

ATTCTTGGATGGTAATCCACCTGAAAGGCTGTGCCT

GCCTATTGTTGATCACATTCGGTCTAGGGGCGGTG

AGGTCCGCCTGAATTCTCGTATTAAAAAGATAGAG

CTGAATCCTGATGGAACTGTAAAACATTTTGCACTT

ACCGATGGGACTCAAATAACTGGAGATGCTTATGT

TTGTGCTACACCAGGTGTGATTTATTACCAGTAAAC

CTTGTTTCCTGACTTCCTGTGCAGCTATGCAACTGA

ACTGACTAGTCTTCGTATTTAGTTGATATCTTCAAG

CTTCTTGTACCTCAAGAGTGGAGTGAAATTTCTTAT

TTCAAGAAGCTGGAGAAGCTGGTGGGAGTTCCTGT

TATCAATGTTCATATATGGTTAGTTGATCGAAATAT

TTGGTTCTGAATTAGAAATGCTTCATTTCCTCGTAT

GGTTATGCTTCTTCCTTGAGGCATTTCTGAAGCTTTT

CTGAGAACTTCTGTTGTTTTGAATACCTCAGGTTTG

ATAGAAAACTGAAAAATACGTATGACCACCTTCTTT

TCAGCAGGTATTCTCCTGGGCATATTTGTAGTTCAT

GCATTTTTTTGTGCACTATATCTTAATTATAATTGTA

TCAAGATATTTCATGCGTTGTTCAGGTTGCGCACAT

TCTACTGTTCATGTACGAATGCTCATTTTCGGTATTA

AATGCCATGTGTTTATTATTATTTTTTCAGGAGTTCA

CTGCTAAGTGTCTATGCAGA

64

Digitaria

Genomic
1012
CAATGACTTTCACATGTGCCCTATACATAAAAGGTC

sanguinalis

CTACGGCTCACATGATTAAGAAGGAATTCATTATTA

AGTGGAAATATAAATATCTTTCGCATTAAAAATTTT

GATATCTGTGCTAGATGTATTGAAGTGTGGGACTT

TGTCATTGCGAACATGTCAGTAGTCACTGTGTTGTA

TTGAAGAATCATGATATATTAGGTAGCGATGGAAA

TATGCACACTCACCTTTTTTCTTTCCTTTTGTTGTGTA

ACCCTCTACAGGAATACTATGATCCAAACCGTTCAA

TGCTGGAGTTGGTCTTTGCTCCTGCAGAGGAATGG

ATTGGACGAAGTGAAACTGAAATTATTGATGCAAC

TATGGAAGAGCTAGCCAAGTTATTTCCTGATGAAA

TTGCTGCCGATCAGAGTAAAGCAAAGATCATTAAG

TATCATGTTGTGAAGACACCGAGGTGAGGTTATTT

GTCAGACACTCCTGATAGATAAGCATAAGTAGCTC

TAGCTCTGATAGTTTTAGTTTAGTGTTTTTTTTTGTG

TGTGTGTGTGTGTGTGTTGTTTCCTTATGTTCATACT

CTGCCTTGCTTTGACAGATCGGTTTACAAAACTGTT

CCAAACTGTGAACCTTGCCGACCTCTCCAAAGGTCA

CCGATTGAAGGGTTCTATTTGGCTGGTGATTACAC

AAAGCAGAAATACTTGGCCTCCATGGAAGGTGCAG

TACTATCTGGGAAGCTTTGCGCCCAATCTATAGTGC

AGGTAAACACTCGCCACATGTTCTTGGTTGTACATA

AAAGCATCAGATTGCTTGTAAGTTTGATCATTTTGA

TGTGGTACATTTTGGCAGCTAATGATTTAACATCTG

CTGCTTTCAGGATTATAGCAGGCTCTCCCTCAGGAG

CCAGAAAAGCCTGCAATCCGAAGAAGTTCCTGTCG

CATCTTAGGCGTAGTTCAGGCTCCCATTCGGTGTGT

CATCTTATCACCTATTTCGTGGGAACCCACCAACTG

CTCATGTTGAG

65

Kochia scoparia

cDNAContig
1995
ATGAGTTATTTTGGATATGCTTGTGCTACCCAATCC

ACTTCAAGATGTGTTCTTTTGGGCAATTCTGGTAAC

CCCACTTCAGTTTCATCTCGTGGCAGTGATTTCATG

GGTCATTCTGTAAGAAATTTCAGTTTTAGCAAAAGA

CAGAGAATTGGGCACTGCCCATTGAAGGTTGTTTG

TGTAGATTATCCAAGACCAGAGCTTGAAGGTACAG

TCAATTACTTGGAAGCTGCTTATTTATCTTCAACTTT

TCGGAATTCACCTCGTCCTCAAAAGCCGTTAGAGG

TTGTAATTGCCGGTGCAGGAGGGAAAAGGGTAGT

GATAATTACTGGGTGTTTGGCTAAGGATGTTCAGC

ATAGCATGGTTGTCTCTTACAACCACACTCATGTAT

TACCATGGACCCCCTTTGGAGAGGGTAAGGTGGTT

TTAATTGTATCCATAGGTTTTCAAAGGGTGACAAGT

GGAGGGAAATGGTTACCTTCAGGAAATGAGGGAA

CAGGGAGTTGGGTCCTTGCCTTCATGGGAAAAGAG

AGATTGTTAGGTTTGGCTGGTCTATCCACAGCGAA

GTACTTGGCAGATGCAGGACACAAACCCATATTGC

TTGAGGCACGAGATGTTTTGGGTGGAAAGCTGTTG

AAGTTATTCATCATTCTGTACAATGTTAAGTCAGTG

TTAATGAGGTTTAGAGGGGTTGCAGCGTGGAAAG

ATGAGGATGGTGACTGGTATGAAACTGGGCTCCAT

ATATTCTTTGGGGCTTATCCAAATGTGCAGAACTTG

TTTGGAGAACTTGGTATCAATGACCGATTGCAATG

GAAGGAACATTCTATGATTTTTGCAAGGCCTGACA

AACCGGGTGAATTTAGCCGCTTTGATTTTCCTGAAG

CCCTGCCTGCACCTTTAAATGGCATATGGGCAATCT

TAAGGAATAATGAAATGCTAACATGGCCAGAGAAA

ATCAAGTTTGCTATTGGTCTCTTACCTGCTATGGCT

GGTGGACAGTCCTATGTCGAGGCACAAGATGGTTT

AAGTGTTCAAGAGTGGATGAAAAAACAAGGTGTG

CCTGATCGTGTTACAGATGAAGTATTCATTGCCATG

TCAAAGGCACTTAACTTCATAAATCCGGATGAACTT

TCGATGCAGTGTATCTTGATTGCTCTGAATCGATTT

CTTCAGGAAAAGCATGGTTCAAAAATGGCTTTCTT

GGATGGAAATCCTCCAGAAAGGTTATGCATGCCTA

TTGTTGAGCATATTGAGTCACTAGGTGGTGAAGTG

CAGCTTAACTCTCGTATTCAAAAGATAAAGTTAACT

CAAGATGGAAGTGTGGATAGCTTCTTGCTAACCAA

TGGGAAAGAAGTTAGAGGGGATGCTTACGTCTTTG

CTACTCCAGTTGACATCCTAAAGCTACTTCTTCCTG

AAGAGTGGAAAGAAATTTCATACTTCAAAAAGTTG

GAGAAACTAGTAGGAGTTCCTGTCATTAATGTTCA

CATATGGTTTGATAGGAAATTGAAGAATACATATG

ACCACCTACTCTTCAGCAGGAGTCCTCTTTTGAGTG

TCTATGCTGATATGTCAGAGACATGCAAGGAATAT

TATGATCCAAACCGGTCCATGCTGGAATTGGTTTTT

GCACCTGCAGAAGAATGGGTTTCTCGGAGTGACAC

GGACATTATTGAGGCAACAATGAACGAACTTGCCA

AGCTTTTTCCTGATGAAATCGCAGCTGATGGGAGC

AAGGCTAAGATCCTAAAATATCATGTAGTCAAAAC

TCCCAGGTCTGTTTATAAGACAGTTCCAAACTGTGA

ACCTTGTCGACCATTGCAAAGGTCACCAATAGAAG

GTTTCTATTTATCCGGTGATTACACAAAGCAAAAAT

ATTTGGCTTCAATGGAAGGTGCTGTCCTGTCTGGG

AAGTTTTGTGCACAGGCTATTGTACAGGATTATGAT

ATGCTTGTTGCTCGAGCACAAAGAGAATTGGCAGG

GGCAGGCAACGCCTGA

66

Kochia scoparia

cDNAContig
1971
ATGAGTCATTTTGGATATGCTTGTGCTACCCAATCC

ACTTCAAGATGTGTTCTTTTGGGCAATTCTGGTAAC

CCCACTTCAGTTTCATCTCGTGGCAGTGATTTCATG

GGTCATTCTGTAAGAAATTTCAGTTTTAGCAAAAGA

CAGAGAATTGGGCACTGCCCATTGAAGGTTGTTTG

TGTAGATTATCCAAGACCAGAGCTTGAAGGTACAG

TCAATTACTTGGAAGCTGCTTATTTATCTTCAACTTT

TCGGAATTCACCTCGTCCTCAAAAGCCGTTAGAGG

TTGTAATTGCCGGTGCAGGAGGGAAAAGGGTAGT

GATAATTACTGGGTGTTTGGCTAAGGATGTTCAGC

ATAGCATGGTTGTCTCTTACAACCACACTCATGTAT

TACCATGGACCCCCTTTGGAGAGGGTAAGGTGGTT

TTAATTGTATCCATAGGTTTTCAAAGGGTGACAAGT

GGAGGGAAATGGTTACCTTCAGGAAATGAGGGAA

CAGGGAGTTGGGTCCTTGCCTTCATGGGAAAAGAG

AGATTGTTAGGTTTGGCTGGTCTATCCACAGCGAA

GTACTTGGCAGATGCAGGACACAAACCCATATTGC

TTGAGGCACGAGATGTTTTGGGTGGAAAGCTGTTG

AAGTTATTCATCATTCTGTACAATGTTAAGTCAGTG

TTAATGAGGTTTAGAGGGTTGCAGCGTGGAAAGAT

GAGGATGGTGACTGGTATGAAACTGGGCTCCATAT

ATTCTAACTTGTTTGGAGAACTTGGTATCAATGACC

GATTGCAATGGAAGGAACATTCTATGATTTTTGCA

AGGCCTGACAAACCGGGTGAATTTAGCCGCTTTGA

TTTTCCTGAAGCCCTGCCTGCACCTTTAAATGGCAT

ATGGGCAATCTTAAGGAATAATGAAATGCTAACAT

GGCCAGAGAAAATCAAGTTTGCTATTGGTCTCTTAC

CTGCTATGGCTGGTGGACAGTCCTATGTCGAGGCA

CAAGATGGTTTAAGTGTTCAAGAGTGGATGAAAAA

ACAAGGTGTGCCTGATCGTGTTACAGATGAAGTAT

TCATTGCCATGTCAAAGGCACTTAACTTCATAAATC

CGGATGAACTTTCGATGCAGTGTATCTTGATTGCTC

TGAATCGATTTCTTCAGGAAAAGCATGGTTCAAAA

ATGGCTTTCTTGGATGGAAATCCTCCAGAAAGGTT

