Brassica Ogura Restorer Lines with Shortened Raphanus Fragment (SRF)

Information

  • Patent Application
  • 20140345005
  • Publication Number
    20140345005
  • Date Filed
    May 16, 2014
    10 years ago
  • Date Published
    November 20, 2014
    9 years ago
Abstract
New Brassica Ogura fertility restorer lines with a shortened Raphanus fragment are provided. The new lines lack the OPC2 marker and are capable of fully restoring fertility in Ogura cytoplasmic male sterile (cms) plants. The improved lines were developed using a new breeding method. The new breeding method can be used to shorten an exotic insertion comprising a gene of interest in any plant.
Description
REFERENCE TO SEQUENCE LISTING SUBMITTED ELECTRONICALLY

The official copy of the sequence listing is submitted electronically via EFS-Web as an ASCII formatted sequence listing with a file named 20140513_BB1870USDIV2_SeqLst created on May 13, 2014 and having a size of 83 kilobytes and is filed concurrently with the specification. The sequence listing contained in this ASCII formatted document is part of the specification and is herein incorporated by reference in its entirety.


FIELD OF THE INVENTION

The invention relates to new Brassica lines having a shortened Raphanus fragment which includes the fertility restorer gene for Ogura cytoplasmic male sterility. The invention also relates to a new breeding method to shorten an exotic insertion comprising a gene of interest in any plant.


BACKGROUND OF THE INVENTION

Oilseed from Brassica plants is an increasingly important crop. As a source of vegetable oil, it presently ranks behind only soybeans and palm in commercial market volume. The oil is used for many purposes such as salad oil and cooking oil. Upon extraction of the oil, the meal is used as a feed source.


In its original form, Brassica seed, known as rapeseed, was harmful to humans due to its relatively high level of erucic acid in the oil and high level of glucosinolates in the meal. Erucic acid is commonly present in native cultivars in concentrations of 30 to 50 percent by weight based upon the total fatty acid content. Glucosinolates are undesirable in Brassica seeds since they can lead to the production of anti-nutritional breakdown products upon enzymatic cleavage during oil extraction and digestion. The erucic acid problem was overcome when plant scientists identified a germplasm source of low erucic acid rapeseed oil (Stefansson, “The Development of Improved Rapeseed Cultivars.” (Chapter 6) in “High and Low Erucic Acid Rapeseed Oils” edited by John K. G. Kramer, Frank D. Sauer. and Wallace J. Pigden. Academic Press Canada, Toronto (1983)). More recently, plant scientists have focused their efforts on reducing the total glucosinolate content to levels less than 20 μmol/gram of whole seeds at 8.5% moisture. This can be determined by nuclear resonance imaging (NRI) or by high performance liquid chromatography (HPLC) (International Organization for Standardization, reference number ISO 91671:1992).


Particularly attractive to plant scientists were so-called “double-low” varieties: those varieties low in erucic acid in the oil and low in glucosinolates in the solid meal remaining after oil extraction (i.e., an erucic acid content of less than 2 percent by weight based upon the total fatty acid content, and a glucosinolate content of less than 30 μmol/gram of the oil-free meal). These higher quality forms of rape, first developed in Canada, are known as canola.


In addition, plant scientists have attempted to improve the fatty acid profile for rapeseed oil (Robbelen, “Changes and Limitations of Breeding for Improved Polyenic Fatty Acids Content in Rapeseed.” (Chapter 10) in “Biotechnology for the Oils and Fats Industry” edited by Colin Ratledge, Peter Dawson and James Rattray, American Oil Chemists' Society, (1984); Ratledge, Colin, Dawson, Peter and Rattray, James, (1984) Biotechnology for the Oils and Fats Industry. American Oil Chemists' Society, Champaign; 328pp; Robbelen, and Nitsch. Genetical and Physiological Investigations on Mutants for Polyenic Fatty Acids in Rapeseed, Brassica napus L. Z. Planzenzuchta., 75:93-105, (1975); Rako and McGregor. “Opportunities and Problems in Modification of Levels of Rapeseed C18 Unsaturated Fatty Acids.” J. Am. Oil Chem. Soc. (1973) 50(10):400-403). These references are representative of those attempts.


Currently, both open pollinated varieties and hybrids of Brassica are grown. In developing improved Brassica hybrids, breeders can utilize different pollination control systems, such as self incompatible (SI), cytoplasmic male sterile (CMS) and nuclear male sterile (NMS) Brassica plants as the female parent. In hybrid crop breeding plant breeders exploit the phenomenon of heterosis or hybrid vigor which results in higher crop yields (grain or biomass) from the combination or hybridization of a male and a female line. Using these plants, breeders are attempting to improve the efficiency of seed production and the quality of the F1 hybrids and to reduce the breeding costs. When hybridisation is conducted without using SI, CMS or NMS plants in a two-way cross, it is more difficult to obtain and isolate the desired traits in the progeny (F1 generation) because the parents are capable of undergoing both cross-pollination and self-pollination. If one of the parents is a SI, CMS or NMS plant that is incapable of producing pollen, only cross pollination will occur. By eliminating the pollen of one parental variety in a two-way cross, a plant breeder is assured of obtaining hybrid seed of uniform quality, provided that the parents are of uniform quality and the breeder conducts a single cross.


In one instance, production of F1 hybrids includes crossing a CMS Brassica female parent, with a pollen producing male Brassica parent. To reproduce effectively, however, the male parent of the F1 hybrid must have a fertility restorer gene (Rf gene). The presence of an Rf gene means that the F1 generation will not be completely or partially sterile, so that either self-pollination or cross pollination may occur. Self pollination of the F1 generation is desirable to ensure the F1 plants produce an excellent yield for the grower. Self pollination of the F1 generation is also desirable to ensure that a desired trait is heritable and stable.


One type of Brassica plant which is cytoplasmic male sterile and is used in breeding is Ogura (OGU) cytoplasmic male sterile (Pellan-Delourme, et al., (1987) Male fertility restoration in Brassica napus with radish cytoplasmic male sterility Proc. 7th Int. Rapeseed Conf., Poznan, Poland, 199-203). A fertility restorer for Ogura cytoplasmic male sterile plants has been transferred from Raphanus sativus (radish) to Brassica by Institut National de Recherche Agricole (INRA) in Rennes, France (Pelletier and Primard, (1987) “Molecular, Phenotypic and Genetic Characterization of Mitochondrial Recombinants in Rapeseed.” Proc. 7th Int Rapeseed Conf., Poznau, Poland 113-118). The restorer gene, Rfl originating from radish, is described in WO 92/05251 and in Delourme, et al., (1991) “Radish Cytoplasmic Male Sterility in Rapeseed: Breeding Restorer Lines with a Good Female Fertility.” Proc 8th Int. Rapeseed Conf., Saskatoon, Canada. 1506-1510.


However, when the Ogura Raphanus restorer gene was transferred from radish to Brassica, a large segment of the Raphanus genome was introgressed into Brassica as well. This large Raphanus genomic fragment carried many undesirable traits, as well as the restorer gene. For example, the early restorer germplasm was inadequate in that restorer inbreds and hybrids carrying this large Raphanus fragment had elevated glucosinolate levels and the restorer was associated with a decrease in seed set—the number of ovules per silique (Pellan-Delourme and Renard, (1988) “Cytoplasmic male sterility in rapeseed (Brassica napus L.): Female fertility of restored rapeseed with “Ogura” and cybrids cytoplasms”, Genome 30:234-238; Delourme, et al., (1994), “Identification of RAPD Markers Linked to a Fertility Restorer Gene for the Ogura Radish Cytoplasmic Male Sterility of Rapeseed (Brassica napus L.)”, Theor. Appl. Gener. 88:741-748). In the case of hybrids, the glucosinolate levels were elevated even when the female parent had reduced glucosinolate content. These levels, typically more than 30 μmol/gram of oil-free meal, exceeded the levels of glucosinolates allowable for seed registration by most regulatory authorities in the world. Thus, the early restorer germplasm could be used for research purposes, but not to develop canola-quality commercial hybrid varieties directly.


INRA outlined the difficulties associated with obtaining restorer lines with low glucosinolate levels for Ogura cytoplasmic sterility (Delourme, et al., (1994) “Identification of RAPD Markers Linked to a Fertility Restorer Gene for the Ogura Radish Cytoplasmic Male Sterility of Rapeseed (Brassica napus L.)”, Theor. Appl. Gener. 88:741-748; Delourme, et al., (1995) “Breeding Double Low Restorer Lines in Radish Cytoplasmic Male Sterility of Rapeseed (Brassica Napus L.)”, Proc. 9th Int. Rapeseed Conf., Cambridge, England). INRA indicated that these difficulties were due to the linkage between male fertility restoration and glucosinolate content in its breeding material. INRA suggested that more radish genetic information needed to be eliminated in its restorer lines (Delourme, et al., (1995) “Breeding Double Low Restorer Lines in Radish Cytoplasmic Male Sterility of Rapeseed (Brassica Napus L.)”, Proc. 9th Int. Rapeseed Conf., Cambridge, England). Although improvements were made to restorers during the early years, isozyme studies performed on the restorer lines indicated that large segments of radish genetic information still remained around the restorer gene (Delourme, et al., (1994) “Identification of RAPD Markers Linked to a Fertility Restorer Gene for the Ogura Radish Cytoplasmic Male Sterility of Rapeseed (Brassica napus L.)” Theor. Appl. Gener. 88:741-748).


INRA attempted to develop a restorer having decreased glucosinolate levels. It reported a heterozygous restorer with about 15 μmol per gram (Delourme, et al., (1995) “Breeding Double Low Restorer Lines in Radish Cytoplasmic Male Sterility of Rapeseed (Brassica Napus L.)”, Proc. 9th Int. Rapeseed Conf., Cambridge, England). However, (i) this restorer was heterozygous (Rfrf) not homozygous (RfRf) for the restorer gene, (ii) this restorer was a single hybrid plant rather than an inbred line, (iii) there was only a single data point suggesting that this restorer had a low glucosinolate level rather than multiple data points to support a low glucosinolate level, (iv) there was no data to demonstrate whether the low glucosinolate trait was passed on to the progeny of the restorer, and (v) the restorer was selected and evaluated in a single environment—i.e. the low glucosinolate trait was not demonstrated to be stable in successive generations in field trials. Accordingly, the original Brassica Ogura restorer lines were not suitable for commercial use. For the purposes of this disclosure, this material is referred to as the “original” Brassica restorer lines.


Improved restorer lines were produced by Charne, et al., (1998) WO 98/27806 “Oilseed Brassica Containing an improved fertility restorer gene for Ogura cytoplasmic male sterility.” The improved restorer had a homozygous (fixed) restorer gene (RfRf) for Ogura cytoplasmic male sterility and the oilseeds were low in glucosinolates. Since the restorer was homozygous (RfRf), it could be used to develop restorer inbreds or, as male inbreds, in making single cross hybrid combinations for commercial product development. The glucosinolate levels were below those set out in standards for canola in various countries and breeders could use the improved restorer to produce Brassica inbreds and hybrids having oilseeds with low glucosinolate levels. This was a benefit to farmers, who could then plant Brassica hybrids which, following pollination, yielded oilseeds having low glucosinolate levels. This breeding effort removed approximately two thirds of the original Raphanus fragment. This estimate is based on the loss of 10 of 14 RFLP, AFLP and SCAR markers (WO98/56948 Tulsieram, et al., 1998-12-17). However, the Raphanus fragment in this material is still unnecessarily large. For the purposes of this disclosure, this material is referred to as the “first phase recombinant” Brassica restorer lines or germplasm.


Despite the improvement in the “first phase recombinant” restorer germplasm, it is still associated with deleterious agronomic performance. These deleterious traits may result from genes within this Raphanus fragment unrelated to fertility. Practically, only the restorer gene in the Raphanus fragment is required for the canola CMS pollination system. Therefore, the shorter the Raphanus fragment in a restorer line, the better the restorer line is expected to perform.


The Ogura restorer gene has been isolated and cloned by DNA LandMarks Inc./McGill University (US Patent Application Publication Number 2003/0126646A1, WO 03/006622A2), Mitsubishi (US Patent Application Publication Nubmer 2004/0117868A1) and INRA (WO 2004/039988A1). The gene can be used to transform Brassica plants.


Others have tried to produce restorer lines with a shortened Raphanus fragment. For example, Institut National de la Recherche (INRA) developed a line with a shortened Raphanus fragment by crossing a restorer line, “R211”, which had a deletion of the Pgi-2 allele and crossing it with a double low B. napus line, Drakkar. The progeny plants were irradiated before meiosis with gamma irradiation to induce recombination. This resulted in one progeny plant, “R2000”, in which the Pgi-2 gene from Brassica oleracea was recombined (WO 2005/002324 and Theor. Appl. Genet (2005) 111:736-746). However, the Raphanus fragment in R2000 is larger than that of the first phase recombinant restorer material developed by the Applicant and described above.


Another example, WO 05074671 in the name of Syngenta describes a shortened Raphanus fragment in their BLR1 recombination event. The BLR1 recombination event was produced solely by crossing and selection, followed by screening with molecular markers; no mutagenesis was used. However, the Raphanus fragment can be shortened further.


SUMMARY OF THE INVENTION

An aspect of the invention is to provide a Brassica plant comprising a fertility gene for Ogura cytoplasmic male sterility, wherein the fertility gene is on a Raphanus fragment introgressed from Raphanus sativa, and the Raphanus fragment lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33. The Brassica plant can lack the OPC2 marker in the Raphanus fragment.


Another aspect of the invention is to provide a Brassica plant comprising a fertility gene for Ogura cytoplasmic male sterility, wherein the fertility gene is on a Raphanus fragment introgressed from Raphanus sativa, and the Raphanus fragment (i) lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33, and (ii) comprises a molecular marker selected from the group consisting of RMB01, E35M62, RMB02, RMB03, RMB04, RMB05, RMB06, RMB07, RMB08, RMB09, RMB10, OPF10, RMB11, RMB12, RMC01, RMCO2, RMCO3, E38M60, RMC04, RMCO5, RMC06, RMC07, RMC08, RMC17, RMC18, RMC19, RMC20, RMC21, RMC22 and RMC23. The Brassica plant can be designated R1439, representative seed of which have been deposited under NCIMB Accession Number 41510, or a descendent or a plant produced by crossing R1439 with a second plant. The progeny or descendent plant of this Brassica plant can comprise a Raphanus fragment which lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC09, RMC10, RMC11, RMC12, RMC13, RMC14, RMC15, RMC16, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33.