ATGCATGCCTATTGTTGAGCATATTGAGTCACTAGG

TGGTGAAGTGCAGCTTAACTCTCGTATTCAAAAGA

TAAAGTTAACTCAAGATGGAAGTGTGGATAGCTTC

TTGCTAACCAATGGGAAAGAAGTTAGAGGGGATG

CTTACGTCTTTGCTACTCCAGTTGACATCCTAAAGC

TACTTCTTCCTGAAGAGTGGAAAGAAATTTCATACT

TCAAAAAGTTGGAGAAACTAGTAGGAGTTCCTGTC

ATTAATGTTCACATATGGTTTGATAGGAAATTGAA

GAATACATATGACCACCTACTCTTCAGCAGGAGTCC

TCTTTTGAGTGTCTATGCTGATATGTCAGAGACATG

CAAGGAATATTATGATCCAAACCGGTCCATGCTGG

AATTGGTTTTTGCACCTGCAGAAGAATGGGTTTCTC

GGAGTGACACGGACATTATTGAGGCAACAATGAAC

GAACTTGCCAAGCTTTTTCCTGATGAAATCGCAGCT

GATGGGAGCAAGGCTAAGATCCTAAAATATCATGT

AGTCAAAACTCCCAGGTCTGTTTATAAGACAGTTCC

AAACTGTGAACCTTGTCGACCATTGCAAAGGTCAC

CAATAGAAGGTTTCTATTTATCCGGTGATTACACAA

AGCAAAAATATTTGGCTTCAATGGAAGGTGCTGTC

CTGTCTGGGAAGTTTTGTGCACAGGCTATTGTACA

GGATTATGATATGCTTGTTGCTCGAGCACAAAGAG

AATTGGCAGGGGCAGGCAACGCCTGA

67

Kochia scoparia

Genomic
12119
AGGAAAATCTAGATGAAATCACAAAACAAAACCCA

CTAAACTATACTTATCCTAGAAAAGTAAAAGCATTC

AATTAGTGATGAGAAGCTTAAGCATACGCTGCACA

AAAACAACCAACTAATCAACTCATAGAAAACAGCA

ACTGATGTCAGTAAGTAGTTTCTAAAATTTTACCTT

CCTTGCAAGAGATGACCAAGCCCAACTGTCCCGAA

CACGGTCAGGGAAATGAGAGGAAGGCCATATCTC

ATAAATGGGTTCCTTCTCCCCAATCTCTTTAATCCTG

AATACTGAAAGCCTGGAAAAGCAGCAGCTTTCTTT

GAATCATTAACTGGCGCTCTCGCAACGACTGTCAT

GTTTCTCCCTCTAAATATGACTCTGAAGTTCCAATTT

CACTCAGAAATTAGTTGTTCAACTTAGCAATCAAAC

AAATTTAACTAATTTGTAGCTTAAACACTTGTAAGA

ACAACATCTGGAAAACCCACATCAAGTTTTGTTCAA

CGAAAGCACCATAATTGATCCATAAACCAAGAAAA

CTGGCAAATTCATACTCCTCATCAAACATTTCGACA

TTCATAGTTTCAAAAAGTAGAATGATAATTTTAGAA

AGTCGTTTATACTTCAAAATTGCAAAGAATAAGAC

GCATAACGTACTGTATCCATAAACGATTGAAAAAA

AATAATTCATGCTTTTGATTGATATTCTGTGCCTTGT

AAAAATATCTGTAATAGCGCAATTAATTGACACTTG

CAAAAGCTCAAATCAAAACGCTAAAGTTAAATCAC

AAATAGCAACTAATCAAATTCATAATTTGTCGAAAG

TATGAATGAGGTTAAAGTTACACAAAATACCTGAA

AATGGCGAAAATAATGCGGAAAAATCTTTATTCTTC

TTTAGCTCGTTCTTCTTCTGCAAGAAGCAAACTTGA

TTTTAGGATATGCTAATTTCGCAAACCAGAATTTAG

GGTTCGTTTGGTAGGGCGTAAAACGTTTTCAAATG

AAAATAGTTTTCATTGAAAAACATTTTACAATTGAA

AACTCATTTTCATACAAGTTTTCTATTGTTTGGTTGA

ATGGAAAATGATACAAAAGGTTTATTGTTTTATTTT

TATTATCAAAAATATTTTTTTAAAAAATAAAATCAA

AATCCAGATTGATTAATAAATTAAAACGTCGAATAA

TGTAGCAAATAGTGTTATTGATATCAATCAATCATG

ATTTTGATGAAAATACAATCAAGAATTCTTAAGCAA

AATCTTGATGCGCGTCCACAACATCCGAAAAATAA

ACATTAATTTGGTTTATCAGGATGATTTCCAGAAAT

TTATGGAAAATCGAAAATTTCAAAATCATCCAAAAA

TTCGCGTCAACTTTTATCAATAATCAAACATCAAAA

TTCAATCAATTACCTATGTAGTTGAAATATCAATCT

ATCCAATAATCCAGCAATAATACAATAATCAAATAC

TGAAATTCCAGAAAAAAACATTCATCTTGTCATCTT

GATTGCTGCTACCATATCTTCATTAGATCTTCTTCCC

CAATTGATTATTAAACCAAATGAATTATTTAGGATT

TTTGAAATATTTGAATTGATTGTAAAAATTGAAAGA

AATTCGAGACCGGCAAAGAATTGAAGAAGATGGA

AATTCGAGGCAAAGAATTGAAGAATTGAAGAATTG

AAGAATTGAAGTGAAGTTGTTGAAATTGAATTGTA

CTGTGCGAATTCAAAAGAGAGTTATGATAGAGAAA

GTGTAGATGTTAGATGTCGTATGATGGCAGAAGAA

AGTACGAAACAAAGGAAAACCTTTTCCTTTGATTTT

TGAAGGAAAAGATTTTCAATTGGAATGTAAAATAA

TTTTACACTCAAGTTTTCCATTTTATTTTTTCAATCTT

ACCAAACAATGTAAAATAGGAAAATAGTTTTCAGG

GAAAATGTTTTACGCCCTACCAAACACTACCTTAAT

CTTGGCGGTTGAGAGATTTCATCTCAATAATTAAAA

GTATAAAATCCAAGAAGAAAAGATTACCAAAAAAC

TTGGAGAAAGAAATTGATTAAGAGATGATGAGATA

TGGCAGTACCGCGATTACCGAACAAAGATTGAAAT

GATGATGAGATGATGATGATGATGATGATTGATGA

TGATGATGATGAATTGATGATGAGCTAGCTCGAAA

ACGGATTTGTGCGGGTAATGGCTCAAACGATTCTG

AAGACTACGTTATTCATCCATTTTGGTCGCTAGTGG

GCATGACTTGAGTAAAATGGATTGAAGTGACGGCT

AGATTGGATTTGGGGCTAGCCAAGACATAAGAATC

GTTTGGGTTAATCGTTAACCGTTAAGAGTGGGTCG

AGACTAATATAGGAGCAACTTTTCGTTCGAAACCCA

AAAAAAAAAAAACAAAACAAAGCACATGATGAATA

CTGAATAAAAAAATAATTAATTGGATCCATCTTATA

TGCCTAAGGCGTACCCAAAAGTCATGAAGGTTGGC

TGATCCTATCTACGGAATACACAATGCTTAAACAAT

TAAAATTAACATACTTTGTAGGTGAGGCATGCTTG

GTTTGATCAAATTTAGACATGAGTGACGAATTGAA

TCTTGCCTAATAGGATCAAACTCATGAAGTTATGAT

ATGACATGCACTATGGATTATTTTTTGCATGAGATT

TTTATAAAACTTGATATAATCTACCTAACTAATGTAT

GTCCTGATTGACATTTGAGTTGTCCAATAACGTACC

ACGACATCAATTCAAGAGTTCTTCGAAGAAAATAA

GTAAATAACCCCAATCTCAAGGATAAGGAGATTTG

AAGGCTAAAAAAACTTGATCTACCCATTGAGTAGA

CTACCCACCATTAATTGACAGTGGTAAAAAGTGGT

GACAATAGAATTACACTCAAGTTATGAAACAATAG

ATATGTATATGCGATCCATTAAGTAAATGTAATCAT

GTCCGAGCCGAAGGGATCAAGCCTAGACACCAGTC

AAGCTTGGGTTGGTAAAATGGTGAAGTACTTCGTA

TGTATTGAAGTATTGTAAGTACATGAGTAACCGCA

AAGGCTCTAAAGCTACTACTACTACTACTCCTAATT

GGGTAACCGCAATATGTGTGGACAGTTCGAAAGCC

ACACAATTTGAGTGGCATTTTCCATTTTTCAATTCTC

CTCTCTCTCTCTCTCAGTGGCTCAAACAGAAATCGC

ATTACACCCACATTCCACAAATGGCCCTTTGATAAA

GCACTAAACCTACTCTACTCCTACACTCCTTCATCTA

ATCTCAATTTCCGTTACTTCTTTGGTTCTATTGCACA

CCCTTTTACACCCATTGCAGTTTATATTCCACTGAAT

TTCGTATTGCAAACCCAATTTACAAAAATTGCAGAA

GAAAATGAGTTATTTTGGATATGCTTGTGCTACCCA

ATCCACTTCAAGATGTGTTCTTTTGGGCAATTCTGG

TAACCCCACTTCAGTTTCATCTCGTGGCAGTGATTT

CATGGGTCATTCTGTAAGAAATTTCAGTTTTAGCAA

AAGACAGAGAATTGGGCACTGCCCATTGAAGGTTC

TATTGCTTGCTTTCTTGTTTATGGATCAATTTTATGG

GATTTGATGAAAAGATTAGATTTTGTTTATAGTTGA

ATTAATCGAGAATTTTAATGTATGATGCAGGTTGTT

TGTGTAGATTATCCAAGACCAGAGCTTGAAGGTAC

AGTCAATTACTTGGAAGCTGCTTATTTATCTTCAAC

TTTTCGGAATTCACCTCGTCCTCAAAAGCCGTTAGA

GGTTGTAATTGCCGGTGCAGGTAAGTGGGATGTTT

CCTGTAACTTGCTTTGTTCATTAGTTTCTTGTTCTTTT

GCTTGTTGCTTTATAAACTAGTGATGTTTGGTATGT

GTTTGGTGTAATCATTGTCTTACTGATATGGAAAGG

ATTATGTAGGAGGGAAAAGGGTAGTGATAATTACT

GGGTGTTTGGCTAAGGATGTTCAGCATAGCATGGT

TGTCTCTTACAACCACACTCATGTATTACCATGGTA

AGGGTTGTACTTAGAAAATTGTTGTATTTGGCAATT

GGCAATACAATGGAATTGAACCATATTTCATGAAG

GACCCCCTTTGGAGAGGGTAAGGTGGTTTTAATTG

TATCCATAGGTTTTCAAAGGGTGACAAGTGGAGGG

AAATGGTTACCTTCAGGAAATGAGGTTTGTTCCTAC

ACTTACACCAAATGGTGTGCAATTACACCTTAAAAT

CCATTACCAAACACCCTTAGGTTTCGGTTTATCATCT

GTTAGAGGCCTACCAATGAGAATTTCCCTTACGTTA

ATGAAGTAATGGGTTTTGACACCTTTTTTTTTTATGT

TGCATGTTCGAAATAAGCTTTGTAGTTTGAAGTAGC

TTACGGCTAATAGCTGTTATGCGGGAATATTGTGA

ATTGGAAAAAGAATAAGAGAGTACTTGCTTCAAGG

ATCATAAGGTTTATGATTGTTGGAATCATCTTTAGT

GAAATTTTGATTTTCAACTGATCTCTACGGTAACTA

TTGGTCCTTCAAAATTCTAGACGCAGAATCGTTTAG

GTGAGGGTGAACTCTGATTATGAATAGTCAATGTC

TCTCCCAACGTGAAACTTATTAGTTCTAGCTGTTAT

GTGCTCCAATTCGAGGAACATCGTGAATTGGAGAA

AGAATACTGCTTCAAGGATCATGAGTTTATGATTGT

CGTAAACTTCTCTTAGTTCTTTAGTGAAATTTCAGC

AGATTTTAATGGTAATTAGCAGTCCTTCAAAATCCT

AGATGCGGAATCATCTAGGGCATGTATATGGTAAA

CTCTCATGATAGATAACTAGTGTCTCCTCCATGTAA

ACTTTATTAGGTATTTTCTTTGTCAAAAAGAGTATTT

TTCATTGGAAAAACAATATAATGGTGACTACTGCAT

ATGTTTGGTTAGCTATTCCTGTTGCAAATCAGATTT

TGAATGGAACATGTCTTATTCCCTTCTAGAGCTCTC

CTGGTGCAATTCTAGCATTTTCCCCTCAATAAGTGG

TATTTGAGCTAATATTTCAAGTCTAGACATTATAGC

ATGCTATAATGAGGCGGAATTGTTTGAGCCATGTT

AAAGGGTTCCATGACATGTAATATGCTAGTTTATG

GCAGGGAACAGGGAGTTGGGTCCTTGCCTTCATGG

GAAAAGAGAGATTGTTAGGTATTTCTTAAGTTTGC

ATGGGAAAGAGTTCTTTTATCTTTATAGTGAAAGTT

GACTAGTATGCAAGTATGGTGGTGGATTACCCTTA

TTGCCATTTGGACTTGTATGCTATTTAGTGCATATA

CTTCAGCCTAGCTTAATCTTGACAAAAATGCCTTGA

GTTCTAGTGGTTTGCTTTATTCATTGGTTGATTTGCT

ATTTCTGCTAGTGAAATTAGAGAGAAAATTGATGC

CTGTTTCAGTGTTTCTCATCAAGGTAAATGGACAAA

ACTGTCTATGTCTTGAAATTTTCTGTGAATACTCAA

GCAGGCTTCCTTGGTTTGCTTCAGGCTGATTTTCAT

TGCCTCAGTTTCTGCTTGTTGGTATCAGAATAAAAA

TAGATACTTTTATGTATTTGTGAGAGATTTGTTGGT

AGAACCACATTTATTCTGAGAAATATTTGTACAAAT

GGGAGTTTAAGGTTATAAGTGTGTAAGCCTTTTGA

GGTATTTTGTTTTAAAAATCTTATCGTTATTTCAGAG

CAGCAAGTTACATATAGTAAACTTGGGAGCATTGG

AGATGTGATGGAATTAGATTCAATATATTTTATCAT

CAAGATATGAGTTCTAATTCAAAACTTTCCTTCTAG

GTTTGGCTGGTCTATCCACAGCGAAGTACTTGGCA

GATGCAGGACACAAACCCATATTGCTTGAGGCACG

AGATGTTTTGGGTGGAAAGGTATGTGCTTATATGC

TATTTTTTCAGAAATATATCCTTTGTGCTTCTTCTCTT

CTCAGTTTATGTTGACTATAATAAATGAAACAGCTT

AATTGTCTTGGTTGTATGCTTTCATAGTATTATCTAG

GCTACATGGTTATACGGACATATATTATTGAGTGG

AGTGATTTAGTCATCTTAAGTGGTTATTTACTTTTAT

TTTATAGCTGTTGAAGTTATTCATCATTCTGTACAAT

GTTAAGTCAGTGTTAATGAGGTTTAGAGGGTAATG

GACTAATAGACAAGCTTTGTGCTGTGAACGGTTTG

AGAACATGTGCTATTGGGACTGATGTTATGCAATG

TTTGTGGTAGTCTTCCTTCTTATGCATTTGTTTATTG

TTACTGTTTCACAGGGTTGCAGCGTGGAAAGATGA

GGATGGTGACTGGTATGAAACTGGGCTCCATATAT

TCTGTGAGTATAATATTTTGCTTTTCAGCTTAGATAT

CCTGTTTAAGCTTCTAGTCCTACAATTTATGTTTTCT

GCTGAGTGGATTTTTGTAAAAGTTTTACGGGATCT

GTGCAATTTCTGCCTTCTGATTCTGTTATTATTTGGA

AGGGCGTGATATTGTGACAATTTCAAAGTGGTTTC

ACTCCAGACAAAAGTCAAACTAACAATTCAATGTAC

TGAATACCCTTTTATTTTCTTGAAGTTGGGGCTTATC

CAAATGTGCAGAACTTGTTTGGAGAACTTGGTATC

AATGACCGATTGCAATGGAAGGAACATTCTATGAT

TTTTGCAAGGCCTGACAAACCGGGTGAATTTAGCC

GCTTTGATTTTCCTGAAGCCCTGCCTGCACCTTTAA

ATGGTGAGTATTTGACACCTTATATTCTTTAGCAAA

CTAAGTATTGTATAAGCCAAACTGCACCTGGTGAC

ATTCATTGATTTCTTTCTTGCTCACCGACTTTCCTTG

AGATTCTAGCAACATCTTATTCTCCGTCTTCTAATGA

GTAAACTAGTTTTGATTCTGTTCATTCTTAATGTGTT

TGGCAGGCATATGGGCAATCTTAAGGAATAATGAA

ATGCTAACATGGCCAGAGAAAATCAAGTTTGCTAT

TGGTCTCTTACCTGCTATGGCTGGTGGACAGTCCTA

TGTCGAGGCACAAGATGGTTTAAGTGTTCAAGAGT

GGATGAAAAAACAAGTAGGAACAAACGATCATTTT

TAAAACCTTATTTTTCAAATTCCTTGATGATTGTCTA

GATTGTTAGTTCATTACATGTCTAACTTTAAACATT

GATGTTACAGGGACATCTATTTTATTTATTTTTGAA

AATTCCTTTTGCAAATTTTGTAGGGTGTGCCTGATC

GTGTTACAGATGAAGTATTCATTGCCATGTCAAAG

GCACTTAACTTCATAAATCCGGATGAACTTTCGATG

CAGTGTATCTTGATTGCTCTGAATCGATTTCTTCAG

GTATAGCCCCATTTCACTATCTGCTTTAAGTGTGTTT

TATTTTCAATTGAATTCGACCTGCTCAACTATATGG

AACTTAAGTAATTTTGATTTGAACTTATTGATACAA

ACGTATCAAAACTTACGATAATCTTTTTCAGTTTGA

TACACTATCGTTTTGTTTCTGAGAACTTTTTGTAAAT

TGGATTATATGTGATGTTAAAATTATGGAATTCACT

CAACAGGAAAAGCATGGTTCAAAAATGGCTTTCTT

GGATGGAAATCCTCCAGAAAGGTTATGCATGCCTA

TTGTTGAGCATATTGAGTCACTAGGTGGTGAAGTG

CAGCTTAACTCTCGTATTCAAAAGATAAAGTTAACT

CAAGATGGAAGTGTGGATAGCTTCTTGCTAACCAA

TGGGAAAGAAGTTAGAGGGGATGCTTACGTCTTTG

CTACTCCAGGTTTACTTTTCTTCTTTACCGAATGGGA

TTATTATTCAACTAGGAAATTATTGCCATTTTTAGTC

AAGACAGGCTCCTGAAGAAATTATTTATTGCCATCT

GTATTGTTCTCTGATATACCTTTAAATTTTTATTACA

GTTGACATCCTAAAGCTACTTCTTCCTGAAGAGTGG

AAAGAAATTTCATACTTCAAAAAGTTGGAGAAACT

AGTAGGAGTTCCTGTCATTAATGTTCACATATGGTT

AGTGATACCTCTTGTCTACAGGAATATAGTTTCTTA

ATGCTATAACCCAATCTTATGTGTCTTCTCTTACTCT

ATGTAATTTTATTTATGTATCTATCTTTCTCTTTCCAT

GTCCATGTATTTTGTTATTTCTGTCTTTGGCTTTTTA

GAATGGTTTGTCAGTATATCTTTGCAATTAGGCTCT

GATTTAATAGCCTACTACTATACGAAGTATATCATT

TCTTTGGTAGTATATTTTCTGTAGTTTGCGTTGAGA

GTTTGAGACTCCTATACGTAGAGCTTCATCTTAATA

AAATTTTATGTCTTGTAAAATCTGTCTGTTTTGAAAT

GTCAAAAAAGCTGTCAAAAGCTATTTCTCACCCTCT

CCTTATGAAGAACTTCAATGAAATCTCCTCTAATAT

TGGGACTGACATTTAACAACTGTTGGCTTGCAGGT

TTGATAGGAAATTGAAGAATACATATGACCACCTA

CTCTTCAGCAGGTGTGTTCAATTAAAGTGCTAAATT

CAATATCATTTTCATAGCACTCAAACAATACTCAAA

GATTATCCTTCCCTTTTTGTCCTTGTTTTATACTCATT

TCGTTTTCCCTTTTTTTGTTGGAAAGCACATTTTGTT

GAGCATATGCCATGAGCTGCATACTTGCATAAAAT

TGGGCAAAGGAGCCACAGTCATTTGATATGAAGTA

TGATTTAAGAATCCTCCTATGAAGTTAGAAAAGTTA

TGGTACTAGTTTTCTTTTACTGAGTGAACGGGGTAT

CCCTGCCAGCAATGTGTACAAGGATACTGGCTTGC

TGCAGAAAGATACTTTCAGTATTGATAAGATACAA

ATTGCATTTTTCTTTTGGATGAAATACAGTGAACTG

GCAATGGTGTCAGCTTGAACGTTGAGAATCCTTGA

TATCCATTTGATTCATGTTTTCACTTGTGCGTGGATT

TCACTCCTATAAGTTTGTCATTGCAGGAGTCCTCTTT

TGAGTGTCTATGCTGATATGTCAGAGACATGCAAG

GTAATTTCTCCTCAATTTTGTTCTTCATCATGTAATA

CATGCTGTCTCATTCGCAAACGTCTACTATGTGCTA

TTCAATCGAAGGCATATGTAATGTTATTTAATCAAA

AGCATATACTGTATATAAGTGCTTTGTCACTTCCAA

AACTATGTCTGTTTTTTAATCCCCTATCGATTTTTTT

ATTTGTTATTTATTTCTTAATTGTTTTGTTAGCTTGTT