Another aspect of the invention is to provide a Brassica plant comprising a fertility gene for Ogura cytoplasmic male sterility, wherein the fertility gene is on a Raphanus fragment introgressed from Raphanus sativa, and the Raphanus fragment (i) lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33, and (ii) comprises a molecular marker selected from the group consisting of RMB01, E35M62, RMB02, RMB03, RMB04, RMB05, RMB06, RMB07, RMB08, RMB09, RMB10, OPF10, RMB11, RMB12, RMC01, RMCO2, RMCO3, E38M60, RMC04, RMCO5, RMC06, RMC07, RMC08, RMC09, RMC10, RMC11, RMC12, RMC13, RMC14, RMC15, RMC16, RMC17, RMC18, RMC19, RMC20, RMC21, RMC22 AND RMC23. The Brassica plant can be designated R1815, representative seed of which have been deposited under NCIMB Accession Number 41511, or a descendent or a plant produced by crossing R1815 with a second plant. The progeny or descendent plant can comprise a Raphanus fragment which lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33.


Another aspect of the invention is to provide a Brassica plant comprising a fertility gene for Ogura cytoplasmic male sterility, wherein the fertility gene is on a Raphanus fragment introgressed from Raphanus sativa, and the Raphanus fragment (i) lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33, and (ii) comprises a molecular marker selected from the group consisting of RMB01, E35M62, RMB02, RMB03, RMB04, RMB05, RMB06, RMB07, RMB08, RMB09, RMB10, OPF10, RMB11, RMB12, RMC01, RMCO2, RMCO3, E38M60, RMC04, RMCO5, RMC06, RMC07, RMC08, RMC09, RMC10, RMC11, RMC12, RMC13, RMC14, RMC15, and RMC16. The Brassica plant can be designated R1931, representative seed of which have been deposited under NCIMB Accession Number 41512, or a descendent or a plant produced by crossing R1931 with a second plant. The progeny or descendent plant can comprise a Raphanus fragment which lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC17, RMC18, RMC19, RMC20, RMC21, RMC22, RMC23, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33.


Any of the Brassica plants described above can be Brassica napus, B. rapa or B. juncea. The plants can be inbreds or hybrids.


Another aspect of the invention is to provide a Brassica seed from any of the Brassica plants described above. Another aspect is to provide a plant cell from any of the plants described above, or parts of the plants described above. The parts can be selected from the group consisting of nucleic acid sequences, tissue, cells, pollen, ovules, roots, leaves, oilseeds, microspores, vegetative parts, whether mature or embryonic.


Another aspect of the invention is to provide an assemblage of crushed Brassica seed of any one of the Brassica plants described above.


Another aspect of the invention is to provide a use of the seed of any of the Brassica plants described above for preparing oil and/or meal.


Another aspect of the invention is to provide a method of producing oil, comprising: (i) crushing seeds produced by the plant line designated R1439, R1815, or R1931 and having NCIMB Accession Number 41510, 41511 and 41512 respectively, or by a descendent of R1439, R1815, or R1931, or by a plant produced by crossing R1439, R1815, or R1931 with a second plant; and (ii) extracting oil from said seeds. The method can further comprise the step of: (i) refining, bleaching and deodorizing said oil.


Another aspect of the invention is to provide use of any of the plants described above for growing a crop.


Another aspect of the invention is to provide a method of growing a Brassica plant, comprising: (i) sowing seed designated R1439, R1815, or R1931 and having NCIMB Accession Number 41510, 41511 and 41512 respectively, or seed from a descendent of R1439, R1815, or R1931, or from a plant produced by crossing R1439, R1815, or R1931 with a second plant; and (ii) growing the resultant plant under Brassica growing conditions.


Another aspect of the invention is to provide use of any of the plants described above for breeding a Brassica line. The breeding can be selected from the group consisting of conventional breeding, pedigree breeding, crossing, self-pollination, doubling haploidy, single seed descent, backcrossing and breeding by genetic transformation.


Another aspect of the invention is to provide a method of breeding a Brassica plant having a fertility gene for Ogura cytoplasmic male sterility, wherein the fertility gene is on a Raphanus fragment introgressed from Raphanus sativa, and the Raphanus fragment lacks a molecular marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33, comprising: (i) crossing any of the plants described above with another Brassica plant to produce a first generation progeny plant; (ii) screening the first generation progeny plant for the Ogura Raphanus restorer gene; and (iii) optionally repeating steps (i) and (ii). The first generation progeny plant can be an inbred plant. The first generation progeny plant can be a hybrid plant. The progeny plant produced by this method is also provided.


Another aspect of the invention is to provide a method for breeding a new line having a shortened Raphanus fragment compared to a Raphanus fragment in a first plant, wherein the shortened Raphanus fragment in the new line includes an Ogura fertility restorer gene, the method comprising: (i) mutagenizing a first population of the first plant having a Raphanus fragment with an Ogura fertility restorer gene for cytoplasmic male sterility; (ii) screening the first population for deletions of the Ogura fertility restorer gene in the Raphanus fragment to identify a second plant with a deletion of the Ogura fertility restorer gene in the Raphanus fragment; (iii) crossing the second plant having the deletion of Ogura restorer gene in the Raphanus fragment with the first plant comprising the Raphanus fragment with an Ogura fertility restorer gene for cytoplasmic male sterility; (iv) identifying a third plant with a shortened Raphanus fragment compared to the first plant, wherein the shortened Raphanus fragment includes the restorer gene, and (v) breeding the third plant to produce a new line with a shortened Raphanus fragment which includes an Ogura fertility restorer gene. The first plant can be R1439, R1815 or R1931. The third plant can lack a molecular marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33. The new line produced by this method is also provided.


Another aspect of the invention is to provide an isolated nucleic acid comprising the sequence set forth in any of the sequences listed in SEQ ID NO: 1 to SEQ ID NO: 158.


Another aspect of the invention is to provide use of an isolated nucleic acid comprising the sequence set forth in any of the sequences listed in SEQ ID NO: 1 to SEQ ID NO: 158 for molecular marker development.


Another aspect of the invention is to provide use of an isolated nucleic acid comprising the sequence set forth in any of the sequences listed in SEQ ID NO: 1 to SEQ ID NO: 158 as a primer.


Another aspect of the invention is to provide use of the isolated nucleic acid comprising the sequence set forth in any of the sequences listed in SEQ ID NO: 1 to SEQ ID NO: 158 as a probe.


Another aspect of the invention is to provide use of one or more of the sequences of SEQ ID NOS: 1 to 158 to screen a plant to characterize the Raphanus fragment.


Another aspect of the invention is to provide a method of screening a plant to characterize the Raphanus fragment, comprising; (i) hybridizing at least one primer sequence selected from the group consisting of SEQ ID NO: 1 to SEQ ID NO: 158 to a plant genome; (ii) performing a PCR assay; and (iii) characterizing the Raphanus fragment.


Another aspect of the invention is to provide a method of producing a deletion mutant in a genome having a Raphanus fragment with an Ogura fertility restorer gene, comprising: (i) providing a population of cells, wherein the cells are heterozygous for the Raphanus fragment and the cells have an Ogura CMS cytoplasm; (ii) mutagenizing the cells to produce mutagenized cells; (iii) producing plants from the mutagenized cells; and (iv) screening the plants for sterility to identify a deleted Ogura fertility restorer gene in a deletion mutant wherein the mutagenized Ogura gene is not able to restore fertility in a plant having the Ogura CMS cytoplasm. The step of mutagenizing the cells can include irradiation. The deletion mutant produced by this method is also provided.


Another aspect of the invention is to provide a method of recombining a Raphanus fragment having an Ogura restorer gene, comprising: (i) providing a plant having a Raphanus fragment with an Ogura restorer gene in the nuclear genome; (ii) crossing the plant of (i) with a plant having a Raphanus fragment in which an Ogura restorer gene has been deleted in the nuclear genome; and (iii) identifying progeny in which the Raphanus fragment has been recombined. The plant of (i) can be homozygous for the Raphanus fragment with an Ogura restorer gene (RfRf) and the plant of (ii) can be homozygous for the Raphanus fragment in which the Ogura restorer gene has been deleted (Rf̂Rf̂), and the progeny from a first progeny population that are heterozygous for the Raphanus fragment (Rf Rf̂) to allow for recombination at an efficient rate of (a) the Raphanus fragment with an Ogura restorer gene (Rf) and (b) the Raphanus fragment in which the Ogura restorer gene has been deleted (Rf̂). The method can further comprise pollinating (a) a plant that does not contain a Raphanus fragment (rfrf) and has an Ogura CMS cytoplasm with (b) pollen from the progeny plant above that is heterozygous for both the Raphanus fragment with an Ogura restorer gene and the Raphanus fragment without an Ogura restorer gene in the nuclear genome (RfRf̂), to produce a second progeny population that is heterozygous for the Raphanus gene in an Ogura CMS cytoplasm, wherein the second population comprises approximately 50% of plants with a rfRf genotype, approximately 50% of plants with rfRf̂genotype and some progeny in which the Raphanus fragment has been recombined (rfRf*), and wherein analysis of the Raphanus fragment in the second progeny is facilitated because there is no interference in analyzing the Raphanus fragment. The second population progeny plants can be screened for fertility prior to analysis. The method can further comprise a step of identifying a plant comprising a homozygous recombined Raphanus fragment. The progeny plant having a recombined Raphanus fragment produced by this method is also provided.


Another aspect of the invention is to provide a method for shortening an exotic insertion in a first plant wherein the exotic insertion includes a gene of interest, the method comprising: (i) mutagenizing the first plant having the exotic insertion which includes a gene of interest to produce a second plant having a partially deleted exotic insertion lacking the gene of interest; (ii) crossing the second plant with the first plant to produce a first population in which both the exotic insertion from the first plant and the partially deleted exotic insertion from the second plant can recombine; (iii) crossing the plants of the first population with plants that do not have the exotic insertion to produce a second population of plants; and (iv) screening the second population of plants to identify a third plant with a shorter exotic insertion than the exotic insertion in the first plant, wherein the shorter exotic insertion in the third plant includes the gene of interest.


Another aspect of the invention is to provide a method for breeding a new line having an exotic insertion that is shorter than the exotic insertion in a first plant, wherein the exotic insertion includes a gene of interest, the method comprising; (i) mutagenizing the first plant having the exotic insertion which includes a gene of interest to produce a second plant having a partially deleted exotic insertion lacking the gene of interest; (ii) crossing the second plant with the first plant to produce a first population in which both the exotic insertion from the first plant and the partially deleted exotic insertion from the second plant can recombine; (iii) crossing the plants of the first population with plants that do not have the exotic insertion to produce a second population of plants; and (iv) screening the second population of plants to identify a third plant with a shorter exotic insertion than the exotic insertion in the first plant, wherein the shorter exotic insertion in the third plant includes the gene of interest.


The previous two methods can further comprise a step of generating genetic information of a genomic region surrounding and including the exotic insertion. Generating of genetic information can be selected from the group consisting of generating molecular markers, sequence information and a genetic map. The first plant can be heterozygous for the gene of interest when undergoing mutagenesis in step (i). The first plant can be homozygous for the gene of interest when crossed to the second plant in step (ii). The second plant can be homozygous for the partially deleted exotic insertion lacking the gene of interest when crossed to the first plant in step (ii). The methods can further comprise a step after the step (ii) of identifying plants having the exotic insertion from the first plant and the partially deleted exotic insertion from the second plant using the genetic information. The methods can further comprise the step of increasing the seed of step (ii). The methods can further comprise the step of breeding the third plant to generate a commercial line. The exotic insertion can be a Raphanus insertion and the gene of interest can be the Ogura fertility restorer gene. The exotic insertion can include a gene of interest selected from the group consisting of disease resistance, insect resistance, drought tolerance, heat tolerance, shattering resistance and improved grain quality. The third plant produced by either of the previous two methods is also provided.


Another aspect of the invention is to provide a molecular marker selected from the group consisting of SEQ ID NOS: 159 to 237.


Another aspect of the invention is to provide use of one or more of the sequences of SEQ ID NOS: 159 to 237 to screen a plant to characterize the Raphanus fragment.


Another aspect of the invention is to provide a method of characterizing a plant genome having a Raphanus fragment comprising an Ogura fertility restorer gene, comprising: (i) utilizing a sequence selected from the group consisting of SEQ ID NO:159 to SEQ ID NO:237 to screen the plant genome; and (ii) characterizing the Raphanus fragment.


Another aspect of the invention is to provide a combination of markers/primers for characterizing the Raphanus fragment comprising a marker selected from the group SEQ ID NOS: 159 to 237.


Another aspect of the invention is to provide a kit for characterizing the Raphanus fragment comprising a primer selected from the group consisting of SEQ ID NOS: 1 to 158. The kit can further comprise marker information.


Another aspect of the invention is to provide a Brassica plant comprising the recombination event of R1439, R1815 or R1931.





BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described in relation to the figures in which:



FIG. 1 illustrates the improvements made in (i) the original (NW3002), (ii) first phase recombinant (NW1717) and (iii) new second phase recombinant Brassica Ogura restorer lines with shortened Raphanus fragment (SRF).



FIG. 2 shows molecular markers lost in mutant lines R1, R2 and R5, and SRF lines R1439, R1815 and R1931, compared to the first phase recombinant Raphanus fragment in NW1717 and the original line, NW3002



FIG. 3 shows a crossing diagram for Shortened Raphanus Fragment (SRF) development.



FIG. 4 shows a cartoon depicting a general method for shortening an exotic insertion.





DEFINITIONS

CMS: Means cytoplasmic male sterility and is a type of male sterility useful in hybrid seed production.


Contig: Is a contiguous sequence of DNA created by assembling overlapping sequenced fragments of a chromosome. A contig is also a group of clones representing overlapping regions of the genome. The term contig can also be used to denote a chromosome map showing the locations of those regions of a chromosome where contiguous DNA segments overlap. Contig maps are important because they provide the ability to study a complete, and often large, segment of the genome by examining a series of overlapping clones which then provide an unbroken succession of information about that region such as physical size and orientation.


Maintainer line (also known as B-line): A maintainer line is a line that carries native cytoplasm (i.e. non CMS) and the same nuclear genetics as a cytoplasmic male sterile (CMS) line. When crossed to the CMS line it “maintains” the sterility of the progenies of the CMS line. Accordingly, it has essentially the same nuclear genetic information as the CMS line, but is not male sterile. The maintainer line is a fertile plant and it can produce its own fertile progenies.


Original restorer lines (also known as original Brassica Ogura restorer lines): These lines are the original Brassica Ogura restorer lines, and carry the high glucosinolate trait when the restorer gene is present in the homozygous condition. Accordingly, these lines can not be commercialized or used in commercial seed production. An example of these lines is NW3002 as shown in FIG. 1.