ATATGTTTGTCTTTGAGACTTTTTGGTTGTTATCATT

GAACATCTTTATGACTTACTCCTTTCGGAATCAAGT

TACACATACAATGAAAGTGTGTATGATTAAATTTGT

CAATAGGCTATTATTTGTTTGAGTGATGAGGAGAT

GATAACTTTATTCCTACTATAAAGAAAAGGTCTACT

TTAAAACCTCGTCTTGTCATTAATTATGAGGGTTGG

ATGTTGGGATTGAGATAAATCAACTGATACCAGAA

CCCAGAAGGGGAAAATGCAGAAATACTACCTCATG

AGCTGTGGCTGACCTTTCTGTTCCCATGATCTTGTC

TTATTCTATGAGTATGAACTAAAGTAGTAGAGTGTT

CCCAATCTTTTGGAGCGTACAGGAATATTATGATCC

AAACCGGTCCATGCTGGAATTGGTTTTTGCACCTGC

AGAAGAATGGGTTTCTCGGAGTGACACGGACATTA

TTGAGGCAACAATGAACGAACTTGCCAAGCTTTTTC

CTGATGAAATCGCAGCTGATGGGAGCAAGGCTAA

GATCCTAAAATATCATGTAGTCAAAACTCCCAGGTG

AGATAATATGTACTATACTGCTCTGTATTAGTTAGA

TTTGGTAATCGTTTGTGGTATTAAGCAGACCTTATC

TGCTGAAAAGCAGTATCGATATTTACTACTGTTAAG

GTCTCTAACTGTTAATTCTTCCATTCCTTCACAGGTC

TGTTTATAAGACAGTTCCAAACTGTGAACCTTGTCG

ACCATTGCAAAGGTCACCAATAGAAGGTTTCTATTT

ATCCGGTGATTACACAAAGCAAAAATATTTGGCTTC

AATGGAAGGTGCTGTCCTGTCTGGGAAGTTTTGTG

CACAGGCTATTGTACAGGTAATGAGGTTTTGCTCA

AACATCATAAGCATGATATTCATGAGTTTCACTTCC

TATATCTCCTAGAATCCTCATGATATTGTTACTCTAT

AAATTATGTTTACTGAAAATTTAGTCCTATTATTCAT

TTGCAGGATTATGATATGCTTGTTGCTCGAGCACAA

AGAGAATTGGCAGGGGCAGGCAACGCCTGATTTG

AAATTCTTTGATATTTGCCCATTTTTTTCGTCGGAGA

TTTGGATTGGTGATCTTGTTCAGATCGAGTTCAGAT

CGATATTCAACTACTGGAAACAAACTCTGGGAAGC

ATTCTCAGTTATACTCAATTTTTTTTTCTGCTGTTCA

AGATGTATATGTGTAGCTTAATTGTAGGGAAACAT

GTACAGGCATGTACTCATAAGTGGTTTCAAATGTA

AGTAGTAATTCAATACATGTACTAACATTTCTGTGG

AAATAGGAAACTGTTTTAGAAGAGTGTCCCCTTTCT

ACTTCGTAAATGACATTTAGATTGTGGCTTTGTTGC

TGGGAGCATGGTCCGGCTTGGTTAGGAAGCACGA

GGCCATTGCCCGAATGCCGCCAATGTGGATTGATG

GATCTTCTCTTAGCTTCTTAAGGGGTTAGTCTTTTTC

CATGATACTTCCTCAGTTATTGAAAGAATGTAAACC

TTTTTTTTTTTTTTCATTTTGTCGTGAAACTTCGCAAT

TTTCAATCTTATACGTGTATGAAACTTCGATATTACT

TCTCCATATTTTTAATCACAACACGTATGGATTGCC

GGATTGGCAATAAAGTTGATGATAGAGAAAATATG

TGGGGGCATATGAAATTCTTGTGAGAGTAAAGTGG

TGGTCTTGTATACCATTTTAAAAACGTCGTAAACAT

TTTGAATCAACTCAAAAATATAAAAAGTGTCCCCTT

TATACTTCATTCATTTGCATTTGGACATCCCTTTCAA

ATATTGCTAAGCTTAGCTTAGCGATTAGGGTTGAA

CCTTTTAACCTTGAGGATGCAGGTTAAATTTTTACT

AAAGCATTTCGGGGTTTTTCTATTATTACTCTTTCCC

CCCTACTTTTAAAGCGTCTAGTCATCAAACTTACAG

CGGATCGATGTTTGAATACGATAACGTTATCCTACA

AAAAAGAAGAAAGGGTACCTCAACCCCAATTCCCC

AAGACCTACTCCCAAAGTCCAAAACAACATGAGTG

GATTTGCAAGTTGCAAATAGGCATTAGGCATATAT

TATTTGGGCAAAATAGTAGTAATTGGAGTTGCGTT

GTGCATTCTTTGAAGATTAACTACTTGAGTGTGCGT

GCAGTCGGTGCCGTCAGTAACAAACTACATACACA

TCACATCTCGAGGGATGAACCCCCCATTAAGCTACT

CTACAAGAACCATGAACCTCCATGGGGACACCCAC

ACTATGCTACTAAGCAAAATCCTTAACATCCTCGAC

TAGATATATACTTCTTCCGTTTCTTTTTACTGTAAAT

GCAACAAAAGTATCTTTTTGTTTTCACAAATGTCGA

TTTGGCTTGTAAAGCTTGTGAATTGGCTCGATTTTT

ATTTTTCTTTCGCAATTTCATAAAACTCGTTACACTT

TTCATTCTAAGATGGTCTCACATTACTTGTTATACTT

TTTTTTTTTTGTAATAAACTATTTATTATATATCTCTT

CTCACATGAGTCCTCCTTGCTTTTTTATTCTCTATCTC

CTCCCTCTCCAAAAATCAGTGAATTGAGAAATGTAG

CGAGTAATATGAAACGGAAGAAGTACTTTGGAAAA

CATTTGTACTATCAATACATACATGAAAACAATGAT

CCTATCTATTACATATATGACAAGATTAAGAAATTC

ACTGTCTATTAAAACCAACAAATTGAATATTAATTG

AAGAAGAAAAGAAAAACATAAAAACTGAAGGTAA

TAATGTACTGTATAAAACTTGTTCATGAATAGTTTG

AAAAAAG

68

Kochia scoparia

Genomic
10701
AATGCTTAAACAATTAAAATTAACATAATTTGTAGG

TGAGGCATGCTAGGTTTGATCAAATTTAGACATGA

GTGACGAATTGAGTCTTGCCTAATAGGATCAAACT

CATGATATGACATGCACTATGGATTATTTTGCATGA

GATTTTTATAAAACTTGATATAATCTACCTAACTAAT

GTATGTCCTGATTGACATTTGAGTTGTCCAACAACG

TGCCACGACATCAATTCAAGAGTTCTTCGAAGAAA

ATAAGTAAATAACCCCAATCTCAAGGATAAGGAGA

TTTGAAGGGTAAAAAAACTTGATCTACCCATTGAG

TAGACTACCCACCATTAATTGACAGGGTAGAAAGT

GGAAAATTCCTAGTCAATCCAATGGATTGATAATCC

AATGGCATTTTGGTAAATAAATGGAAAAAAAGAAA

AAAATAAATGGCAATGTTGTAAATAAAATATTTCAT

TTATTTACTAAAATACCATTGAATTGACAATTTTTGT

CAATCCATTGGATGGACTAGGCATCCCTCGTAGAA

AGTGGTGACAATAGAATTTCACTCAAGTTATAAAC

AATAGATATGTGTATGCGATCCATTAGGTAAATGT

AATCATGTCCGAGCCGAAGGGATCAAGCCTAGACA

CTAGTCAAGCTTGGGTTGGTAAAATGGTAAACACT

TCGTATGTATTGAAGTATTGTAAGTACATGAATAAC

CGTAAAGGCTCTAAAGCTACTACTACTACTAATTGG

GTAACCGCAATATGTGTGGACAGTTCGAAAGCCAC

ACAATTTGAGTGGCATTTTCCATTTTTCAATTCTCTC

TCTCTCTCAGTGGCTCAAACAGAAATCGCATTACAC

CCACATTCCACAAATGGCCCTTTGATAAAGCACTAA

ACCTACTCTACTCCTACACTCCTTCATCTAATCTCAA

TTTCCGTTACTTCTTTGGTTCTATTGCACACCCTTTT

ACACCCATTGCAGTTTATATTCCACTGAATTTCGTAT

TGCAAACCCAATTTACAAAAATTGCAGAAGAAAAT

GAGTCATTTTGGATATGCTTGTGCTACCCAATCCAC

TTCAAGATGTGTTCTTTTGGGCAATTCTGGTAACCC

CACTTCAGTTTCATCTCGTGGCAGTGATTTCATGGG

TCATTCTGTAAGAAATTTCAGTTTTAGCAAAAGACA

GAGAATTGGGCACTGCCCATTGAAGGTTCTATTGC

TTGCTTTCTTGTTTATGGATCAATTTTGTGGGATTTG

ATGAAAAGATTAGATTTTGTTTATAGTTGAATTAAT

CGAGAATTTTAATGTATGATGCAGGTTGTTTGTGTA

GATTATCCAAGACCAGAGCTTGAAGGTACAGTCAA

TTACTTGGAAGCTGCTTATTTATCTTCAACTTTTCGG

AATTCACCTCGTCCTCAAAAGCCGTTAGAGGTTGTA

ATTGCCGGTGCAGGTAAGTGGGATGTTTCCTGTAA

CTTGCTTTGTTCATTAGTTTCTTGTTCTTTTGCTTGTT

GCTTTATAAACTAGTGATGTTTGGTATGTGTTTGGT

GTAATCATTGTCTTACTGATATGGAAAGGATTATGT

AGGAGGGAAAAGGGTAGTGATAATTACTGGGTGT

TTGGCTAAGGATGTTCAGCATAGCATGGTTGTCTCT

TACAACCACACTCATGTATTACCATGGTAAGGGTTG

TACTTAGAAAATTGTTGTATTTGGCAATTGGCAATA

CAATGGAATTGAACCATATTTCATGAAGGACCCCCT

TTGGAGAGGGTAAGGTGGTTTTAATTGTATCCATA

GGTTTTCAAAGGGTGACAAGTGGAGGGAAATGGT

TACCTTCAGGAAATGAGGTTTGTTCCTACACTTACA

CCAAATGGTGTGCAATTACACCTTAAAATCCATTAC

CAAACACCCTTAGGTTTCGGTTTATCATCTGTTAGA

GGCCTACCAATGAGAATTTCCCTTACGTTAATGAAG

TAATGGGTTTTGACACCTTTTTTTTTTATGTTGCATG

TTCGAAATAAGCTTTGTAGTTTGAAGTAGCTTACGG

CTAATAGCTGTTATGCGGGAATATTGTGAATTGGA

AAAAGAATAAGAGAGTACTTGCTTCAAGGATCATA

AGGTTTATGATTGTTGGAATCATCTTTAGTGAAATT

TTGATTTTCAACTGATCTCTACGGTAACTATTGGTC

CTTCAAAATTCTAGACGCAGAATCGTTTAGGTGAG

GGTGAACTCTGATTATGAATAGTCAATGTCTCTCCC

AACGTGAAACTTATTAGTTCTAGCTGTTATGTGCTC

CAATTCGAGGAACATCGTGAATTGGAGAAAGAATA

CTGCTTCAAGGATCATGAGTTTATGATTGTCGTAAA

CTTCTCTTAGTTCTTTAGTGAAATTTCAGCAGATTTT

AATGGTAATTAGCAGTCCTTCAAAATCCTAGATGC

GGAATCATCTAGGGCATGTATATGGTAAACTCTCA

TGATAGATAACTAGTGTCTCCTCCATGTAAACTTTA

TTAGGTATTTTCTTTGTCAAAAAGAGTATTTTTCATT

GGAAAAACAATATAATGGTGACTACTGCATATGTT

TGGTTAGCTATTCCTGTTGCAAATCAGATTTTGAAT

GGAACATGTCTTATTCCCTTCTAGAGCTCTCCTGGT

GCAATTCTAGCATTTTCCCCTCAATAAGTGGTATTT

GAGCTAATATTTCAAGTCTAGACATTATAGCATGCT

ATAATGAGGCGGAATTGTTTGAGCCATGTTAAAGG

GTTCCATGACATGTAATATGCTAGTTTATGGCAGG

GAACAGGGAGTTGGGTCCTTGCCTTCATGGGAAAA

GAGAGATTGTTAGGTATTTCTTAAGTTTGCATGGG

AAAGAGTTCTTTTATCTTTATAGTGAAAGTTGACTA

GTATGCAAGTATGGTGGTGGATTACCCTTATTGCC

ATTTGGACTTGTATGCTATTTAGTGCATATACTTCA

GCCTAGCTTAATCTTGACAAAAATGCCTTGAGTTCT

AGTGGTTTGCTTTATTCATTGGTTGATTTGCTATTTC

TGCTAGTGAAATTAGAGAGAAAATTGATGCCTGTT

TCAGTGTTTCTCATCAAGGTAAATGGACAAAACTGT

CTATGTCTTGAAATTTTCTGTGAATACTCAAGCAGG

CTTCCTTGGTTTGCTTCAGGCTGATTTTCATTGCCTC

AGTTTCTGCTTGTTGGTATCAGAATAAAAATAGATA

CTTTTATGTATTTGTGAGAGATTTGTTGGTAGAACC

ACATTTATTCTGAGAAATATTTGTACAAATGGGAGT

TTAAGGTTATAAGTGTGTAAGCCTTTTGAGGTATTT

TGTTTTAAAAATCTTATCGTTATTTCAGAGCAGCAA

GTTACATATAGTAAACTTGGGAGCATTGGAGATGT

GATGGAATTAGATTCAATATATTTTATCATCAAGAT

ATGAGTTCTAATTCAAAACTTTCCTTCTAGGTTTGG

CTGGTCTATCCACAGCGAAGTACTTGGCAGATGCA

GGACACAAACCCATATTGCTTGAGGCACGAGATGT

TTTGGGTGGAAAGGTATGTGCTTATATGCTATTTTT

TCAGAAATATATCCTTTGTGCTTCTTCTCTTCTCAGT

TTATGTTGACTATAATAAATGAAACAGCTTAATTGT

CTTGGTTGTATGCTTTCATAGTATTATCTAGGCTAC

ATGGTTATACGGACATATATTATTGAGTGGAGTGA

TTTAGTCATCTTAAGTGGTTATTTACTTTTATTTTAT

AGCTGTTGAAGTTATTCATCATTCTGTACAATGTTA

AGTCAGTGTTAATGAGGTTTAGAGGGTAATGGACT

AATAGACAAGCTTTGTGCTGTGAACGGTTTGAGAA

CATGTGCTATTGGGACTGATGTTATGCAATGTTTGT

GGTAGTCTTCCTTCTTATGCATTTGTTTATTGTTACT

GTTTCACAGGTTGCAGCGTGGAAAGATGAGGATG

GTGACTGGTATGAAACTGGGCTCCATATATTCTGT

GAGTATAATATTTTGCTTTTCAGCTTAGATATCCTGT

TTAAGCTTCTAGTCCTACAATTTATGTTTTCTGCTGA

GTGGATTTTTGTAAAAGTTTTACGGGATCTGTGCAA

TTTCTGCCTTCTGATTCTGTTATTATTTGGAAGGGC

GTGATATTGTGACAATTTCAAAGTGGTTTCACTCCA

GACAAAAGTCAAACTAACAATTCAATGTACTGAAT

ACCCTTTTATTTTCTTGAAGTTGGGGCTTATCCAAAT

GTGCAGAACTTGTTTGGAGAACTTGGTATCAATGA

CCGATTGCAATGGAAGGAACATTCTATGATTTTTGC

AAGGCCTGACAAACCGGGTGAATTTAGCCGCTTTG

ATTTTCCTGAAGCCCTGCCTGCACCTTTAAATGGTG

AGTATTTGACACCTTATATTCTTTAGCAAACTAAGT

ATTGTATAAGCCAAACTGCACCTGGTGACATTCATT

GATTTCTTTCTTGCTCACCGACTTTCCTTGAGATTCT

AGCAACATCTTATTCTCCGTCTTCTAATGAGTAAAC

TAGTTTTGATTCTGTTCATTCTTAATGTGTTTGGCAG

GCATATGGGCAATCTTAAGGAATAATGAAATGCTA

ACATGGCCAGAGAAAATCAAGTTTGCTATTGGTCT

CTTACCTGCTATGGCTGGTGGACAGTCCTATGTCGA

GGCACAAGATGGTTTAAGTGTTCAAGAGTGGATGA

AAAAACAAGTAGGAACAAACGATCATTTTTAAAAC

CTTATTTTTCAAATTCCTTGATGATTGTCTAGATTGT

TAGTTCATTACATGTCTAACTTTAAACATTGATGTTA

CAGGGACATCTATTTTATTTATTTTTGAAAATTCCTT

TTGCAAATTTTGTAGGGTGTGCCTGATCGTGTTACA

GATGAAGTATTCATTGCCATGTCAAAGGCACTTAA

CTTCATAAATCCGGATGAACTTTCGATGCAGTGTAT

CTTGATTGCTCTGAATCGATTTCTTCAGGTATAGCC

CCATTTCACTATCTGCTTTAAGTGTGTTTTATTTTCA

ATTGAATTCGACCTATTCAACTATATGGAACTTAAG

TAATTTTGATTTGAACTTATTGATACAAACGTATCA

AAACTTACGATAATCTTTTTCAGTTTGATACACTATC

GTTTTGTTTCTGAGAACTTTTTGTAAATTGGATTATA

TGTGATGTTAAAATTATGGAATTCACTCAACAGGA

AAAGCATGGTTCAAAAATGGCTTTCTTGGATGGAA

ATCCTCCAGAAAGGTTATGCATGCCTATTGTTGAGC

ATATTGAGTCACTAGGTGGTGAAGTGCAGCTTAAC

TCTCGTATTCAAAAGATAAAGTTAACTCAAGATGG

AAGTGTGGATAGCTTCTTGCTAACCAATGGGAAAG

AAGTTAGAGGGGATGCTTACGTCTTTGCTACTCCA

GGTTTACTTTTCTTCTTTACCGAATGGGATTATTATT

CAACTAGGAAATTATTGCCATTTTTAGTCAAGACAG

GCTCCTGAAGAAATTATTTATTGCCATCTGTATTGT

TCTCTGATATACCTTTAAATTTTTATTACAGTTGACA

TCCTAAAGCTACTTCTTCCTGAAGAGTGGAAAGAA

ATTTCATACTTCAAAAAGTTGGAGAAACTAGTAGG

AGTTCCTGTCATTAATGTTCACATATGGTTAGTGAT

ACCTCTTGTCTACAGGAATATAGTTTCTTAATGCTA

TAACCCAATCTTATGTGTCTTCTCTTACTCTATGTAA

TTTTATTTATGTATCTATCTTTCTCTTCCATGTCCATG

TATTTTGTTATTTCTGTCTTTGGCTTTTTAGAATGGT

TTGTCAGTATATCTTTGCAATTAGGCTCTGATTTAAT

AGCCTGCTACTATACGAAGTATATCATTTCTTTGGT

AGTGTATTTTCTGTAGTTTGCGTTGAGAGTTTGAGA

CTCCTATACGTAGAGCTTCATCTTAATAAAATTTTAT

GTCTTGTAAAATCTGTCTGTTTTGAAATGTCAAAAA

AGCTGTCAAAATCTATTTCTCACCCTCTCCTTATGAA

GAACTTCAATGAAATCTCCTCTAATATCGGGACTGA

CATTTAACAACTGTTGGCTTGCAGGTTTGATAGGA

AATTGAAGAATACATATGACCACCTACTCTTCAGCA

GGTGTGTTCAATTAAAGTGCTAAATTCAATATCATT

TTCATAGCACTCAAACAATACTCAAAGATTATCCTT

CCCTTTTTGTCCTTGTTTTATACTCATTTCGTTTTCCC

TTTTTTTGTTGGAAAGCACATTTTGTTGAGCATATG

CCATGAGCTGCATACTTGCATAAAATTGGGCAAAG

GAGCCACAGTCATTTGATATATATGATTTAAGAATC

CTCCTATGAAGTTAGAAAAGTTATGGTACTAGTTTT

CTTTTACTGAGTGAACGGGGTATCCCTGCCAGCAA

TGTGTACAAGGATACTGGCTTGCTGCAGAAAGATA

CTTTCAGTATTGATAAGATACAAATTGCATTTTTCTT

TTGGATGAAATACAGTGAACTGGCAATGGTGTCAG

CTTGAACGTTGAGAATCCTTGATATCCATTTGATTC

ATGTTTTCACTTGTGCGCGGATTTCACTCCTATAAG

TTTGTCATTGCAGGAGTCCTCTTTTGAGTGTCTATG

CTGATATGTCAGAGACATGCAAGGTAATTTCTCCTC

AATTTTGTTCTTCATCATGTAATACATGCTGTCTCAT

TCGCAAACGTCTACTATGTGCTATTCAATCGAAGGC

ATATGTAATGTTATTTAATCAAAAGCATATACTGTA

TATAAGTGCTTTGTCACTTCCAAAACTATGTCTGTTT

TTTAATCCCCTATCGATTTTTTTATTTGTTATTTATTT

CTTAATTGTTTTGTTAGCTTGTTATATGTTTGTCTTT

GAGACTTTTTGGTTGTTATCATTGAACATCTTTATG

ACTTACTCCTTTCGGAATCAAGTTACACATACAATG

AAAGTGTGTATGATTAAATTTGTCAATAGGCTATTA

TTTGTTTGAGTGATGAGGAGATGATAACTTTATTCC

TACTATAAAGAAAAGGTCTACTTTAAAACCTCGTCT

TGTCATTAATTATGAGGGTTGGATGTTGGGATTGA

GATAAATCAACTGATACCAGAACCCAGAAGGGGA

AAATGCAGAAATACTACCTCATGAGCTGTGGCTGA

CCTTTCTGTTCCCATGATCTTGTCTTATTCTATGAGT