First phase recombinant restorer lines or germplasm (also known as first phase recombinant Brassica Ogura restorer lines or germplasm): These lines contain a smaller Raphanus fragment than the original restorer lines based on marker measurement. These lines do not carry the high glucosinolate trait when the restorer gene is in the homozygous condition. Accordingly, these lines are used commercially. An example of these lines is disclosed in Charne, et al., (1998) WO 98/27806 “Oilseed Brassica Containing an improved fertility restorer gene for Ogura cytoplasmic male sterility.” A further example is NW1717 as shown in FIG. 1. The first phase recombinant restorer lines can be differentiated from the second phase recombinant restorer lines with shortened Raphanus fragment by the presence of many markers for example (i) the OPC2 marker as shown in FIG. 1 and (ii) the RMC24 to RMC33 inclusive and RMA01 to RMA10 inclusive markers shown in FIG. 2.


Deletion mutant lines (Rf̂): These lines contain a mutated Raphanus fragment, in which the Raphanus restorer gene and other Raphanus genes on the fragment have been deleted. For the purposes of the applicant's teaching, these lines are designated Rf̂. When the mutated Raphanus fragment (minus the restorer gene) is in the homozygous condition, the mutant lines are designated Rf̂Rf̂ and the lines are sterile when their cytoplasm is Ogura CMS. When the mutated Raphanus fragment is in the heterozygous condition, the lines are designated Rf̂Rf or Rf̂rf, as is known to those skilled in the art. For example, Rf̂Rf signifies that one allele comprises the mutated Raphanus fragment (minus the restorer gene), and the other allele comprises the first phase recombinant Raphanus fragment (with the restorer gene). In the case of Rf̂Rf, the lines are fertile when their cytoplasm is Ogura CMS. Rf̂rf signifies that one allele comprises the mutated Raphanus fragment (minus the restorer gene), and the other allele does not contain the Raphanus fragment at all. In the case of Rf̂rf, the lines are sterile when their cytoplasm is Ogura CMS. These mutant lines were used to generate the lines with the shortened Raphanus fragment (SRF), comprising the restorer gene (see below).


Second phase recombinant restorer lines or germplasm (also known as second phase recombinant Brassica Ogura restorer lines, second phase recombinant Brassica Ogura restorer lines with shortened Raphanus fragment (SRF) or Rf*): These lines contain approximately half of the Raphanus fragment (as estimated by number of markers lost) found in first phase recombinant restorer lines, and include the Raphanus restorer gene. Examples of these lines include R1439, R1815 and R1931 of the present invention, as shown in FIG. 1. For the purposes of the applicant's teaching, these lines are designated Rf*. When the SRF is in the homozygous condition, the lines are designated Rf*Rf*. When the SRF is in the heterozygous condition, the lines are designated Rf*Rf or Rf*rf, wherein Rf*Rf designates a line comprising one allele having a SRF and the other allele having the Raphanus fragment from the first phase recombinant lines, and Rfrf designates a line comprising one allele having a SRF and the other allele not comprising a Raphanus fragment at all. All of these SRF lines, whether Rf*Rf*, Rf*Rf or Rf*rf, are fertile when their cytoplasm is Ogura CMS.


DESCRIPTION OF THE VARIOUS EMBODIMENTS

The original Brassica Ogura restorer lines were developed by INRA by transferring the Ogura restorer gene from Raphanus sativa to Brassica napus (Pelletier, et al., (1987) “Molecular, Phenotypic and Genetic Characterization of Mitochondrial Recombinants in Rapeseed.” Proc. 7th Int Rapeseed Conf., Poznau, Poland 113-118). These lines included the gene or genes that conferred the high glucosinolate trait. In FIG. 1 these original lines are exemplified by NW3002.


The first phase recombinant Brassica Ogura restorer lines were developed by various institutions, among them the Applicant. The first phase recombinant restorer lines eliminated the gene or genes that confer the high glucosinolate trait. In FIG. 1, these first phase recombinant restorer lines are exemplified by NW1717. However, the first phase recombinant restorer lines still carry a substantial amount of the Raphanus genome (FIG. 1). Further, some lines can be associated with undesirable agronomic characteristics. These undesirable traits may result from the genes within the remaining Raphanus fragment or from the elimination/disruption of the genes on the Brassica chromosome.


The present teaching concerns second phase recombinant Brassica Ogura restorer lines with a shortened Raphanus fragment (SRF). The second phase recombinant Brassica Ogura restorer lines were developed by (i) preparing a physical map using bacterial artificial chromosome (BAC) contigs for the Raphanus fragment in the first phase recombinant restorer lines, (data not shown), (ii) mapping the Raphanus fragment with high density markers in the first phase recombinant restorer lines, (iii) producing knock-out mutant populations of first phase recombinant Brassica Ogura restorer lines, (iv) screening the knock-out mutant populations and identifying mutant lines with various deletions of the first phase recombinant Raphanus fragment including Ogura restorer gene, (v) crossing the mutant lines with first phase recombinant restorer lines to provide the opportunity for recombination at the Raphanus locus and produce second phase recombinant restorer lines with a shortened Raphanus fragment (SRF), (vi) identifying new recombinations in lines having the Ogura restorer gene with a shortened Raphanus fragment (SRF), (vii) characterizing the second phase recombinant restorer lines with a shortened Raphanus fragment (SRF), (viii) testing the second phase recombinant restorer lines with SRF for better fertility, embryogenesis and agronomy, and (ix) crossing the new second phase recombinant restorer lines with additional lines to produce commercial lines.


The following Examples are presented as specific illustrations of the present invention. It should be understood, however, that the invention is not limited to the specific details set forth in the Examples.


Example 1
Preparing High Density Marker Map of the Raphanus Fragment in the First Phase Recombinant Brassica Ogura Restorer Line, NW1717


FIG. 2 shows high density markers on the first phase recombinant Brassica Ogura restorer line, NW1717. The marker specificity was investigated with a set of pedigree lines, 6 restorer lines and 6 non restorer lines. Only some of the markers that are specific to the Ogura restorer were used to screen the knock-out mutant populations and later the SRF materials of the present invention (see below). The markers are coded and their specifications are listed in Table 1a. The sequence information for the markers is provided in Table 1b.


Table 1a contains key marker information. Columns 1, 2, 3, 11 and 13 list the marker group, the marker name, the size of PCR band, forward primer sequence and reverse primer sequence, respectively. Columns 4 to 10 list the presence or absence of the markers in the first phase recombinant restorer NW1717, the deletion mutant lines R1, R2 and R5, and the SRF lines R1439, R1815 and R1931, respectively (as described in Examples 2-5 below). With the exception of Group IV, all markers are present on the Raphanus fragment in the first phase recombinant lines. These markers were used to characterize the original deletion mutants and the shortened Raphanus fragment lines (SRF lines) of the present invention.


A kit useful for characterizing the Raphanus fragment comprising the primers and/or markers is included within the scope of the invention. For example, a kit can include appropriate primers or probes for detecting marker loci associated with the Raphanus fragment and instructions in using the primers or probes for detecting the marker loci and correlating the loci with size of the Raphanus fragment present. The kits can further include materials for packaging the probes, primers or instructions, controls such as control amplification reactions that include probes, primers or template nucleic acids for amplifications, molecular size markers, or the like. The kits can also include markers, marker sequence information, physical sequential order information, and expected PCR band size.


Example 2
Producing Knock-Out Mutant Populations of the First Phase Recombinant Brassica Ogura Restorer Line, 00SNH09984

Seed from the F1 line, 00SNH09984, which comprises the CMS cytoplasm and is heterozygous (Rfrf) for the Ogura restorer gene, was irradiated in the KFKI Atomic Energy Research Institute (AERI), Hungary. Hybrid seed (i.e., wherein the Ogura restorer gene is in the heterozygous state) was chosen for mutagenesis (i.e., irradiation treatment) because hybrid seed has only one copy of the restorer gene (i.e., it is heterozygous for the restorer gene) and therefore there is a higher probability that the mutation of the restorer gene will produce a phenotypic mutant population than homozygous seed which has two identical copies of the restorer gene. In addition, it is more efficient to screen the MO mutagenized heterozygous population than a mutagenized homozygous population since knock-out mutants can be identified at the current generation (M0) in the heterozygous condition whereas mutants of homozygous seed would need to be identified at M1 or M2 generations if only one of the two gene copies was knocked out. Three groups of 500 g of seed were irradiated with the following dosages 30Gy, 60Gy, and 90Gy. Another 500 g untreated seeds served as control. All treatments were performed with the standard protocol as follows:


Seed mutagenesis was carried out at the Biological Irradiation Facility (BIF) of the Budapest Research Reactor (BRR) located in the Budapest Neutron Center (BNC) and operated by the KFKI Atomic Energy Research Institute (AERI). In general, for seed irradiation with fast neutrons the filter/absorber arrangement number 1A was used. The order of filters starting at the core towards the irradiation cavity was:

    • Internal:143.6 mm Al+18 mm Pb+15 mm Al
    • External inside the borated water collimator: no external filter in front of the sample
    • Beam stop behind the sample: 30 mm Fe+45 mm Pb+8 mm Al+20 mm B4C


The samples were irradiated inside a Cd capsule with a wall thickness of 2 mm. The irradiation temperature was less than 30° C., at normal air pressure and the humidity was less than 60%. The samples were rotated at 16 revolutions/minute. The samples were usually re-packed to avoid surface contamination and the activation of the original holder/bag. The nominal neutron dose rate (water kerma˜absorbed dose in water) at 10.2 MW was 6.93 mGy/s.


During the irradiation there was a real time dose monitoring and the irradiation was terminated when the required dose was delivered.


Example 3
Screening Knock-Out Mutant Populations for Deletions in the Raphanus Fragment

Treated seed and the untreated control were planted in a one acre licensed field in Canada, in May 2001 as described in Table 2. “PNT” refers to “Plant with Novel Trait”. In addition, the corresponding maintainer B line, 96DHS-60, was planted twice as a control, as shown in the planting map as described in Table 3.









TABLE 2





Details of the mutagenized seed in the field trial


















Crop and recipient line

Brassica napus




Purpose of trial
Screening male sterile mutant



Containment method
200 meter isolation



Location of trials
Ontario, Canada



Number of PNT plots/site
4,000 rows, about one acre



Number of plants/site
250,000 seeds Approx.



Proposed harvest dates
September 2001



Treatments during growing season
None

















TABLE 3







Planting map of mutagenized seed field trial













Planting



Row
Material
Date















40.00 m
1.45 m
1 × 4
1st planting B line (96DHS-60)
9-May-01



8.70 m
6 × 4
rm-30 Gy (00SNH09984-30 Gy)
9-May-01



8.70 m
6 × 4
rm-60 Gy (00SNH09984-60 Gy)
9-May-01



8.70 m
6 × 4
rm-90 Gy (00SNH09984-90 Gy)
9-May-01



1.45 m
1 × 4
1st planting B line (96DHS-60)
9-May-01



1.45 m
1 × 4
2nd planting B line (96DHS-60)
18-May-01



1.45 m

Pathway



2.90 m
2 × 4
control (untreated 00SNH09984)
9-May-01









100.00 m










An estimate of the total number of plants was calculated by sample counting. At flowering, the plants were observed and sterile plants were identified visually. 1415 sterile plants were identified in the treated populations as summarized in Table 4. 104 sterile plants were also observed in the control (which probably resulted from seed impurity), which represents 0.52% of the total control plants, lower than the treated seeds in which up to 0.95% of the plants were sterile. A sterile plant from the mutagenized population could indicate that a mutation occurred on the Raphanus fragment such that the restorer gene was deleted or mutated. The sterile plants were labeled and all open flowers were removed. The remaining buds were bagged to ensure no stray pollen could pollinate them. In addition, all fertile plants around the identified sterile mutant plant were destroyed. Young leaves and tissues were collected from all sterile plants. The sterile mutants were pollinated with pollen from the B-line. Seed from the mutant plants was harvested.









TABLE 4







Results of seed mutagenesis screening











Treatment
30 Gy
60 Gy
90 Gy
Control














Total Plant
64,307
61,713
45,029
19,989


Sterile Plant
614
558
243
104


Sterile/total (%)
0.95
0.90
0.54
0.52









Example 4
Identifying Mutants with Various Deletions in the Raphanus Fragment of the First Phase Recombinant Raphanus Line

The leaf samples from the sterile plants identified as mutants in the field were lyophilized and ground. Genomic DNA was extracted. Methods of DNA extraction are known to those skilled in the art.


The 1415 mutant samples were characterized by performing PCR with a set of representative markers and characterizing which markers were retained and which were lost. The markers consisted of 6 PCR markers. One marker (OPC2) is known to those skilled in the art, while the other 5 markers (RMA07, RMB04, RMB12, RMC32 and RME08) are described here. Each of 6 markers represents a different region of the genomic fragment from the first phase recombinant Raphanus lines. All markers are located within the Raphanus fragment of the first phase recombinant Raphanus lines, except RME08, which is located in the napus genome adjacent to the Raphanus fragment. Those samples that retained at least one of the Rf markers were kept for further analysis, eliminating false sterile mutants (A-line contamination in hybrid seed). Based on the PCR results, 111 of the 1415 samples were positive for at least one marker. The M1 (second generation mutant) seeds of these 111 sterile plants (crossed with B line) were planted in the greenhouse and the sterility phenotype was confirmed. Leaf tissues were collected and analyzed by PCR using the 6 markers. Using the combination of the PCR results and phenotype data, seven restorer mutants were identified. Three mutant lines, designated Deletion Mutant R1, Deletion Mutant R2 and Deletion Mutant R5 were analyzed further using additional markers and carried forward.



FIG. 2 shows the characterization of the original mutant lines, designated Deletion Mutant R1, Deletion Mutant R2 and Deletion Mutant R5 in comparison to the first phase recombinant restorer line, NW1717. FIG. 2 lists the markers lost on the mutant lines compared to the markers on the NW1717. As can be seen, significant deletions have occurred in the original mutant lines, including deletion of Group II which comprises the restorer gene (Rf). As these plants are heterozygous for the mutated Raphanus fragment, they are designated Rf̂rf. These mutant lines (which lost the restorer gene) were crossed with first phase recombinant restorer lines to provide various materials for producing new recombinants as described in Example 5. The new recombinants were used to develop second phase recombinant restorer lines with SRF which included the restorer gene.


Example 5
Crossing of Mutant R1, Mutant R2 and Mutant R5 Lines with First Phase Recombinant Restorer Lines to Enhance the Probability of Recombination of the Mutated Raphanus Fragment

The crossing program is detailed below and all pedigree lines are summarized in Table 5 and FIG. 3. In the column entitled generation, “M” refers to mutant, “F” refers to offspring or “filial generation”, “F1” refers to first filial generation (heterozygous), “F2” refers to the second filial generation (segregating), “BC” refers to backcross, “DHS” refers to double haploid seed, and “S” refers to self pollinated seed. Each of 5 representative markers has a different purpose. RMA07, RMB12 and OPC2 represent the marker Group I, II and III, respectively. Y5N is a proprietary marker that targets the non-Rf genome. The CMS marker is also proprietary and confirms the presence of Ogura CMS cytoplasm.