ATGAACTAAAGTAGTAGAGTGTTCCCAATCTTTTGG

AGCGTACAGGAATATTATGATCCAAACCGGTCCAT

GCTGGAATTGGTTTTTGCACCTGCAGAAGAATGGG

TTTCTCGGAGTGACACGGACATTATTGAGGCAACA

ATGAACGAACTTGCCAAGCTTTTTCCTGATGAAATC

GCAGCTGATGGGAGCAAGGCTAAGATCCTAAAATA

TCATGTAGTCAAAACTCCCAGGTGAGATAATATGT

ACTATACTGCTCTGTATTAGTTAGATTTGGTAATCG

TTTGTGGTATTAAGCAGACCTTATCTGCTGAAAAGC

AGTATCGATATTTACTACTGTTAAGGTCTCTAACTG

TTAATTCTTCCATTCCTTCACAGGTCTGTTTATAAGA

CAGTTCCAAACTGTGAACCTTGTCGACCATTGCAAA

GGTCACCAATAGAAGGTTTCTATTTATCCGGTGATT

ACACAAAGCAAAAATATTTGGCTTCAATGGAAGGT

GCTGTCCTGTCTGGGAAGTTTTGTGCACAGGCTATT

GTACAGGTAATGAGGTTTTGCTCAAACATCATAAG

CATGATATTCATGAGTTTCACTTCCTATATCTCCTAG

CATACTCATGATATTGTTACTCTATAAATTATGTTTA

CTGAAAATTTAATCCTATTATTCATTTGCAGGATTAT

GATATGCTTGTTGCTCGAGCACAAAGAGAATTGGC

AGGGGCAGGCAACGCCTGATTTGAAATTCTTTGAT

ATTTGCCCATTTTTTTCGTCGGAGATTTGGATTGGT

GATCTTGTTCAGATCGAGTTCAGATCGATATTCAAC

TACTGGAAACAAACTCTGGGAAGCATTCTCAGTTA

TACTCAATTTTTTTTCTGCTGTTCAAGATGTATATGT

GTAGCTTAATTGTAGGGAAACATGTACAGGCATGT

ACTCGTAAGTGGTTTCAAATGTAAGTAGTAATTCAA

TACATGTACTAACATTTCTGTGGAAATAGGAAACT

GTTTTAGAAGAGTGTCCCCTTTATACTTCGTAAATG

ACATTTAGATTGTGGCTTTGTTGCTGGGAGCATGG

TCCGGCTTGGTTAGGAAGCACGAGGCCATTGCCCG

AATGCCGCCAATGTGGATTGATGGATCTTCTCTTAG

CTTCTTAAGGGGTTAGTCTTTTTCCATGATACTTCCT

CAGTTATTGAAAGAATGTAAACCTTTTTTTTTTTTTT

CATTTTGTCGTGAAACTTCGCAATTTTCAATCTTATA

CGTGTATGAAACTTCGATATTACTTCTCCATATTTTT

AATCACAACACGTATGGATTGCCGGATTGGCAATA

AAGTTGATGATAGAGAAAATATGTGGGGGCATAT

GAAATTCTTGTGAGAGTAAAGTGGTGGTCTTGTAT

ACCATTTTAAAAACGTCGTAAACATTTTGAATCAAC

TCAAAAATATAAAAAGTGTCCCCTTTATACTTCATTC

ATTTGCATTTGGACATCCCTTTCAAATATTGCTAAG

CTTAGCTTAGCGATTAGGGTTGAACCTTTTAACCTT

GAGGATGCAGGTTAAATTTTTACTAAAGCATTTCG

GGGTTTTTCTATTATTACTCTTTCCCCCCTACTTTTAA

AGCGTCTAGTCATCAAACTTACAGCGGATCGATGT

TTGAATACGATAACGTTATCCTACAAAAAAGAAGA

AAGGGTACCTCAACCCCAATTCCCCAAGACCTACTC

CCAAAGTCCAAAACAACATGAGTGGATTTGCAAGT

TGCAAATAGGCATTAGGCATATATTATTTGGGCAA

AATAGTAGTAATTGGAGTTGCGTTGTGCATTCTTTG

AAGATTAACTACTTGAGTGTGCGTGCAGTCGGTGC

CGTCAGTAACAAACTACATACACATCACATCTCGAG

GGATGAACCCCCCATTAAGCTACTCTACAAGAACC

ATGAACCTCCATGGGGACACCCACACTATGCTACTA

AGCAAAATCCTTAACATCCTCGACTAGATATATACT

TCTTCCGTTTCTTTTTACTGTAAATGCAACAAAAGTA

TCTTTCTGTTTTCACAAATGTCGATTTGGCTTGTAAA

GCTTGTGAATTGGCTCGATTTTTATTTTTCTTTTGCA

GTTTCATAAAATTCGTTACACTTTTCATTCTAAGATG

ATCTCACATTACTTGCTATACTTTTTTTTGTACTAAA

CTATTTATTATATATCTCTTCTCACATGAGTCCTCCT

TGCTTTTTTATTCTCTATCTCTTCCCTCTCCAAAAATC

AGTGAATTGAGAAATGTAGCGAGTAATATGAAATG

GAAGAAGTACTTTGGAAAACATTTGTACTATCAATA

CATACATGAAAACAATGATCCTATCTATTATATATA

TGACAAGATTAAGAAATTTACTGTCTATTAAAACCA

ACAAATTGAATATTAATTGAAGAAGAAAAGGAAAA

CATAAAAACTGAAGGTAACAATGTACTGTATAAAA

CTTGTTCATGAATAGTTTGAAAAAAGGTTCGAACA

ACAATTGGTCAAAACTTAAATTAACAAACTCAAAGT

CGAGATTAAGCTCGAGTAAACTTAAACAAACACTA

ACCGAGCTTATTTTTTTAGTTTTTTTAATAAAATCAC

AAAACATTAGAAAAAAAAATCTAGAATACACCAAG

TGTAACAAAGAAATGTTGTCCTTTTACTCGAATAAG

ATTCACAAGCCTTATACAAATCCTTAATTAGCATTA

CATTATTTACATGATACATTGCATTGGGGCACAATT

ATATAACCAAGGATCATGATAACCCACCATTATTTT

TTCAATTAGATAAGTTGATACCATTGCTTAAAATCT

TAACAAAAAATCTATATATCAACCTTAATAAAATTT

AAAATATAAGGTTTACAATATTATTTAATAAAATTG

ATATCAACATTCTTAGCTTTTTGGTGCATGTTGTAA

CTTAGAAAATGGTTTGATTTTATTTTCATGCACCAC

AAATGAGGCTAATCATCTCACTTCAACTCACACATA

CAAGAGCTGTTATGAACTCCTATTCTGAAGCCCAAT

TTACTGAACCTTGAGATTGAGATTAAATTTGTCCTT

TTATTTGAACCTTAAAGTGTAATTAAAGTTTAAAGT

TTTTGTTCTAATAATAATATTCCTTAAACAGATATTT

TTTTTTTATATGATTGTTCTCTTTAAGATGCATGTTT

AGAAGCAATAATTCTCACATATTTAAGAAAGTGCTA

ATTTGAGGTAATTGTGTTGGATGATTGGGTGCGAA

TGAGCCGCAATGCTGAATAACGGACTTTTATTAATA

TTAACCATTAAACCAAGACTTCATAATAACCCCCTA

TGAAATGTCCCTTATACCCTTAATGAATTAAATTAC

AATATTTAAAAAAAATTAATAATATATTTTTACTCTT

CAATTGTCAATTTGCCATAAATGTTGAATAAGTTTA

ATA

69

Lolium

cDNA
1685
GCGCTTATCGTTGATTAAACCAGGGCTGACAAGAA

multiflorum

TCTACCAGCAGCTGCTTCATTATGGATACAGGCTGC

TTATCATCTATGAACATAACTGGAGCTGCGCAAGT

GCGGTCCTTTGTGGGACAACTTCATACACAGAGGT

GCTTCACAAGCAGCAGTGTCCAGCCGCTGAAAAGT

AGTTCTCCAACGAGCGCTGGTTTGGCGTCTCTTGGC

TCAAGGAATAGAGGGAAAAAATCACGCCGTGGGC

TTGCTGCTCTGCAGGTTGTTTCCCAGGATTTACCAA

GACCTCCACTGGAAAACACAATTAACTATCTGGAA

GCTGGGCAGCTTTCTTCATCTTTTAGAAGCAGTGAA

CGACCCAGTAAACCATTACAGGTCGTGATTGCTGG

TGCAGGATTGGCTGGACTATCAACTGCAAAATATC

TAGCAGATGCTGGCCATAAACCCATATTGCTAGAG

GCAAGAGATGTTTTGGGTGGAAAGTTAGCTGCTTG

GAAGGATGAAGATGGTGATTGGTATGAGACTGGT

CTTCATATTTTCTTTGGAGCTTATCCCAACGTACAG

AATTTGTTTGGTGAGCTTGGTATTAATGATCGCTTG

CAATGGAAGGAACACTCTATGATATTTGCCATGCC

AAACAAGCCAGGAGAATACAGCCGTTTTGATTTCC

CAGAGGTTTTGCCAGCGCCTTTAAACGGAATATGG

GCCATACTGAAGAACAATGAAATGCTTACTTGGCC

GGAGAAGGTGAAGTTTGCTATTGGACTTCTTCCAG

CAATGCTTGGTGGCCAAGCTTATGTTGAAGCTCAA

GATGGCTTAACTGTTTCAGAGTGGATGGAAAAGCA

GGGTGTTCCTGATCGAGTCAACGATGAGGTTTTTA

TTGCAATGTCCAAGGCACTCAATTTCATAAACCCTG

ATGAGTTATCCATGCAGTGCATTCTTATTGCTCTAA

ACCGATTTCTCCAGGAGAAGCATGGCTCAAAAATG

GCATTCTTGGATGGTAATCCACCTGAAAGGCTATG

TATGCCTATTGTCAACCACATTCAGTCTTTGGGTGG

TGAGGTCCGCCTGAACTCTCGTATTAAGAAAATTG

AACTGAACCCTGACGGGACTGTGAAGCACTTTGCA

TTGAGTGATGGGACTCAAATAACTGGAGATGCTTA

TGTTTGTGCTGCACCAGTTGATATCTTCAAGCTTCTT

GTACCGGAACAGTGGAGAGAGATCTCTTATTTCAA

GAGGCTGGATAAGTTGGTGGGAGTTCCTGTCATCA

ATGTTCATATATGGTTTGACAGAAAACTGAAAAAC

ACATACGACCACCTTCTTTTCAGCAGGAGTCCACTT

TTAAGCGTCTATGCAGACATGTCAGTAGCGTGCAA

GGAGTATTATGATCCAGACCGTTCAATGCTGGAGT

TGGTGTTTGCTCCAGCAGAGGAATGGATTGGACGT

AGCGACGCTGAAATCATCGAAGCAACCATGCAAGA

GCTAGCCAAGTTATTTCCTGATGAAATTGCTGCTGA

TCAGAGTAAAGCAAAAATTCGTAAATACCATGTTG

TGAAGACACCGAGATCTGTTTACAAGACCATCCCA

GATTGTGAACCTTGCCGACCTCTGCAACGATCACC

GATCGAAGGGTTCTATCTGGCTGGCGATTACACGA

AGCAGAAATATTTGGCTTCCATGGAGGGT

70

Lolium

Genomic
1670
AAGGAAACAGTGCACCAGCGTCGTCGTCGCCCGAC

multiflorum

CAAAGGTCTTAGATTTTCACCCTGAAGATAGTCCCC

ACTCTCAAAACAATGCCTCCAACAAGAACATTGCCA

GGCACAACCAGTTAAGGCCNNNCCTTGGGTTTTCA

CCCTGAGAGGTAAGACTCTGAGCTTCCCCTGTGCT

GCCGCCCCCNNATGCATACCACTGCTGCAGAGCCT

GGAACGCCGAGCAGATCCCTCAGCATCACGGAGAC

TCAAACCTCCTTTAGCCAGTCCACCAATCTGGCCTT

CATGATATTCCTTCTTCTGACTTCACCATGGACCAA

AAAGTCACCTGATGTACACACAGAATAGAGCTTCG

CGCCGCTCCTTCCGGAACCAAACGGTCGGAATAAA

AACATGGGTGCGCGCGACCGAATACCACCTGATCC

AGCAAACTGCAGGCAAAAGATGCACTGTTCCATTC

ACCAGCGGAGCTTTCCGGAACTCATCTCTCCAGCTA

GATCAAAGCAAACTGATCTCCGGAAGATCTTCATCC

TCGCATGCGAGAAACCCGAGGACCGCCACCAAAAA

CAAAGAAAGATCAGCAGCCCCCACGCCGCCAATCC

CTCTTGCCGGATCACCAAAGAAGAGGACAGCGACG

CAGATCATGCGTACGGCCGCCAAACCGTTACCGGG

GGCGGAGGCCGCCACCGCTCCACCGAATCCTCCAT

GGCTACCGACGGAGAGCCTCAGGCCCCAGCCAAGT

AGCCGTGCCGCCCGGCTTCCTCCACTGGCGCTACAT

CACCTCCCATGGAACGCCGCCGCGGAAACCCTCTT

CTCCCCCTCGTCGATTCGACGAAAGGGGTGCCGCC

ACCACCGCTAGAGCCAGGCCGGGACCGGGGCCGA

GGCACGGGGGCCGGGGCCGAGGCCAGCGCCGGG

GTCGGGGCCGCGGCCGGAAGCGGCAGCGGCTGA

GGGCGACGGGCGGCGGGTGGATGTAGGCCGCGG

GGGGAGGAGGAGCCTCCGCCGCCGCCCGGGAGG

GGGGCGGGAGAGGGGGGCGGCGGGTTAGGGTTA

GGTGAGTAGCCCCAGATGAGTCAAACTTCTATTGT

TGTGTTGGTGCGTTATGGTATGGCATTATTGTGGTC

TAATCACCTCTCTGCTTGCAGGATTCTAAATTGTTG

TCCCGTAGGAGCCAGGAAAGCCTGAAGACAAAATC

CGAAGTTCCCGTCGCTTCCTAGGTGTATTTAATTAG

CACACAAATCATTCTTAGCACATTCTGTGGTATTTTC

ACACTGTTGTAGAGTTGAACAGGTGATTGAGCTGA

TATCCATATTGTGAAAAAGGAAATCTGTAAAACGA

GAAGCTGCATAAAAGCAGCTCTGATCCATATAGCA

ATTCTTACGTTAGACCTTTCCGGAAGGCAAAAGTG

ATAAAAAAAGGATCTTAGATATTATCTTCGTTTGCA

ACAATTGGAACTGGATCATTAACCGCTTACTTTTCT

GGAATTGTATAACATTAAAACCTAAGGTTCGTGTC

AGCAAAAGGGGATGAAATCATGGATAATATCCTAG

CATCTAAATCTTGTAAGCAAATGGGATTTATGATAT

TTGGCAGTTGCAACACCAAGCTGCAGTTACAAAAA

GGAGGCACAGAGACAGGCCCTGAGATAGATGATG

GGGCCTCAGTAAGTGAGATATT

71

Lolium

Genomic
1612
CAAAAGTTCAGAACAAAAAAATAGAGAGAAACAC

multiflorum

CAAAGTTGTTTCTCTGAAACCGTCATGCCATTCTTT

AAAAGGAAGAAGAGGTATTTTCAAAACATCGTGCT

TCACTGCTTCTGCTGATTATGTGCATATACAAAGTT

ATAAGTTCATTGGAAACGATACTAGTTAGCCTTTAG

ACATGCATTTGGATCCCTGCTTTGTTTCATGTTGTTA

GCAAATTCCTACACCCTTGAAATAAAAAGATTATTA

TCTTGCTGTTCTTTTAAAGGGTAACTTGATTGTGAA

CGTGATGCCGGCGGGCTGGACAGATGGGAGGCAC

AGACTTTATATAAGCTCCATGGAAGCCTCTTTCATC

GATCAACTCTACGGCTACAAAGTAAATCAGAAAGC

CCATGACTTGAAAATCATCCGCGGTGGAGTGTTGG

GGAAACTCAAATCGCAGAGGACCAATGTTCGTGCT

CCAGTAACGGGTGAATGCCTCCTGCCTGCAAACCC

GTGGATGCGTGACTGCAGCAGCAGCAGCAGCAAT

GCAAGAAGTGATGTAGCAAAAACCGCAGTGGGTG

ATCACGAGTCTGGTATATGGACTATCCATGGGAGG

AGTCCGCTGTCGCATGAAAGGGAATTGGGAGCTTG

CAATGGAGAAAAACTTCTCCATGATAATACAGGTA

GCTATCTCAGTTACCTCATTCAACTTCCGGTGTATC

ATATGTTTTCAACACTAGCTGATTTTATGGAAGATG

CATGAACAATTCAAAAATCAATTGTGTGTAAGCTCC

AAGATGCTGTCTGTCTGAACGTACCTATGTTAGCAA

TAAGCTCGTAAAAGTTAGACTGCTAACCATGCTCTG

AAGCAGTCTGCTACGAAGAACTAAATATCTGATGC

CATTTTTTTTCTCTCCCTGCAGAGGTCTCTGATGAG

AACTTTTCTGACTACGAGACGAAACTCGATGCGGA

ATCAAGTAAATTGTGCAAGAAAAGGAGGTTAAGCA

GTACTTCCACTTACTGAATGATCAAATGAGCTCGCA

TGATTAATTAGCATATAGTGTGTTGCAAGCATTGA

GATGAAAAGCAACACACCGAATTACTCAAAGAACC

TGTTTGCTGCCTCAAAATCTGTTCGGAGCCTGTTTG

TATCCTGTCAGACGCCCTCACTCACTACTTGGAGTA

GTAGATAATATTGTTTCGTTTATTGGATGCAAATGC

AATGCATTCTATAAAGTTTGACTAATTATATGGAAA

AAAATTAACAACTAAAATATCATATCACTGTTATTA

GAACCACCATGGAATATATTTTCATAGTATATGCAT

TTGGTATTGCGATGTATGCTGAAATAGAGTGGGTA

TTATCTCTAGGAGGCTTCTTCCTTTCAAGTCAAGTTT

TGTATCCCGATATATACTCACCCGAGACCGAGAGA

CACCGATACAACAATGTCCAAAGAGTAACGTCAAT

TTCATACTCTTTCAGGAACCATGCATCTAAGGCAAA

CGTTGTAATTAATCAATAAGGTACAATATGAGACC

AGAGTGTGGTGCTTGGCCGGGGCCAAATATTTTAG

TAATGTAATCCCAAGAGAGTAGTATGTCGTGTAAT

GCCTAGGATTTGTCTGA

72

Lolium

Genomic
1352
AACTGAACCCTGACGGGACCGTGAAGCACTTTGCA

multiflorum

TTGAGTGATGGGACTCAAATAACTGGAGATGCTTA

TGTTTGTGCTGCACCAGGTGTGATTTATTTTCAAGA

ATCATGTTTTCTTTACACCTGTTCAGTTTAACTGACT

AGCCTGTTATTCAGTTGATATCTTCAAGCTTCTTGTA

CCGGAGCAGTGGAGAGAGATCTCTTATTTCAAGAG

GCTGGATAAGTTGGTGGGAGTTCCTGTCATCAATG

TTCATATATGGTGAGTTGATTGAAACTATTGGTTCT

AAGTCAAGACAACTTCGTGTTTTTCGGTTCGACTTA

TATGGTCCTGCCTCATGTGTTATTTCAGGTTTGACA

GAAAACTGAAAAACACATACGACCACCTTCTTTTCA

GCAGGTATTCCTTTCTTCATACTCATCTTCCTGTTGG

CACCTAGTGCATTTTGTTGTCTTGTATTCAAATTGA

GCGTCTTCAATCCTACCCCTACATGCTTTGAATGTG

TTTTTGTTTGATACCAAGTACCAGATGTCCCTTATGT

TGATCTTGTTCACTTCTGTTTCAGGAGTCCACTTTTA

AGCGTCTATGCAGACATGTCAGTAGCTTGCAAGGT

ACTAACTCAAGGAGTTATTAATATTGCATAGATACT

AATATGAGGCATGTGATCCTGCATTCTTCTTGGAAT

CCACCATATTAAGTATTGATTGCGGGTTAACCGGA

ATTGTACTTTGAGGACTATTGACCAAAGGCCCAAA

ATGCTTTTGCTAAGAAGGAATCATTATTGAACTTAA

AATTATAGATACCTTTGGCATTGCAAATTGTAGTTA

TAAATTACTGAAGTATAGCATTTTTGTCATTGCTAA

CATGTCCGTTGGCTGTTGATTTCGTGAATCATTTTA

GTTAGAATAACTGAATAACCGTGCTAGCTTAACTG

AAAGAACGAAGGACATGGATGCATACTCGTAATTT

TATTTTTTCCTTGTTCTTTAACTCTATGCAGGAGTAC

TATGATCCAGACCGTTCAATGCTGGAGTTGGTCTTT

GCTCCAGCAGAGGAATGGATTGGACGTAGCGACG

CTGAAATCATCGAAGCAACCATGCAAGAGCTAGCC

AAGTTATTTCCTGATGAAATTGCTGCTGATCAGAGT

AAAGCAAAAATTCGTAAATACCATGTTGTCAAGAC

GCCGAGGTGAGGACATTTTGCTAACACCCATCCTG

TTGATTAATCAAAAGGACACCTGATGTGGTCTTGTT

CTCTTACACTGTTTATATTTTTCTGGCTCGCTGTTAC

AGATCTGTTTACAAGACCATCCCAGATTGTGAGCCT

TGCCGACCTCTGCAACGATCACCGATC

73

Lolium

Genomic
1210
CCTTTGTACTCTGTGTATAGGTTATATCCATTGGCA

multiflorum

GTGTACAGATAGTATTTGATGCCTCAGACAAATAT

GTACACAATAATAAGATAGAACACCTTGAGTGAAG

TACAAAGTGATTTTTGAGTAGTCACATTGAGGTTCT