    • (i) October 2001: As discussed above, the sterile mutants (Rf̂rf) were pollinated with a maintainer line (rfrf), 96DHS60, to produce seeds that were Rf̂rf or rfrf in a Ogura CMS cytoplasm. On Table 5 these are designated Rf̂1rf, Rf̂2rf, and Rf̂5rf to distinguish each of the three mutants, R1, R2 and R5. This is shown in generation M1 F1 of Table 5.
    • (ii) 2002: M1 F1 seeds (Rf̂rf/rfrf) from the three identified mutant lines (Mutant R1, Mutant R2 and Mutant R5) were sown in the greenhouse. Rf̂rf plants were identified by screening using selected markers (i.e., RMA01-10 for R2 and R5; RMC01-33 for R1 and R2) and pollinated with first phase (wild-type) recombinant restorer line (RfRf) to produce seeds having genotypes of Rf̂Rf and rfRf in CMS cytoplasm. This was done for two reasons: (a) to obtain fertile fixed mutant genotypes with normal cytoplasm after further crossing (shown below), and (b) to dilute the mutant dosage (each crossing diluted by 50%). Once the Rf̂rf plants were crossed with the wild-type (the first phase recombinant restorer line), all progenies (Rf̂Rf and rfRf) were fertile. This is shown in generation M2F1 of Table 5. An rf-specific marker, Y5N, was used to screen the fertile progenies and to eliminate plants with rfRf genotype. Then the B-line 96DHS60 plants (rfrf) were pollinated with Rf̂Rf plants. For every crossing two female plants (in case of each of the 3 mutants) and two male plants (first phase recombinant restorer line, NS4304MC) were used and their seeds were bulked with approximately 200 seeds per bulk. All crossings were done under normal growth room conditions for canola: 16 hour light at 22° C. and 8 hour dark at 18° C. This is shown in generation M3F1 of Table 5.


      Producing homozygous Rf̂Rf̂lines in a normal (non-cms) cytoplasm:
    • (iii) As stated above, in 2002, plants grown from the Rf̂Rf/rfRf seed were identified by using the rf-specific marker to eliminate rfRf plants. The Rf̂Rf plants were crossed to the maintainer line rfrf (as a female) to convert the CMS cytoplasm to a napus cytoplasm and produce Rf̂rf and Rfrf genotypes in a fertile (non CMS) background. The purpose of converting the background from CMS to non-CMS was to enable self-pollination and develop fixed Rf̂Rf̂ plants. This is shown in generation M3F1 of Table 5.
    • (iv) In 2003, plants grown from the Rf̂rf seed with napus cytoplasm were self-pollinated to produce Rf̂Rf̂, Rf̂rf and rfrf seeds. The pollinations were carried out as stated above. This is shown in generation M3F2 of Table 5.


      Crossing Rf̂Rf̂lines with RfRf lines:


The purpose of these crosses was to provide an enhanced probability of abnormal recombination (also referred to as crossover distortion) between the deleted Raphanus fragment of the mutant Rf̂ lines and the first phase recombinant Raphanus fragment of the Rf lines.

    • (v) In 2003, the plants grown from the Rf̂Rf̂ seed with napus cytoplasm were crossed to the first phase recombinant RfRf restorer line (as female), NS4304MC, to produce 100% fertile Rf̂Rf seed with Ogura CMS cytoplasm. This 2-way cross would align Rf̂ and Rf chromosomes in a cell and provide the possibility that abnormal chromosomal crossover (also called crossover distortion) would occur at the Raphanus fragment locus and recombine the Raphanus fragment. Progenies with a shortened Raphanus fragment that contained the restorer gene could be identified using high density markers within the Raphanus fragment. This is shown in generation M4F1 of Table 5 and FIG. 3.
    • (vi) In 2004, the Rf̂Rf lines from step (v) were crossed to a female CMS line (rfrf), NS2173FC, to produce large populations of Rf̂rf and Rfrf in a CMS background. This novel three-way cross (F1 crossing to an unrelated A-line) had superior advantages over F1 self-pollination (F2 population) to generate new recombinations while the Rf̂Rf plant is undergoing meiosis. Without being limited to any particular theory, this 3-way cross eliminated the Rf and Rf̂ Raphanus chromosome interference in identifying the progenies having a newly recombined Raphanus fragment, leading to a greater probability of identifying a new shortened Raphanus fragment comprising the restorer gene. Our results indicated that by using this approach a recombination rate of approximately 0.1% (1 of 1,000) had occurred. As shown in Table 6, if the same recombination rate occurs in F1 self-pollinated population, 1 of 1,000,000 progenies would be homozygous for new Raphanus recombination and could be identified by marker profiling, providing that the male and female gametes have the same recombination locus. If the male and female gametes have different recombination loci, it would be nearly impossible to identify any shortened Raphanus recombination in F2 population. If the F3 population is used for screening, the population would be excessively large to analyze, in the order of multi-million plants.


Three large populations, approximately 4,000 seeds each, were produced from each of the three mutant lines, Mutant R1, Mutant R2 and Mutant R5. Theoretically, only the Rfrf progenies would be fertile. Rf̂rf plants are sterile and would be discarded. All fertile plants, approximately 2,000 each of three populations, were screened with a set of PCR markers. If crossover or recombination occurred then a few fertile plants would lose some markers but still retain the restorer gene. These plants were identified as Rf*rf with shortened Raphanus fragment. This is shown in generation M5F1 of Table 5 and FIG. 3.









TABLE 6







Efficiency comparison between a novel 3-way cross and self-pollination








Novel 3-way cross (rfrf × RfRf/Rf{circumflex over ( )}Rf{circumflex over ( )})











Male gamete
Conventional self-pollination (RfRf/Rf{circumflex over ( )}Rf{circumflex over ( )}-> F2)











Rf
Rf{circumflex over ( )}
Male gamete














(50%)
(50%)
Rf* (0.1%)
Rf (50%)
Rf{circumflex over ( )}(50%)
Rf* (0.1%)




















Female
rf
50%
50%
0.1% Rf*rf
Female gamete
Rf (50%)
25% RfRf
25% RfRf{circumflex over ( )}
0.05% RfRf*


gamete
(100%)
Rfrf
Rf{circumflex over ( )}rf
fertile


fertile
fertile
fertile




fertile
sterile








Rf{circumflex over ( )}(50%)
25% RfRf{circumflex over ( )}
25% Rf{circumflex over ( )}Rf{circumflex over ( )}
0.05% Rf{circumflex over ( )}Rf*









fertile
sterile
fertile








Rf* (0.1%)
0.05%
0.05%
0.0001%









RfRf*
Rf{circumflex over ( )}Rf*
Rf*Rf*









fertile
fertile
fertile









Efficiency
Fertile progenies (50% population) need
Fertile progenies (75% population) need screening;



screening;
Frequency to identify Rf*Rf* is 1 of 1,000,000.



Frequency to identify Rf*rf is 1 of 1,000.











    • (vii) In 2004, approximately 6,000 rfRf plants were screened with multiple PCR markers. Three second phase recombinant restorer lines with a shortened Raphanus fragment, designated R1439, R1815 and R1931, were identified with up to 50% loss of the Raphanus fragment compared to the first phase recombinant restorer material, NW1717 (see detail marker profile in FIG. 2). R1815 originated from Mutant R2 crossing population, and R1439 and R1931 originated from Mutant R5 crossing population. These plants comprise a new recombination event, designated R1439, R1815 and R1931 respectively.

    • (viii) In 2005, and 2006 the three lines were fixed by breeding and doubled haploid production, and designated R1439, R1815 and R1931. This is shown in generations M6F2 and M6DHS1 of Table 5.

    • (ix) 2005 and 2006 the three SRF lines were also backcrossed 5 times to produce BC0, BC1, BC2, BC3, and BC4 lines. Each backcrossing used four plants of NS1822FC as female and 4 plants of each Rf*rf genotype (i.e., R1439, R1815 and R1931) as male. The seeds were bulked and planted immediately to produce Rf*rf and rfrf plants. The sterile rfrf plants were discarded and only fertile Rf*rf were carried forward to the next generation of backcrossing. In addition to backcrossing, BC2 and BC4 plants were self-pollinated to produce BC2S1 (F2) and BC4S1 (F2) seeds. Then BC2S1 and BC4S1 plants were self-pollinated to produce fixed BC2S2 (F3) and BC4S2 (F3) as breeding material. This is shown in generations M7BC0 to BC4S2 of Table 5, inclusive.





Example 6
Characterization of Second Phase Recombinant SRF Lines

Table 7 compares the deletions in the Raphanus fragment of the second phase recombinant restorer lines with the Raphanus fragment in the first phase recombinant restorer line, NW1717. The Raphanus fragment in the second phase recombinant restorer lines is estimated to be about 36% to 49% shorter than the Raphanus fragment in the first phase recombinant restorer line, NW1717. This estimation is based on number of markers deleted. For example, in SRF line R1815, 21 of the 59 markers have been lost. Based on the number of markers lost (21/59), approximately 36% of the Raphanus fragment has been deleted (64% of the Raphanus fragment remains). In the case of SRF line R1439, 29 out of 59 markers have been lost. Based on the number of markers lost (29/59), approximately 49% of the Raphanus fragment has been deleted (approximately 51% remains). FIG. 2 shows the markers that have been deleted and the markers that remain in the SRF lines/recombination events, R1439, R1815 and R1931. Physical maps (not in scale) of the SRF lines are found in FIG. 2.









TABLE 7







Remaining Raphanus Fragment in SRF Lines










SRF Lines













R1439
R1815
R1931
NW1717

















% of NW1717*
~51%
~64%
~53%
100%



Marker Loss/
29/59
21/59
28/59
0/59



Total Rf Marker







*estimated by number of markers lost






The SRF lines are more similar to NW1717 than to the deletion mutants R1, R2 and R5 because they include the Raphanus restorer gene. The deletion mutants R1, R2 and R5 were lacking the Ogura restorer and were quite different than NW1717. The main function of the deletion mutants was to cause crossover distortion and break down the Raphanus fragment in NW1717 to generate the SRF lines. The SRF lines retain fewer undesirable radish genes and are expected to have better agronomic performance.


The third row of Table 7 summarizes the number of markers lost for each line. There are 59 markers on the first phase recombinant restorer line, NW1717. The number of markers lost in the second phase recombinant lines ranges from 21 to 29. The SRF lines contain the restorer gene and they have been tested to confirm that they restore male fertility of Ogura CMS lines.



FIG. 1 shows the relationship between the original Brassica napus line in which the Ogura restorer fragment was introgressed (NW3002), the first phase recombinant commercial line (NW1717) and the second phase recombinant restorer line with a shortened Raphanus fragment (SRF lines). As can be seen, significant deletions have occurred on the Raphanus fragment. The original lines (represented here by NW3002) contained the restorer locus and the high glucosinolate locus. The first phase recombinant restorer lines which were used commercially (represented by NW1717) contain much smaller Raphanus fragment than NW3002. The high glucosinolate locus was deleted in the first phase recombinant restorer lines. The second phase recombinant restorer lines contain much shorter Raphanus fragment than NW1717, but still retain the restorer gene. The second phase recombinant restorer lines have better agronomic performance, as will be discussed below. The OPC2 and E38M60 markers can clearly distinguish between the first phase recombinant and the second phase recombinant Raphanus fragments. The E38M60 marker is found in NW1717 and in the second phase recombinant restorer lines. The OPC2 marker is found in NW1717, but not in the second phase recombinant restorer lines. Additional markers as shown on FIG. 2 can be used to distinguish the three SRF lines from first phase recombinant lines and from each other. For example, the set of the markers, RMC09 to RMC23 inclusive, can distinguish the three SRF lines from each other. R1439 has lost the DNA sequences which contain many of the markers of Group III and all of the markers of Group I. It is flanked by RMB01 and RMC23, but lacks RMC09 to RMC16 inclusive. R1815 has lost the DNA sequences which contain the markers from RMC24 to RMC33 and all the markers of Group I. It is flanked by RMB01 and RMC23. Finally, R1931 has lost the DNA sequences which contain the markers of Group I and markers RMC17 to RMC23 of Group III. It is flanked by RMB01 and RMC16.


A comparison of the second phase recombinant Brassica Ogura restorer lines of the present invention with competitors' lines (INRA R2000, INRA R211 and INRA R113) is shown in Table 8. The new recombined restorer lines produced by the novel breeding method disclosed here have a shorter Raphanus fragment than the Raphanus fragment of the competitors' lines. The novel breeding method disclosed here which produced these lines proved to be very successful.









TABLE 8







Key Rf Marker Profiling among Selected Ogura Restorer Materials
















Marker











Group
Rf Marker
SRF-R1439
SRF-R1815
SRF-R1931
NW1717
R2000-INRA
R211-INRA
R113-INRA
NW3002 (R40)





I
RMA01



+
+
+
+
+



RMA02



+
+
+
+
+



RMA08



+
+
+
+
+



RMA10



+
+
+
+
+


II
RMB01
+
+
+
+
+
+
+
+



E35M62
+
+
+
+
+
+
+
+



RMB02
+
+
+
+
+
+
+
+



RMB04
+
+
+
+
+
+
+
+



RMB08
+
+
+
+
+
+
+
+



RMB10
+
+
+
+
+
+
+
+



OPF10
+
+
+
+
+
+
+
+



RMB12
+
+
+
+
+
+
+
+


III
RMC01
+
+
+
+
+
+
+
+



RMC02
+
+
+
+
+
+
+
+



E38M60
+
+
+
+
+
+
+
+



RMC08
+
+
+
+
+
+
+
+



RMC09

+
+
+
+
+
+
+



RMC11

+
+
+
+
+
+
+



RMC15

+
+
+
+
+
+
+



RMC16

+
+
+
+
+
+
+



RMC17
+
+

+
+
+
+
+



RMC19
+
+

+
+
+
+
+



RMC21
+
+

+
+
+
+
+



RMC23
+
+

+
+
+
+
+



RMC24



+
+
+
+
+



OPC2



+
+
+
+
+



RMC25



+
+
+
+
+



RMC27



+
+
+
+
+



RMC29



+
+
+
+
+



RMC31



+
+
+
+
+



RMC32



+
+
+
+
+


IV
E33M47




+
+
+
+



E32M50




+
+
+
+



OPN20




+
+
+
+



OPH15




+
+
+
+



IN6RS4




+
+
+
+



E33M58




+
+
+
+



E32M59A






+
+



E32M59B






+
+



OPH03







+









The novel breeding method taught here can be used for purposes other than reducing the size of the Raphanus fragment. It can be used whenever an exotic insertion comprising a gene or genes of interest has been introduced into a germplasm and one wishes to reduce the size of the exotic insertion, but preserve the gene or genes of interest. Moreover, the new breeding method is not limited to Brassica species, but can be used for any species, including wheat, corn, soybean, alfalfa, and other plants. In many circumstances a breeder may find it useful to introduce exotic insertions into elite germplasm using techniques as is known to those skilled in the art. For example, the exotic insertion can be introduced by crossing, transformation of artificial chromosomes, nucleus injection, protoplast fusion, and other methods as is known to those skilled in the art. For example, insect and disease resistance genes are often transferred via wide crosses to elite plant germplasm. In addition, agronomic traits such as drought resistance, heat tolerance, shattering and grain quality (seed composition) have also been transferred by interspecific crosses.


However, in most cases the breeder will discover that together with the gene or genes of interest, “superfluous” genetic material is introduced that affects other traits. Essentially, there are two problems with the superfluous genetic material. First, the superfluous genetic material may carry undesirable genes. For example, the original Raphanus insertion included genes that conferred a high glucosinolate trait. Second, the superfluous genetic material may result in problems with meiosis because the chromosomes cannot align properly due to the exotic insertion. This may lead to fertility problems and less agronomic vigor, as was seen in the original Raphanus material. Accordingly, once breeders have introduced exotic insertions into elite germplasm, they then tend to spend years “chipping away” at it to reduce its size, while screening for the gene or genes of interest. Traditionally, this has been done by continuous crossing to elite lines in the hopes that the exotic insertion will be reduced. The problem is, however, that there is no homologous sequence in the elite germplasm to recombine with the exotic insertion, and so this can be time consuming and not efficient.


The novel breeding method described here overcomes this problem by producing a line (i.e. a deletion mutant) which comprises the elite germplasm and the exotic insertion in which the gene or genes of interest have been deleted. This deletion mutant is crossed with the original germplasm containing the exotic insertion. Since the deletion mutant still contains part of the exotic insertion, it can align with the original insertion and induce genetic recombination. Essentially, the new breeding method provides a line which can easily recombine with the original exotic insertion. This new breeding method was described in detail in the examples with regard to reducing the Raphanus fragment, but as discussed above, it can be used for any situation in which an exotic insertion into an elite germplasm requires reduction in size. The novel breeding method is summarized by the following steps and shown as a cartoon in FIG. 4. For clarity, the exotic insertion is denoted “E”, the exotic deletion is denoted “EA”, the recombined shortened exotic insertion is denoted “E*”, and the null chromosome (i.e. without the exotic insertion) is denoted “e”:

    • (i) It is very useful to have an understanding of the exotic insertion and the region surrounding the exotic insertion. This can be done by a genetic map, sequence information, a molecular marker map, and/or other methods as is known to those skilled in the art, of the genomic region surrounding and including the exotic insertion. A high density marker map will facilitate the identification of a shorter recombined exotic insertion.
    • (ii) The next step is to produce deletion mutants preferably in heterozygous lines, wherein the lines are heterozygous for the exotic insertion (Ee)→(Êe). Deletion mutants are mutants in which the gene or genes of interest are deleted from the genome, but some of the exotic insertion is still present. By using heterozygous lines, one can identify the deletion mutants more readily than using homozygous lines because the phenotype of the deletion mutants will not be masked by the homologous locus. The deletion mutants can be maintained, stabilized and reconfirmed by crossing with null lines (ee) one or more times.
    • (iii) The next step is to cross the deletion mutants (Êe) with lines that are homozygous for the exotic insertion (EE) to produce (ÊE) and (eE) seed, and subsequently identifying those lines that contain the deletion (ÊE). The identification of (ÊE) can be done by screening the genome using markers identified in step (i). For example, the markers can be specific to the null lines (ee). Alternatively, one can self ÊE and eE and use the progeny segregation to identify ÊE plants in which no ee genotype can be present in their progenies. Optionally, the Êe deletion mutants are first self-pollinated (assuming a trait other than fertility) and ÊÊ plants are selected and crossed with EE, so that all offspring are ÊE.
    • (iv) Optionally, the (ÊE) plants are increased to obtain sufficient numbers for pollination purposes. This can be done by (a) self pollination of (ÊE) to produce (ÊÊ), (ÊE) and (EE) seed, followed by (b) cross pollination of (ÊÊ) with (EE) to produce many (ÊE) plants. In the present invention, this step was done to change the cytoplasm from CMS to normal cytoplasm. If this step is not required, one can move on to Step (v) directly since theoretically only one (ÊE) plant is required.
    • (v) The next step is to cross (ÊE) with a null line (ee) to create a large F1 population, up to thousands of seeds. During meiosis the exotic insertion in the (ÊE) line undergoes recombination, such that at least some gametes comprise a recombined exotic insertion which includes the gene or genes of interest, but is significantly shorter than E. The shorter recombined exotic insertion is denoted E*. The recombination rate will depend on the plant species, the size of the exotic insertion, the size and character of the deletion mutant, and other factors. The recombination rate for the Raphanus fragment was found to be approximately 0.1%. The progenies (Êe), (Ee) and (E*e) are screened with molecular markers to identify exotic insertions that have recombined (E*e). By serial backcrossing with a null line (ee), the phenotype of E* is expressed. The phenotype can be verified with measurements depending on the genes or traits of interest. Although not being limited to any theory, a high degree of homology between the exotic insertion and the deletion mutant may lead to a greater probability of crossing over.


By following this new breeding method, a skilled worker can reduce the size of an exotic insertion while maintaining the gene of interest. This can be done with any species and with any exotic insertion as discussed above.


Further, this method can be repeated until the exotic insertion is deleted to an acceptable length. For example, lines containing the shortened fragment (E*E*) can be crossed with the deletion mutants (ÊÊ) to produce PEA lines. These lines can then be crossed with null lines (ee) lines to allow recombination of the exotic insertion. The progeny (E*e, Êe and E**e) can be screened for further reduction of the exotic fragment. E** denotes a further reduction in the exotic fragment which retains the gene or genes of interest.


Example 7
Continued Backcrossing with Maintainer Line to Produce BC2, BC3, BC4, BC2S2 and BC4S2 Generations, and Convert SRF Lines to Breeding Materials with Normal Maintainer and Restorer Background

All backcrossing and self-pollination were done in the greenhouse under the same conditions mentioned above. BC1 seeds were planted and showed normal genetic segregation. Because of mixed genotype (Rf*rf/rfrf), 50% of the BC1 plants were fertile and other 50% plants were sterile. Four fertile BC1 plants (Rf*rf) were selected as male and crossed to a female line (male sterile A-line) NS1822FC, that has the same nucleus as the maintainer line but with a male sterile cytoplasm to produce BC2 seeds. The bulked BC2 seeds were advanced the same way to produce BC3 and BC4 seeds. Each generation of backcrossing showed normal fertility segregation, 50% fertile and 50% sterile (Table 10). The selected fertile BC2 and BC4 plants, Rf*rf, were self-pollinated to generate BC2S1 and BC4S1 (F2) seeds, respectively. BC2S1 and BC4S1 seeds were planted and segregation was observed (Table 11). The homozygous BC2S1 and BC4S1 plants were identified and self-pollinated to produce fixed BC2S2 and BC4S2 seeds. Table 5 lists a summary of the pedigree lines leading to the SRF lines. This is shown in generations M6F2 to BC4S2 of Table 5, inclusive. The result of the breeding was the development of three new lines with a homozygous locus comprising a shortened Raphanus fragment (Rf1439Rf1439, Rf1815Rf1815 and Rf1931RF1931.) Table 9 is a summary of the chronological events leading to the development of the SRF restorer lines.









TABLE 9







Chronological Events Leading to Rf Lines with Shortened Raphanus Fragment (SRF)









Year
Activity
Result





2000
Irradiated hybrid seeds in KFKI Atomic Energy Research
1.5 kg treated canola seeds



Institute (AERI), Hungary.


2001
planted treated seeds and untreated seeds in 1 acre
1215 sterile plants from treated population



permitted field


2001
DNA isolation and PCR screening with many Rf markers
3 Rf mutants (R1, R2 & R5) identified


2001
crossed with maintainer line
3 Rf mutant seeds (rfRf{circumflex over ( )}) with different marker loss


2002
crossed with wildtype restorer line
Rf{circumflex over ( )}Rf seed


2002
crossed Rf{circumflex over ( )} Rf to maintainer line to convert CMS to
fertile mutant plants (rfRf{circumflex over ( )})



normal cytoplasm


2003
selfing rfRf{circumflex over ( )} plant
fixed mutant progeny (Rf{circumflex over ( )}Rf{circumflex over ( )})


2003
crossed Rf{circumflex over ( )}Rf{circumflex over ( )} to wildtype restorer line
fertile F1 seed (RfRf{circumflex over ( )})


2004
crossed Rf{circumflex over ( )}Rf to female line
large population of F1 seeds (~4,000 each mutant)


2004
screened ~6,000 rfRf{circumflex over ( )}/rfRf plants with multiple Rf
3 SRF lines with various loss of Raphanus genome in NW1717



markers


2005
fixed 3 rfRf{circumflex over ( )} lines through breeding or DH
Rf{circumflex over ( )}Rf{circumflex over ( )} seeds


2005
Series backcrossing with maintainer line
BC0 and BC1


2006
continued backcrossing with maintainer line
BC2, BC3 and BC2S1


2006
continue characterization, expand evaluation and
BC2S2, BC4 and BC4S1



incorporate into breeding materials


2007
continue characterization, expand evaluation and
BC4S2 and integreting SRF lines into breeding program with elite



incorporate into breeding materials
genetic background


2007
Field test
agronomic data and quality data









Example 8
Preliminary Data for Improved Fertility Rates in SRF Lines Compared with First Phase Recombinant Lines

Preliminary results from greenhouse grown plants indicate that the SRF lines undergo normal Mendelian segregation of the restorer trait and are better able to restore fertility to Ogura CMS plants than the first phase restorer lines. Table 10 summarizes the backcrossing data from all backcross generations except BC2 in which the data was not collected. The SRF lines were backcrossed to CMS lines. Details of the experiments can be found above, specifically in Example 7. Backcrossed populations of SRF lines R1439, R1815 and R1931 resulted in fertile progenies of 47%, 45% and 52%, respectively. The data is very close to the theoretical number of 50%. Table 11 summarizes the BC4S1 (F2) segregation of three SRF lines with parallel comparison of the NW1717 source. R1439 and R1815 showed normal F2 segregation. That is, one quarter of the F2 progenies, rfrf, were sterile. Two quarters were heterozygous fertile, rfRf* and one quarter were homozygous fertile, Rf*Rf*. The exception was R1931 which showed higher heterozygous and lower homozygous fertile progenies than the theoretical rate.









TABLE 10







Summary of Backcrossing Data for SRF Lines











SRF

Total
Fertile Progeny
Sterile Progeny


















Line
Gen
Population
Recurrent
Donor
Plant
Plant
%
Genotype
Plant
%
Genotype





















R1439
BC0
05SM205
NS1822FC
rfRf1439
32
15
47
rfRf1439
17
53
rfrf



BC1
05SM235
NS1822FC
rfRf1439
32
17
53
rfRf1439
15
47
rfrf



BC3
06SM399
NS1822FC
rfRf1439
20
7
35
rfRf1439
13
65
rfrf



BC4
06SM414
NS1822FC
rfRf1439
20
10
50
rfRf1439
10
50
rfrf
















Total
104
49
47

55
53



















R1815
BC0
05SM208
NS1822FC
rfRf1815
32
14
44
rfRf1815
18
56
rfrf



BC1
05SM236
NS1822FC
rfRf1815
32
19
59
rfRf1815
13
41
rfrf



BC3
06SM400
NS1822FC
rfRf1815
20
8
40
rfRf1815
12
60
rfrf



BC4
06SM415
NS1822FC
rfRf1815
20
6
30
rfRf1815
14
70
rfrf
















Total
104
47
45

57
55



















R1931
BC0
05SM209
NS1822FC
rfRf1931
32
14
44
rfRf1931
18
56
rfrf



BC1
05SM237
NS1822FC
rfRf1931
32
20
63
rfRf1931
12
38
rfrf



BC3
06SM401
NS1822FC
rfRf1931
20
9
45
rfRf1931
11
55
rfrf



BC4
06SM416
NS1822FC
rfRf1931
20
11
55
rfRf1931
9
45
rfrf
















Total
104
54
52

50
48

















TABLE 11







Summary of BC4S1 (F2) Population Segregation for SRF Lines












Total
rfrf (Sterile)
rfRf* (Fertile)
Rf*Rf* (Fertile)

















Rf Source
Plant
Expected
Observed
%
Expected
Observed
%
Expected
Observed
%




















R1439
128
32
32
25%
64
69
54%
32
27
21%


R1815
127
32
34
25%
64
67
54%
32
26
20%


R1931
127
32
30
24%
64
90
71%
32
7
6%


NW1717
127
32
31
24%
64
72
57%
32
24
19%









Example 9
Preliminary Data for Embryogenesis Using the SRF Lines

F2 populations of three SRF lines were used as donor plants to fix SRF lines through double haploid (DH) production. The spring canola DH protocol used through microspore embryogenesis was detailed in Swanson, Eric B., Chapter 17, p. 159 in Methods in Molecular Biology, vol. 6, Plant Cell and Tissue Culture, Ed. Jeffrey W. Three F2 populations, 05SM194, 05SM197 and 05SM198, were grown in the greenhouse under normal canola growth conditions, 32 plants for each population. Upon flowering, 10 fertile plants were randomly selected as DH donor plants. Fertile plants had two genotypes: rfRf* and Rf*Rf*. The 10 donor plants were not genotyped with molecular markers but should, on average, consist of 3 Rf*Rf* plants (⅓) and 7 rfRf* plants (⅔). The buds from the 10 donor plants were bulked and used as initial microspore source for DH production. The DH progenies were grown in the same green house conditions until flowering. Their phenotype (fertility) was recorded and summarized in Table 12. The fertile progeny have the Rf*Rf* genotype and the sterile progeny have rfrf. A large difference was observed among three SRF lines. R1439 and R1931 had good embryogenesis in DH production, 47% and 38% fertile progenies, respectively, while R1815 had poor embryogenesis, about 1% fertile progenies.