GAAATTGCAAATAAGAGAAGAGTTTCATACTGTCA

AATTTTTAGCTTGTTTGCATTTTATTAATGGGCCTTA

TTCTCTTAATAATATTTTTACCGGGTTTTTTGCGTGA

CTGTATGAAAATATATAAGGGATTCACGCATACAG

TAGCTTAGATTTTAATGTTCCATACATCATTGTTGG

CCTGGTTGAATTTTTTTTTGTCTATAAATTCTCTTCT

ACCAGCCTTTTCTCCCTGCCGGTAGCTTGTGTACGG

TACTTCTCATTCTGTGCATGTATGTAACCATATGTTT

TTTTTTTGGGTTTTAAGTTGGAGCTTATCCCAACGT

ACAGAATTTGTTTGGTGAGCTTGGTATTAATGATCG

CTTGCAATGGAAGGAACACTCTATGATATTTGCCAT

GCCAAACAAGCCAGGAGAATACAGCCGTTTTGATT

TCCCAGAGGTTTTGCCAGCGCCTTTAAACGGTAAG

ATCATACATAGCCCTGGTGTTGCTTAATAGATGAAA

GAATGGCAAGAAAACTTAGGAATGCATCCTAGTGT

TAGTTCTTTCATTTTGCTAATATTTGAATGCAACTAG

TGGGGTATGTTAGTGCAAACAACATTGTCATGGCC

ATCCAGCTGTTCTCTTCCCATCAATGTCAGTTTATCA

TTGATTATGCATGTATTTAACAGGAATATGGGCCAT

ACTGAAGAACAATGAAATGCTTACTTGGCCGGAGA

AGGTGAAGTTTGCTATTGGACTTCTTCCAGCAATGC

TTGGTGGCCAAGCTTATGTTGAAGCTCAAGATGGC

TTAACTGTTTCAGAGTGGATGGAAAAGCAGGTATG

AGCCCACCAAGTCAGTTAGACTCATCTCTTTGTACT

GAACACATAGCCGTCTCAATTCACACTTGATATATG

AGGATATGTTGTAACGCGATAAATTGCTGCCTTCCT

TCTATTGTTATATTTTTATGAAGAAGTGTGGCTAGG

TCCATAAATGAAACTATATGCTCAAGTTTCCATACT

TTTTTCCACCCAGCCCTTTTGTATGCAATGTAGGCTT

AAGTAATACTTATATTTCTATTAATC

74

Lolium

Genomic
1057
TCTTGGCTCAAGGAATAGAGGGAAAAAATCACGCC

multiflorum

GTGGGCTTGCTGCTCTGCAGGTTAAGATTTCGTCCC

TGTTCGGAAAATAAAGTGGTTTCTCTATTTTATCTC

ACCACAGCCGTTTCTTGTGAAGTAATTGTTTGCATT

TTCTGCAGGTTGTTTCCCAGGATTTACCAAGACCTC

CACTGGAAAACACAATTAACTATCTGGAAGCTGGG

CAGCTTTCTTCATCTTTTAGAAGCAGTGAACGACCC

AGTAAACCATTACAGGTCGTGATTGCTGGTGCAGG

TCTGATGTAACTCCTGGATTAGAACATATATGAATT

TCACAAATTAGATACCCCCCCTGAGTGAAGCACAA

CTGCCTCTTAGCGTTACTCGTCTCTGGTGTGAATTG

TGCAGGATTGGCTGGACTATCAACCGCAAAATATC

TAGCAGATGCTGGCCATAAACCCATATTGCTAGAA

GCAAGAGATGTTTTGGGCGGAAAGGTCTGATAGTT

TCTTACATCTGTTGCTTATCTCATCTCTAAAATTGTG

CTGGTTATTTAATCTGACTTTTCAGTTGCTGTCGTCA

TTCTGAGTAGCTCACCTTCACCATTATTGTTGCTTGA

TTGCTTCTATCCTTGTATGCCTTCAACAGTTAGCTGC

TTGGAAGGATGAAGATGGTGATTGGTATGAAACT

GGTCTTCATATTTTCTGTAAGTTACGGTACTTCCTTG

TTCCTTTGTGCCCTGTGTATAGCTTGTTTCCACTGGC

AGTGTATAGATAGTATTTGATGCGTCAGACAAATA

TCTACATAATAATAAGATAGAATACCTTGAGTAAA

GTACAAAATGATCTTTGAGGAGCCACATTGAGGTT

CTGAAATTGCAAATAAGTGAAGAGTTTCATACCGT

CAAATTTTTAGGTTGCTTGCATTTTATTAATGGGCC

TTATTCTCTTAATAATATTTTTAGTGGGTTTTTTTTTT

GTGTGACCGTATGAAAACATATAGCTTAAATTTCAA

TGCTGTGCATGTATGTAACCATATTTTTTTTTGGGTT

TTAAGTTGGAGCTTATC

75

Lolium

Genomic
999
ATTACAGATACCTTTGGCATTGCAAATTGTAGTTAT

multiflorum

CAATTACTGAAGTATAGCATTTTTGTCATTGCTAAC

ATGTCAGTCGGCTGTTGATTTCGTGAATCATTTTAG

TTTGAATAACTGAATAACCGTGCTAGCTTAACTGAG

AGAACGAAGGACATGGATGCATACTCGTAATTTTG

ATTTTCCCTTGTTCTTTAACTCTATGCAGGAGTATTA

TGATCCAGACCGTTCAATGCTGGAGTTGGTGTTTG

CTCCAGCAGAGGAATGGATTGGACGTAGCGACGC

TGAAATCATCGAAGCAACCATGCAAGAGCTAGCCA

AGTTATTTCCTGATGAAATTGCTGCTGATCAGAGTA

AAGCAAAAATTCGTAAATACCATGTTGTGAAGACG

CCGAGGTGAGGACATTTTGCCAACACCCATCCTGTT

GATTAATCAAAAGGACACCTGATGTGGTCTTGTTCT

CTTACACTGTTTATATTTTTCTGGCTCGCTGTTACAG

ATCTGTTTACAAGACCATCCCAGATTGTGAGCCTTG

CCGACCTCTGCAACGATCACCGATCGAAGGGTTCT

ATCTGGCTGGTGATTACACGAAGCAGAAATATTTG

GCTTCCATGGAGGGTGCAGTTTTATCCGGGAAGCT

CTGTGCCCAGTCCATAGTTCAGGTAAATGCTTTCCA

CGGTTCTGGTTGCACATAGATGAGTCAAACTTCTAT

TGTTGTGTTGGTGCGTTATGATATGGCATTATTGTG

GTCTAATCACCTCTCTACTTGCAGGATTCTAAATTG

TTGTCCCGTAGGAGCCAGGAAAGCCTGAAGACAAA

ATCCGAAGTTCCCGTCGCTTCCTAGGTGTATTTAGT

TAGCACACAATTCATTCTTAGCACATTCTGTGGTAT

TTTCACACTGTTGTAGAGTTGAACAGGTGATTGAG

CTGATATCCATATTGTGAAAAAGGAAATCTGTAAA

ACGAGAAGCTGCATAAAAGCAGCTCTGATCCATAT

AG

76

Lolium

Genomic
677
TTCAACAGTTAGCTGCTTGGAAGGATGAAGATGGT

multiflorum

GATTGGTATGAAACTGGTCTTCATATTTTCTGTAAG

TTACGGTACTTCCTTGTTCCTTTGTGCCCTGTGTATA

GCGTGTTTCCACTGGCAGTGTATAGATAGTATTTGA

TGCGTCAGACAAATATCTACATAATAATAAGATAG

AACACCTTGAGTAAAGTACAAAATGATCTTTGAGG

AGCCACATTTAGGTTCTGAAATTGCAAATTAGTGA

AGAGTTTCATACCGTCAATTTTTTAGGTTGCTTGCA

TTTTATTAATGGGCCTTATTCTCTTAATAATATTTTT

AGTGGGTTTTTTTTTGCGTGACCGTATGAAAACATA

TAGCTTAAATTTCAATGTTCCATACATCGTTGTTGG

CATGGTGGAATATTTCTTTTGTCTATAAATTCTCTTC

TACCAGCATTTCCTCCCTGCCAGTAGCTTGTGTACG

GTATTCATTCTGTGCATGTATGTAACCATATGTTTTT

TTTTTGGGGGGGTTTAAGTTGGAGCTTATCCCAAC

GTACAGAATTTGTTTGGTGAGCTTGGTATTAATGAT

CGCTTGCAATGGAAGGAACACTCTATGATATTTGC

CATGCCAAACAAGCCAGGAGAATACAGCCGTTTTG

ATTTCCCAGAGGTTTTGCCAGCGCCTTTAAAC

77

Lolium

Genomic
653
AGTACCTCTCCGAGCTCCACATATTAGCCTTGGGTG

multiflorum

TTTCTGCCTCCTTTGGTCGATCCTTCTCTGTGTCTGA

TGATCACCGGGGAGATGAGCGAAACGTCTGTGGA

TGGACCGCTTAAGGCACAGCCACCGGCCATCCGCA

TTCCTCAGGTAACAACAACTCCTCTTGCAGGCACGT

GGTCCTTGTTTATTTTCATTTTTGTTCTTGCTGCTCA

TTACTTTCATGCTTTGCTTCCTAATGATATGCTTGCT

CCATTTACTAACAGTTACACATTCGGCAGATTCATG

GTCAATCTCTTGTTGCGGACATAAAACTCCTTTTATT

TTTTCCAAGTCCGAAATTATTTGCATACATAGATGT

TGCTATCATATTCTTGTTCCCTTGAGGCCTTGACGA

CATAATAAACCGATTACTATCTTGTTCTTTGGCAGG

GCACGTTAACCCTTTTCTTTTCAAGTCCAAAACAAA

TAAATCTTGTTCGTAACAGAAAAAACAAAGGAGCA

CCCAAGTGTGCTGTTTCTCTGAAATATATACCCTCA

TGCCATTGCTCAAAAAGAGGTATCTTCAGAATATG

CTGCTCCTGCTCCTTATGTGCATATAAATAACTATA

GGCTTATGCTTCCATACACCCCCAAATCTCAAAACC

GATTGC

78

Lolium

Genomic
189
ATCGAAGGGTTCTATCTGGCTGGTGATTACACGAA

multiflorum

GCAGAAATATTTGGCTTCCATGGAGGGTGCAGTTT

TATCCGGGAAGCTCTGTGCCCAGTCCATAGTCCAG

GTAAATGCTCTCCACGGTTCTGGTTGCACATAGATG

AGTCAAACTTCTTTTTTTAGATAAAGGGAATATATT

AATATCAAAAGA

METHODS AND COMPOSITIONS FOR WEED CONTROL

Information

Publication Number

Date Filed

Date Published

Inventors

CPC

US Classifications

International Classifications

Abstract

Description

Claims

Parent Case Info

Provisional Applications (1)