TABLE 12







Summary of DH Fixing for SRF Lines











SRF
Donor Plant
Total
Fertile DH Progeny
Sterile DH Progeny

















Line
Generation
Population
Genotype
DH
Plant
%
Genotype
Plant
%
Genotype




















R1439
M6F2
05SM194
1/3 Rf1439Rf1439
89
42
47
Rf1439Rf1439
47
53
rfrf





2/3 rfRf1439


R1815
M6F2
05SM197
1/3 Rf1815Rf1815
114
1
1
Rf1815Rf1815
113
99
rfrf





2/3 rfRf1815


R1931
M6F2
05SM198
1/3 Rf1931Rf1931
116
44
38
Rf1931Rf1931
72
62
rfrf





2/3 rfRf1931









Example 10
First Year Data for Agronomic and Quality Traits of the SRF Line

In 2007, F3 progeny from three sets of seven crosses, each cross having respectively R1439, R1815 or R1931 as one of the SRF parents and a different breeding line or commercial variety as a second parent, were planted in a restorer breeding nursery at Belfountain, Ontario. The row numbers 1, 20, 40, 60, etc. were planted with 46A65—a commercial canola variety selected for quality purposes. Approximately 100 seeds of each F3 and 46A65 check were planted in rows 3 meters long and spaced 50 cm apart. At physiological maturity, the F3 lines in each cross were visually selected for superior vigor, uniformity, early maturity, and the selected lines were later harvested with 15 grams of open pollinated seed samples for quality analysis. Each quality check row was also harvested with the same amount of seed for quality comparison. Selection for oil, protein and total glucosinolates was performed by comparing each SRF line to the two nearest check rows on each side. The F3 lines having higher oil, higher protein and lower total glucosinolates than the two nearest checks were advanced in the breeding program. The results of quality analysis are summarized in Table 13. Based on the total average of all the harvested lines from seven crosses, the SRF lines had lower total glucosinolates than 46A65, the commercial check.









TABLE 13







Results of quality analysis on seed samples collected from 2007


breeding nursery involving F3 lines from three sets of crosses each involving an SRF


source.












No. of

Protein
Glucosinolate



Line
Oil Content (%)
Content (%)**
(umol/g)















or
Range

Range

Range


















SRF Line
Row
Low
High
Average
Low
High
Average
Low
High
Average




















R1439 Inbred
47
40.8
47.6
44.3
24.3
29.4
27.0
7.8
15.2
11.1


R1815 Inbred
47
41.8
46.7
44.4
25.1
29.8
27.2
7.2
14.3
10.2


R1931 Inbred
43
41.9
47.2
44.2
24.8
29.6
27.5
6.5
14.5
10.8


Check-46A65*
38
42.6
46.4
44.5
25.5
29.8
27.7
13.0
16.3
14.5





*OP (open-pollination) canola commercial variety developed by Pioneer.


**Protein content in whole seed.






Each of the three SRF sources was selected as a donor parent and a Pioneer proprietary non commercial breeding line NS1822BC was selected as recurrent parent to initiate three different backcross series. The BC2 plants were self-pollinated successively twice to produce BC2S2. Several BC2S2 homozygous plants for the restorer gene were identified by marker analysis and harvested in bulk within each series. The three BC2S2 bulks became the male parent in three hybrids involving a common OGU CMS inbred line from Pioneer. The three male lines used in producing these hybrids are expected to have 87.5% genetic similarity since they all are BC2 descendents


The hybrids were evaluated in an un-replicated incomplete block design experiment planted at seven locations in Western Canada. Two of these locations were lost due to poor weather. Data was collected from the remaining five locations. Each plot was planted with six meter long row spaced apart by 17 cm. Yield (q/ha), agronomic traits such as days to flower (50% of the plants in a row have at least one flower), days to mature (number of days from planting to the day when seed color changes from green to brown or black within the pods on bottom part (⅓) of raceme), early vigor (1=poor, 9=excellent), plant height (cm), resistance to lodging (1=poor; 9=excellent) and quality traits such as oil %, protein %, total glucosionolates and total saturated fatty acid were recorded (Table 14). The SRF based restorer produced competitive hybrids for all traits when compared to the commercial hybrid 45H26 which is based on NW1717 source.









TABLE 14







Agronomic and Quality Trait Data of the SRF-based Hybrids from 2007


Field Trial




















Days
Early

Plant







Yield
Days to
to
Vigor
Lodging
Height

Protein
Gluc
Total


SRF Line
q/ha
Mature
Flower
1-9
1-9
cm
Oil %
%**
umol/g
Saturate %




















R1439 Hybrid
19.09
89.9
46.2
7.7
6.1
126.8
51.8
45.5
10.2
6.93


R1815 Hybrid
20.49
89.7
46.0
7.5
6.5
126.4
51.2
46.7
13.1
6.77


R1931 Hybrid
20.56
89.5
46.1
7.3
6.6
114.8
51.8
45.1
12.5
7.02


Check-45H26*
20.14
89.7
45.8
7.1
6.8
129.1
50.8
45.7
11.1
7.05


# Environment
5
5
2
2
2
3
5
5
5
5





*NW1717 based hybrid canola commercial variety developed by Pioneer.


**Protein content in meal.






Percent oil is calculated as the weight of the oil divided by the weight of the seed at 0% moisture. The typical percentage by weight oil present in the mature whole dried seeds is determined by methods based on “AOCS Official Method Am 2-92 Oil content in Oilseeds”. Analysis by pulsed NMR “ISO 10565:1993 Oilseeds Simultaneous determination of oil and water—Pulsed NMR method” or by NIR (Near Infra Red spectroscopy) (Williams, (1975) “Application of Near Infrared Reflectance Spectroscopy to Analysis of Cereal Grains and Oilseeds”, Cereal Chem., 52:561-576, herein incorporated by reference) are acceptable methods and data may be used for Canadian registration as long as the instruments are calibrated and certified by Grain Research Laboratory of Canada. Other methods as known to those skilled in the art may also be used.


The typical percentage by weight of protein in the oil free meal of the mature whole dried seeds is determined by methods based on “AOCS Official Method Ba 4e-93 Combustion Method for the Determination of Crude Protein”. Protein can be analyzed using NIR (Near Infra Red spectroscopy), (Williams, (1975) “Application of Near Infrared Reflectance Spectroscopy to Analysis of Cereal Grains and Oilseeds’, Cereal Chem., 52:561-576, herein incorporated by reference). Data can be used for Canadian registration as long as the instruments are calibrated and certified by Grain Research Laboratory of Canada. Other methods known to those skilled in the art may also be used.


Glucosinolate content is expressed as micromoles per gram at 8.5% moisture. The total glucosinolates of seed at 8.5% moisture is measured by using methods based on “AOCS Official Method AK-1-92 (93) (Determination of glucosinolates content in rapeseed-colza by HPLC)”; herein incorporated by reference. NIR data can be used for Canadian registration as long as the instruments are calibrated and certified by Grain Research Laboratory of Canada.


Percent total saturates is the sum of each individual percentage saturate fatty acid to total oil (e.g. % C12:0+% C14:0+% C16:0+% C18:0+% C20:0+% C22:0+% C24:0). The typical percentages by weight of fatty acids present in the endogenously formed oil of the mature whole dried seeds are determined. During such determination the seeds are crushed and are extracted as fatty acid methyl esters following reaction with methanol and sodium methoxide. Next the resulting ester is analyzed for fatty acid content by gas liquid chromatography using a capillary column which allows separation on the basis of the degree of unsaturation and fatty acid chain length. This procedure is described in the work of Daun, et al., (1983) J. Amer. Oil Chem. Soc., 60:1751-1754 which is herein incorporated by reference.


R1439, R1815 and R1931 are examples of plants/recombination events that contain the second generation shortened Raphanus fragment. These plants can be used to generate new restorer lines generate inbred lines and or generate hybrid lines. Further, any plant part from the new lines or descendants or progeny of the new lines, including but not limited to seeds, cells, pollen, ovules, nucleic acid sequences, tissues, roots, leaves, microspores, vegetative parts, whether mature or embryonic, are included in the scope of the invention. Plant cells, protoplasts and microspores, as well as other plant parts, can be isolated by cell and tissue culture methods as is known to those skilled in the art. Any plant cell comprising the new recombination event designated R1439, R1815 or R1931 is included within the scope of this invention.


Shortening the Raphanus Fragment Further—


R1439, R1815 and R1931 are examples of plants that contain the second generation shortened Raphanus fragment. These plants can be used to further shorten the Raphanus fragment by crossing them with the deletion mutant lines, R1, R2 and R5, (or other deletion mutant lines) and repeating the process over again. This process can be carried out repeatedly, until the Raphanus fragment is reduced to a length that is not associated with any undesirable genes or traits.


Generating New Restorer Lines—


The second phase recombinant Brassica Ogura restorer lines of this invention may be used to generate new restorer lines by crossing the commercial restorer lines and selecting for the shortened Raphanus fragment. In addition, new restorer lines can be generated de novo by following the methods of the present invention. Further, double haploid production can also be used to produce fixed SRF restorer lines. Methods of double haploid production in Brassica are known to those skilled in the art. See, for example, Beversdorf, et al., (1987) “The utilization of microspore culture and microspore-derived doubled-haploids in a rapeseed (Brassica napus) breeding program”—In Proc. 7th Int. Rapeseed Conf, (Organizing Committee, ed), pp. 13. Poznan, Poland; Swanson, “Microspore Culture in Brassica”. Chapter 17, Methods in Molecular Biology, Vol. 6, P159-169, Plant Cell and Tissue Culture, Edited by Pollard and Walker by The Humana Press (1990) which are incorporated herein by reference.


Generating Inbred Plants Using Restorer—


The second phase recombinant Brassica Ogura restorer lines of this invention may be used for inbreeding using known techniques. The homozygous restorer gene of the Brassica plants can be introduced into Brassica inbred lines by repeated backcrosses of the Brassica plants. For example, the resulting oilseeds may be planted in accordance with conventional Brassica growing procedures and following self-pollination Brassica oilseeds are formed thereon. Again, the resulting oilseeds may be planted and following self pollination, next generation Brassica oilseeds are formed thereon. The initial development of the line (the first couple of generations of the Brassica oilseed) preferably is carried out in a greenhouse in which the pollination is carefully controlled and monitored. This way, the glucosinolate content of the Brassica oilseed for subsequent use in field trials can be verified. In subsequent generations, planting of the Brassica oilseed preferably is carried out in field trials. Additional Brassica oilseeds which are formed as a result of such self pollination in the present or a subsequent generation are harvested and are subjected to analysis for the desired trait, using techniques known to those skilled in the art.


Generating Hybrid Plants Using New Second Phase Recombinant Restorer Lines as Male Parent—


This invention enables a plant breeder to incorporate the desirable qualities of an Ogura restorer of cytoplasmic male sterility into a commercially desirable Brassica hybrid variety. Brassica plants may be regenerated from the Ogura restorer of this invention using known techniques. For instance, the resulting oilseeds may be planted in accordance with conventional Brassica-growing procedures and following cross pollination Brassica oilseeds are formed on the female parent. The planting of the Brassica oilseed may be carried out in a greenhouse or in field trials. Additional Brassica oilseeds which are formed as a result of such cross pollination in the present generation are harvested and are subjected to analysis for the desired trait. Brassica napus, Brassica campestris, and Brassica juncea are Brassica species which could be used in this invention using known techniques.


The hybrid may be a single-cross hybrid, a double-cross hybrid, a three-way cross hybrid, a composite hybrid, a blended hybrid, a fully restored hybrid and any other hybrid or synthetic variety that is known to those skilled in the art, using the restorer of this invention.


In generating hybrid plants, it is critical that the female parent (P1) that is cross-bred with the Ogura restorer (P2) have a glucosinolate level that is sufficiently low to ensure that the seed of the F1 hybrid has glucosinolate levels within regulatory levels. The glucosinolate level of the seed harvested from the F1 hybrid is roughly the average of the glucosinolate levels of the female parent (P1) and of the male parent (P2). The glucosinolate level of the hybrid grain (F2) is reflective of the genotype of the F1 hybrid. For example, if the objective is to obtain hybrid grain (F2) having a glucosinolate level of less than 20 μmol/gram and the male parent (Ogura restorer) has a glucosinolate level of 15 μmol/gram, the female parent must have a glucosinolate level of less than 25 μmol/gram.


Generating Plants from Plant Parts—



Brassica plants may be regenerated from the plant parts of the restorer Brassica plant of this invention using known techniques. For instance, the resulting oilseeds may be planted in accordance with conventional Brassica-growing procedures and following self-pollination Brassica oilseeds are formed thereon. Alternatively, doubled haploid plantlets may be extracted to immediately form homozygous plants, as is known to those skilled in the art.


Vegetable Meal—


In accordance with the present invention it is essential that the edible endogenous vegetable meal of the Brassica oilseed contain glucosinolate levels of not more than 30 μmol/gram of seeds. The female parent which can be used in breeding Brassica plants to yield oilseed Brassica germplasm containing the requisite genetic determinant for this glucosinolate trait is known and is publicly available. For instance, Brassica germplasm for this trait has been available in North America since the mid-1970's.


Representative winter rape varieties that include the genetic means for the expression of low glucosinolate content and that are commercially available in Europe, for example, include, EUROL®, (available from Semences Cargill), TAPIDOR®, SAMOURAI® (available from Ringot). More recent winter rape varieties include 46W10, 46W14, 46W09, 46W31, 45D01 and 45D03 (available from Pioneer®). Representative spring rape varieties that include the genetic means for the expression of low glucosinolate content and that are commercially available in Canada, for example, include KRISTINA® (available from Svalof Weibull). More recently, 46A76 (available from Proven®) and 46A65 (available from Pioneer®) are available.


The second phase recombinant Ogura restorer lines were deposited at National Collections of Industrial, Marine and Food Bacteria NCIMB Ltd, Ferguson Building, Craibstone Estate, Bucksburn, Aberdeen, AB21 9YA. Scotland, UK. The seeds that were deposited include restorer line R1439 (Accession No. NCIMB 41510), R1815 (Accession No. NCIMB 41511), and R1931 (Accession No. NCIMB 41512) discussed hereafter.


The edible endogenous vegetable oil of the Brassica oilseeds contains fatty acids and other traits that are controlled by genetic means (see, US Patent Application entitled, “Improved Oilseed Brassica Bearing An Endogenous Oil Wherein the Levels of Oleic, Alpha-Linolenic and Saturated Fatty Acids Are Simultaneously Provided In An Atypical Highly Beneficial Distribution Via Genetic Control”, of Pioneer Hi-Bred International, Inc., WO91/15578; and U.S. Pat. No. 5,387,758, incorporated herein by reference). Preferably erucic acid of the Brassica oilseed is included in a low concentration of no more than 2 percent by weight based upon the total fatty acid content that is controlled by genetic means in combination with the other recited components as specified. The genetic means for the expression of such erucic acid trait can be derived from commercially available canola varieties having good agronomic characteristics, such as 46A05, 46A65, BOUNTY®, CYCLONE®, DELTA®, EBONY®, GARRISON®, IMPACT®, LEGACY®, LEGEND®, PROFIT®, and QUANTUM®. Each of these varieties is registered in Canada and is commercially available in that country.


Herbicide Resistance—


As is known to those skilled in the art, it is possible to use this invention to develop a Brassica plant which is a restorer of fertility for Ogura cytoplasmic male sterility, and produces oilseeds having low glucosinolate content and has other desirable traits. Additional traits which are commercially desirable are those which would reduce the cost of production of the Brassica crop or which would increase the quality of the Brassica crop. Herbicide resistance, for example, is a desirable trait.


A person skilled in the art could use the Brassica plant of this invention to develop a Brassica plant which is a restorer of fertility for Ogura cytoplasmic male sterility, produces oilseeds having low glucosinolate content and which is resistant to one or more herbicides. Herbicide resistance could include, for example, resistance to the herbicide glyphosate, sold by Monsanto™ under the trade mark ROUNDUP™. Glyphosate is an extremely popular herbicide as it accumulates only in growing parts of plants and has little or no soil residue.


There are two genes involved in glyphosate resistance in canola. One is for an enzyme which detoxifies the herbicide: it is called GOX, glyphosate oxidoreductase. The other is a mutant target gene, for a mutant form of EPSP synthase. One skilled in the art could use GOX or CP4 (5-Enol-pyruvylshikimate-3-phosphate synthase from Agrobacterium sp. CP4 (CP4 EPSPS)) with promoters in canola. Basically, the genes are introduced into a plant cell, such as a plant cell of this invention carrying the restorer gene for Ogura cytoplasmic male sterility, and then the plant cell grown into a Brassica plant. As another example, a person skilled in the art could use the Brassica plant of this invention to develop a Brassica plant which is a restorer of fertility for Ogura cytoplasmic male sterility, produces oilseeds having low glucosinolate content and which is resistant to the family of imidazolinone herbicides, sold by BASF under trade-marks such as CLEARFIELD. Resistance to the imidazolinones is conferred by the acetohydroxyacid synthase (AHAS) gene, also known as acetolactate synthase (ALS). One skilled in the art could introduce the mutant form of AHAS present in varieties such as the Pioneer™ spring canola variety, 45A71, into a Brassica plant which also carries the shortened Raphanus fragment containing the restorer gene for the Ogura cytoplasm. Alternatively, one could introduce a modified form of the AHAS gene with a suitable promoter into a canola plant cell through any of several methods. Basically, the genes are introduced into a plant cell, such as a plant cell of this invention carrying the restorer gene for Ogura cytoplasmic male sterility, and then the plant cell grown into a Brassica plant.


If desired, a genetic means for tolerance to a herbicide when applied at a rate which is capable of destroying rape plants which lack said genetic means optionally may also be incorporated in the rape plants of the present invention as described in commonly assigned U.S. Pat. No. 5,387,758, that is herein incorporated by reference. Glyphosate resistance may be conferred by glyphosate N-acetyl transferase (GAT) genes: see for example, W02002/36782 or WO2005/012515; US Patent Application Publication Numbers 2004/0082770, 2005/0246798, 2006/0200874, 2006/0191033, 2006/0218663 and 2007/0004912; and Canadian Patent Application Numbers 2,521,284 and 2,425,956 all of which are herein incorporated by reference.


Breeding Techniques—


It has been found that the combination of desired traits described herein, once established, can be transferred into other plants within the same Brassica napus, Brassica campestris, or Brassica juncea species by conventional plant breeding techniques involving cross-pollination and selection of the progeny.


Also, once established the desired traits can be transferred between the napus, campestris, and juncea species using the same conventional plant breeding techniques involving pollen transfer and selection. The transfer of traits between Brassica species, such as napus and campestris, by standard plant breeding techniques is documented in the technical literature. (See, for instance, Tsunada, et al., “Brassica Crops and Wild Alleles Biology and Breeding.” Japan Scientifc Press, Tokyo (1980)).


As an example of the transfer of the desired traits described herein from napus to campestris, one may select a commercially available campestris variety such as REWARD®, GOLDRUSH®, and KLONDIKE®, and carry out an interspecific cross with an appropriate plant derived from a napus breeding line, such as that discussed hereafter (i.e., R1439, R1815 and R1931). Alternatively, other napus breeding lines may be reliably and independently developed using known techniques. After the interspecific cross, members of the F1 generation are self pollinated to produce F2 oilseed. Selection for the desired traits is then conducted on single F2 plants which are then backcrossed with the campestris parent through the number of generations required to obtain a euploid (n=10) campestris line exhibiting the desired combination of traits.


In order to avoid inbreeding depression (e.g., loss of vigor and fertility) that may accompany the inbreeding of Brassica campestris, selected, i.e., BC1 plants that exhibit similar desired traits while under genetic control advantageously can be sib-mated. The resulting oilseed from these crosses can be designated BC1SIB1 oilseed. Accordingly, the fixation of the desired alleles can be achieved in a manner analogous to self-pollination while simultaneously minimizing the fixation of other alleles that potentially exhibit a negative influence on vigor and fertility.


A representative Brassica juncea variety of low glucosinolate content and low erucic acid content into which the desired traits can be similarly transferred is the commercial variety 45J10.


Stand of Plants—


The oilseed Brassica plants of the present invention preferably are provided as a substantially uniform stand of plants. The Brassica oilseeds of the present invention preferably are provided as a substantially homogeneous assemblage of oilseeds.


The improved oilseed Brassica plant of the present invention is capable of production in the field under conventional oilseed Brassica growing conditions that are commonly utilized during oilseed production on a commercial scale. Accordingly, the invention includes a method of growing a Brassica plant, comprising: sowing seed designated R1439, R1815 or R1931 and having NCIMB Accession Numbers 41510, 41511, and 41512 respectively, or a descendent (for example, a sexual progeny or offspring), a vegetative cutting or asexual propagule or from a plant produced by crossing R1439, R1815 or R1931 with a second plant; and growing the resultant plant under Brassica growing conditions. Such oilseed Brassica exhibits satisfactory agronomic characteristics and is capable upon self-pollination of forming oilseeds that possess the commercially acceptable glucosinolate levels within the meal present therein. Further, the applicant's teaching includes an assemblage of crushed Brassica seed of the lines with SRF, their descendants and progeny thereof, and the oil and meal from such lines. The oil can be produced by crushing seeds produced by the plant line designated R1439, R1815 or R1931, or their descendents, sub-lines, or from a plant produced by crossing R1439, R1815 or R1931 with a second plant; and extracting oil from said seeds. The method can further comprise the step of: refining, bleaching and deodorizing the oil.


Deposits

The seeds of the subject invention were deposited in the National Collections of Industrial, Marine and Food Bacteria Ltd (NCIMB), Ferguson Building, Craibstone Estate, Bucksburn, Aberdeen, AB21 9YA Scotland, UK














Seed
Accession No.
Deposit Date








Brassica napus oleifera R1439

NCIMB 41510
Oct. 22, 2007



Brassica napus oleifera R1815

NCIMB 41511
Oct. 22, 2007



Brassica napus oleifera R1931

NCIMB 41512
Oct. 22, 2007









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


The present invention has been described in detail and with particular reference to the preferred embodiments; however, it will be understood by one having ordinary skill in the art that changes can be made thereto without departing from the spirit and scope thereof.









TABLE 1a





Rf Markers for SRF Restorer Lines




























05
06
07





01
02
03
04
Sterile
Sterile
Sterile
08
09 
10














Phenotype
Fertile
CMS
CMS
CMS
Fertile
Fertile
Fertile


Cytoplasm
CMS
Deletion
Deletion
Deletion
CMS
CMS
CMS
















Marker

Size
NW1717
Mutant
Mutant
Mutant
SRF-
SRF- 
SRF-


Group
Marker
(bp)
(wildtype)
R1
R2
R5
R1439
R1815
R1931





I
RMA01
247
+

+
+






RMA02
198
+

+
+






RMA03
233
+

+
+






RMA04
348
+

+
+






RMA05
581
+

+
+






RMA06
249
+

+
+






RMA07
350
+

+
+






RMA08
354
+

+
+






RMA09
357
+

+
+






RMA10
208
+

+
+








II
RMB01
572
+



+
+
+



E35M62
215
+



+
+
+



RMB02
301
+



+
+
+



RMB03
459
+



+
+
+



RMB04
168
+



+
+
+



RMB05
325
+



+
+
+



RMB06
504
+



+
+
+



RMB07
537
+



+
+
+



RMB08
524
+



+
+
+



RMB09
316
+



+
+
+



RMB10
358
+



+
+
+



OPF10
496
+



+
+
+



RMB11
317
+



+
+
+



RMB12
750
+



+
+
+





III
RMC01
356
+
+
+

+
+
+



RMCO2
479
+
+
+

+
+
+



RMC03
266
+
+
+

+
+
+



E38M60
116
+
+
+

+
+
+



RMC04
213
+
+
+

+
+
+



RMC05
500
+
+
+

+
+
+



RMC06
482
+
+
+

+
+
+



RMC07
466
+
+
+

+
+
+



RMC08
547
+
+
+

+
+
+



RMC09
327
+
+
+


+
+



RMC10
465
+
+
+


+
+



RMC11
273
+
+
+


+
+



RMC12
347
+
+
+


+
+



RMC13
382
+
+
+


+
+



RMC14
533
+
+
+


+
+



RMC15
711
+
+
+


+
+



RMC16
400
+
+
+


+
+



RMC17
554
+
+
+

+
+




RMC18
525
+
+
+

+
+




RMC19
543
+
+
+

+
+




RMC20
463
+
+
+

+
+




RMC21
269
+
+
+

+
+




RMC22
747
+
+
+

+
+




RMC23
219
+
+
+

+
+




RMC24
363
+
+
+







OPC2
678
+
+
+







RMC25
364
+
+
+







RMC26
201
+
+
+







RMC27
238
+
+
+







RMC28
623
+
+
+







RMC29
198
+
+
+







RMC30
525
+
+
+







RMC31
379
+
+
+







RMC32
450
+
+
+







RMC33
275
+
+
+









IV
E33M47
122










E32M50
252










OPN20
587










OPH15
637










IN6RS4
236










E33M58
281










E32M59A
406










E32M59B
350










OPH03
591












V
IN10RS4
287
+
+


+
+
+



RME01
454
+
+


+
+
+



RME02
233
+
+


+
+
+



RME03
533
+
+


+
+
+



RME04
699
+
+


+
+
+



RME05
477
+
+


+
+
+



RME06
480
+
+


+
+
+



RME07
579
+
+


+
+
+



RME08
496
+
+


+
+
+



RME09
574
+
+


+
+
+



RME10
570
+
+


+
+
+

















Rf Marker Loss 
0/59
24/59
14/59
49/59
29/59
21/59
28/59


(I, II & III)


















01
02
03

















Phenotype







Cytoplasm
11

13
















Marker

Size
Forward Primer
12
Reverse Primer
14



Group
Marker
(bp)
(5′->3′)
SEQ ID
(5′->3′)
SEQ ID






I
RMA01
247
GCTTCTACTTCC
NO. 1
CAAGCTCTTCGG
NO. 2






ATACCAATGG

TATGAAACG





RMA02
198
AAGCTTCAGCTT
NO. 3
GTTCGTTGTAGA
NO. 4






ATCCTTGG

TCGGATCC





RMA03
233
CTTGCTGCAAAG
NO. 5
AGCTTCAGACCA
NO. 6






CACTTCTC

AGTCCCAG





RMA04
348
GGATCACGAAAC
NO. 7
TCATATCTCCCT
NO. 8






TCCCAAGG

CCTTGTCCA





RMA05
581
AAGCTCAGGCTC
NO. 9
GGGAAGGAGATC
NO. 10






CTTCACCG

CGGACTCA





RMA06
249
AAGCTTATAGAG
NO. 11
TCTAAGATCAGT
NO. 12






TAGCCATTGAG

ATATGGACAGC





RMA07
350
CGGACTCTTTAG
NO. 13
CACCTCCTGTCG
NO. 14






CTCCGCCA

GCATCTCA





RMA08
354
TATTCTGCTTCA
NO. 15
ACGATTGTTAAG
NO. 16






TGTGGTGATC

TTGACGAAAG





RMA09
357
TTTTTCAATGCT
NO. 17
GCACAAAATTAC
NO. 18






TCTGTGCAG

AATCAGCGC





RMA10
208
AAGCTTTGTGTT
NO. 19
AGTTGAAACGAT
NO. 20






GCTAATGTAT

ATAACTTGTGA







II
RMB01
572
ATTGTCGTTGTC
NO. 21
AGAAGAAGAAAG
NO. 22






GATGCATC

TGCCAAGCA





E35M62
215
AAAATTGCGAGG
NO. 23
CTCCAGCTCCTG
NO. 24






TTCAGGAAT

TTAGTGACTCTT





RMB02
301
AATTTATGGGGT
NO. 25
TGGCTGATTTGC
NO. 26






GTCAATTGA

AACATAAA





RMB03
459
GTTCTGGCTATG
NO. 27
CCAGAGTTTGGA
NO. 28






TCGAGACCAC

GGCAGACT





RMB04
168
GAGTTGTGGGTT
NO. 29
ACGCACCAGAAC
NO. 30






TGGCCGTC

GATCAATC





RMB05
325
ATCAGAGCAAAA
NO. 31
CGAAATACCGAA
NO. 32






GAGTGCGTAG

GAACCAAATC





RMB06
504
ACATCGGTCGAA
NO. 33
AATCTTGAGGCA
NO. 34






GAAGTTCC

AGCCTGAC





RMB07
537
AGCTTCTATTCA
NO. 35
GCATTACCGTTG
NO. 36






GCCAAAAGG

GAAAATTTC





RMB08
524
ACCAAAGACACC
NO. 37
CGCACTTTTAGC
NO. 38






ATAACGAGG

AGCAGTTC





RMB09
316
CCCACTCTTGTT
NO. 39
GTTCCCACAGCC
NO. 40






ACCTTCAGC

TACCAGTAC





RMB10
358
ATTGGATTTGAA
NO. 41
TCCATTGATCTC
NO. 42






TGAGATGG

TGCACATC





OPF10
496
AACTTTTTGTGT
NO. 43
ACTCCTTCTAAA
NO. 44






TTGATTTCTTGC

CAAAACCAAACA





RMB11
317
AAGCTTGTCTCC
NO. 45
TCAGAAAGATAT
NO. 46






TACGTACTTC

TTCACGTCAC





RMB12
750
TGGACTAAGAAA
NO. 47
CGAAGAATCTCT
NO. 48






GGGTCAGGTA

ACTCTGTTGT







III
RMC01
356
AGGAAGTGAGAG
NO. 49
TCCATGGGTGTC
NO. 50






GCAGTTGG

CTAGGATC





RMCO2
479
TGCGTAACACTT
NO. 51
TGCAGAACTCAA
NO. 52






CTTTGCTTC

AGCCATTC





RMC03
266
AAGCTTATTTTC
NO. 53
CATCACCATCAT
NO. 54






ATCCTGCAA

CACAGTAATT





E38M60
116
TCCATAGAAGAA
NO. 55
TCGACACACTTA
NO. 56






ACTCTTTGCAAC

CTAATCTGAGAG









TG





RMC04
213
TATTTTGTCCTC
NO. 57
TTCCTTTGTGTT
NO. 58






GGTTAGATC

TGGTTAGGG





RMC05
500
TGCGAGTTTAAT
NO. 59
CCGCGTTATTCT
NO. 60






CCGGACGC

GGTTCAGAGA





RMC06
482
TTCCTCGGCAAG
NO. 61
GCCGTCTAACAG
NO. 62






AACAACGC

CAGGTGCA





RMC07
466
CCGTATTTGAAA
NO. 63
TCAACCGTGAAT
NO. 64






ACGTGGCG

TTGGGTCG





RMC08
547
GAGGCGAAAACA
NO. 65
ATCGCCAAAACT
NO. 66






TAAACAAGG

GTTTCAGG





RMC09
327
TCGGTTTTTCGA
NO. 67
TCCGATTTAGAA
NO. 68






GGGTATCA

TCGAACCTG





RMC10
465
TCCTGCAGTTTG
NO. 69
AAGTTTCCCCAA
NO. 70






AAATCCTTG

ACCAACTTC





RMC11
273
AAGCTTAATAGC
NO. 71
TGAAAACCCTAG
NO. 72






GACTTCTTC

TCTCTCTCTC





RMC12
347
AATGGATGAACT
NO. 73
TGATAACCCCTC
NO. 74






CGAGACGG

GTTTCCTG





RMC13
382
TGTCAGCATTCA
NO. 75
AGGGATTGAAAG
NO. 76






GCAGAAGC

CTGGGAAC





RMC14
533
TTGACGGTTACC
NO. 77
TTGATTGCTTCA
NO. 78






CAAAATACCG

CCCTCACCC





RMC15
711
AAAGCATCCTTT
NO. 79
GAACCAAAAATG
NO. 80






GCAAGGGG

AGTGGATGG





RMC16
400
AAATTGTTACAA
NO. 81
TTCAGTAAACAT
NO. 82






AGTATGAGAAAT

TTTACTCATTCT







G

C





RMC17
554
TTTCCACACAAA
NO. 83
TGGCCAATGAAA
NO. 84






TCGGATTTAA

GTTTACTGAT





RMC18
525
ACCAAACCGAGA
NO. 85
GGTTCGAATACT
NO. 86






ACAAAATAGGTG

TTGGTTTTTTGG





RMC19
543
TGGAGGTGTCAA
NO. 87
CGCAAGTCACTT
NO. 88






AGTGTGGC

TATTTGGC





RMC20
463
GAACCACGACTT
NO. 89
GCTTTGGTTAGA
NO. 90






TGGGTCTG

ATGTCGGC





RMC21
269
GAGAATATTGGA
NO. 91
AAGTCGTGGTTC
NO. 92






AGAAAGCGG

CTTTGAGG





RMC22
747
GCTCTACGAGTG
NO. 93
CACTTTCGGAAT
NO. 94






AGGATCAAAG

CCAAGCTC





RMC23
219
AGCTTATAGGCT
NO. 95
GTTTCTGTTTCT
NO. 96






TCTAGACCC

GCAGGCTC





RMC24
363
AGCTTTAATTCA
NO. 97
AATTTTTTTGTG
NO. 98






TGTATTTTTACA

ATACATTTCAA





OPC2
678
CTGTAACTTTCA
NO. 99
TTTTGGGGATTA
NO. 100






ACCCAACTCGTA

CTCTTCTTAGCT







GAA

TTC





RMC25
364
AAGCTTGATCAA
NO. 101
AACAAACTAATG
NO. 102






AGATCACAG

AGCAACAGG





RMC26
201
CAGACCGTTCAA
NO. 103
CAAGTTGCTCGG
NO. 104






GTTCATGG

CATATGAT





RMC27
238
CCTTCTCCAAAC
NO. 105
TTTTGAGAAATG
NO. 106






CGGTAAAC

ACGGATCG





RMC28
623
AGACCAAGAGGA
NO. 107
AAGAAACAACCC
NO. 108






AGCGTAGC

AGACTCCG





RMC29
198
CAATGATTTATA
NO. 109
GCAGCGTACGGT
NO. 110






CTTCGTTTTTGC

ATGTCTATCT





RMC30
525
CATTTGGTTTGT
NO. 111
AGGCGACAACCT
NO. 112






CCGTGTGT

CTTTCAAC





RMC31
379
CATTTTCTTTAA
NO. 113
ACGACGGCGACA
NO. 114






CAACGCGC

TGTAGTAC





RMC32
450
TCTCTCACACTT
NO. 115
CGCCGAGAATTT
NO. 116






TCTCTCAC

CCGCGCC





RMC33
275
CAAATCAATACC
NO. 117
TTTTTGATTAAT
NO. 118






ATTAAAAGTGG

TTCCTTTCACA







IV
E33M47
122
AATAGAGGGAGA
NO. 119
AGCTACCTAACA
NO. 120






GGATGAAAGAAC

GGTTTTGTTATA









AAG





E32M50
252
TCACATTAGTAA
NO. 121
GATTGATTTTTT
NO. 122






AACGATTGTCCA

GGACTCCGTT







C







OPN20
587
CCTTAGTTTAGT
NO. 123
AGAAACCGCTCA
NO. 124






TGTAGGTGGTGG

ATTTTAACATAA





OPH15
637
CCTTGGCTATGT
NO. 125
TAAAACACAGAG
NO. 126






GCTTATGTATTT

ACAATCGTGAGG





IN6RS4
236
CATTGATACATG
NO. 127
GATGAAAACATT
NO. 128






AATGCAAAGAAG

TACAGACAATGC





E33M58
281
CTGCATAAAATT
NO. 129
TTCTGTTTCAGC
NO. 130






ATCGAAGACAGA

GCTAACAAATC







TA







E32M59A
406
CTTTGTCATTGT
NO. 131
AATATGATTTCC
NO. 132






GTGTGTGTGTGT

AATTTGCCAAGT





E32M59B
350
AATTCTTGCTCC
NO. 133
CACAAGACGATC
NO. 134






ATTATGATTTCA

AGGAAAAAGAA





OPH03
591
TCCACTCCTAGT
NO. 135
TATACAAAATGT
NO. 136






TCACAATCTATT

TGGAATACACAA







TT

GG







V
IN10RS4
287
CAGAACACAGTT
NO. 137
TATAGGAGCTTT
NO. 138






CTATGACACTG

GTTCTGTAGTGG





RME01
454
TCCATTGCAGAA
NO. 139
TGTTTTCTTCGT
NO. 140






TTCACCTG

CATGTCGG





RME02
233
CTTGAGGGAAGG
NO. 141
ATTTTGGGTCAT
NO. 142






AGACGAGA

GGGTTTTT





RME03
533
ATATCCTTAAAC
NO. 143
TTGAATACCTCC
NO. 144






CCTTGCGC

AAGGACCC





RME04
699
GGTCTCAGGTTT
NO. 145
GGTTCTCAAAGA
NO. 146






TGTGGGAG

TTCCGAGG





RME05
477
CTTGGTCACACC
NO. 147
TGTCCGATAAAC
NO. 148






CATCTTCTC

TCTCTGCG





RME06
480
ATCAACCACGTT
NO. 149
AACTCAAATACT
NO. 150






CATCCATG

CTCGGCCAG





RME07
579
ATTTACCAAATG
NO. 151
CCGAGAATTGAA
NO. 152






GATCACTCTGG

CATTGTAAAGA





RME08
496
CAATTCCACAAC
NO. 153
CTTTTCGACTAA
NO. 154






GTAGCAGAG

GAACCGGC





RME09
574
AGCTTGGACTAT
NO. 155
ATTTCAGGACCG
NO. 156






GCCGTTTG

GCTATGTG





RME10
570
TCGAGAATCCTC
NO. 157
AAGCACCACTTA
NO. 158






TACAAACGC

TTCGACAGC

















Rf Marker Loss 







(I, II & III)
















TABLE 1b







Rf Marker Sequences












SEQ



Marker
Size
ID
Sequence (5′ -> 3′)













RMA01
247
NO.
GCTTCTACTTCCATACCAATGGACATTATCGCATAGCTGGCTATATTCTTGGAGTCAGCTGGGAGA




159
AGGTTAGTTCCTTGGTCTTCGTATCGGTGAGCTATGTACTGAGTAATGGCTCTTGATTCTACACAA





AAAAAAAACAAATCATGTTAGTGAAATTTTCTTCTTATGCGTATTTGTTCAATTCAGGTTTGAGAT





TGAAGATGAGATAATGATTGCTTATAAACGTTTCATACCGAAGAGCTTG





RMA02
198
NO.
AAGCTTCAGCTTATCCTTGGCCTAGAAGCAACGTCAATAACTTTCCAACCGTGCCTTGGTTTTACG




160
ATCGGGAAGATGATCTGGAAAGCTGACAACGAGATCTTTCTATTGACATCTCGCTCGTTTTCTGGT





TCCTTCTAGATCAACGGGAAAACACTGATGAAGTTGACTTATCGGCGGATCCGATCTACAACGAAC





RMA03
233
NO.
CTTGCTGCAAAGCACTTCTCTCATCCACTCTTAGTTCAACTTCTGCTTCAAGCTTTAGTATTGTTT




161
GCTTTAAACTTGAGACATCCTCTTGCAAACTCTTCACTGATGCTACCGAGGAGAGACTGAGCTCAC





TGAGACCTTTGTTCTCAACCTTGGCTTGCTGAATCTCCTCATGCAGCTCGTTGTTTCGGAACTCTC





CATGTCATTCATGATCTGGGACTTGGTCTGAAGCT





RMA04
348
NO.
GGATCACGAAACTCCCAAGGAAACTTATAAGTATTTTAGGTAAGACCGGTGTCAAGAAGAACCTGA




162
GGACTATCTTTTCTTGAGAAGAAGTATCAGCTTTCATCAGGATGAATCTTTCACCGGTAGAGATAG





TCTAAGAGAGACACAAGAAAGAACTTCCTATTCCCTTCTTCCTTTCAAAAAAAAAACTCAGGAAAA





GAGCTGAAGAGGAAGACCACTAAAACACAAGTAGTAAGGCTGACATATTTAAGGCTAGACAGAAAC





GTAACAGAAAGGAAAATAAGACTCAAGAACATGAAAGTAGACAAAGGGTTGAAAGAAAAGATATGG





ACAAGGAGGGAGATATGA





RMA05
581
NO.
AAGCTCAGGCTCCTTCACCGCTTCTTCTACATCAATGTTCTTCCCCTTTGATTTGCTACGTTCTTC




163
CCCAGAAGAAGCACTAATCTCAGATTCTTCATCACTGCTCTCATCAGAATCACTGTACCTCCTCTT





CCTCCTATGACCTCTCCTCTTCCTACTACTTCCGCTTTTCTTCTTCTTATTCCTTCTTCTACGCCT





CCTATCTTCCTCATCCGAATCATCACTCTCGCTCTCCTCTTCCGATTCGCTATCACTCCTTCTCCT





ACGCTTACTCCTAGACCTCTTACTCTTCCTCTTCTTCCTAGATCTATCAGATTCAGATCCCGACTT





ACCCGAATCAGATTCGCCTTTCCGTTGTTTCGGATCGTCAACATCCTTCTCCGGAACCACCTCCTC





GTCAGCGGCGTTCTCATCGGACTCTTCCTCGTCGGGATCTCTGGGCGGACTCGGCCGTGTTCTCCC





ATATGCAGTACTTTCCAGATTTCCTCATCCTTGAGGCGTTTAAGCCCTCCTGTACTCCTCGTGACC





TCAATTCCTTTCAACCTCTTTCGTTCCGGAGTCTGAGTCCGGATCTCCTTCCC





RMA06
249
NO.
AAGCTTATAGAGTAGCCATTGAGTCGCCTCTGATTAACTTTTTGAAAAGCCAAGTGTGAACTTTTT




164
CCTCCTTCGTTTCCCAAAAAAAAACCACTTTTCTTTGATAACATTCTCTTGGATCCAAGCAACCCA





AACTGAATCAGTTTTGGAAGAATAACATCCACATGAGCTTGAGCATTCAAGATTTGTTTCATACAT





GGATGTTCCGGCTAGTGATAAATATTTTGCTGTCCATATACTGATCTTAGA





RMA07
329
NO.
CGGACTCTTTAGCTCCGCCATAACAACCACAGCAGCCTCCGGTGTGAAAAAACTCCACTTTTTCAC




165
AACAACCCACCGTCCAAGATCCCTCTCCTTCACCAGAACCGCAATCCGCGCCGAGAAAACAGATTC





CGCCGCCGCCGCCCCAGCCCCCGCCGTGAAAGAAGCTCCGGTGGGATTCACGCCGCCTCAGCTAGA





CCCAAACACACCGTCACCGATCTTCGCGGGGAGCACCGGTGGGCTTCTCCGCAAAGCCCAGGTGGA





AGAGATCTACGTTATTACATGGAACTCGCCGAAAGAACAGATCTTTGAGATGCCGACAGGAGGTG





RMA08
354
NO.
TATTCTGCTTCATGTGGTGATCATCTCCAAACTCACATAGCCAAAATATTGTTTCAAAAAGTTCGA




166
TAACCTTATCAATATCGATCCACTCCAGTGGTCTTTTAATAATGTAATCAATGGATAGTCAATTCG





TGAATCTATTGATTCTTGTATATATGGATATGTGAAAGGAGAACAAATTAAATCATGTACAAGTCA





AACATTGGAGTAGTATTAGCCTCCATTTTCTATAGATATGAATGCTCCGGAAAACAACTTCTTGTT





CAAGATGAAATCAGTACATGAACATCGTACATATATCGAGTAGATTCTCTATGATGTAAGTTCATT





TTCTTTCGTCAACTTAACAATCGT





RMA09
357
NO.
TTTTTCAATGCTTCTGTGCAGAATACCCTAATTCTCAGGAAATTCAACATGGTCTACCTCTAATAC




167
ATTGGCAACAGGTTCAAGGAGATGATGCTCCTCAGGTGATTTTTAAATTATATTTCTCTTTTTAAA





GGCAGTTATTTATTATAATTATTTTCTTGTCAATAATATTCACCAAAGATATCCTCACTAATACAT





TCACTCTTCCTTTTACCTTGATTTATACGTTTTCCCCTGGAATCTATACTTAATATTCCATCAAAA





ATAGTTATTGTATGTTTACTTTGAAAGGTACCAAAACCACATATTTAATTTCAATCGTTATTATGA





TTATATGCGCTGATTGTAATTTTGTGC





RMA10
208
NO.
AAGCTTTGTGTTGCTAATGTATATATTAACATCTTGTCAAACTACTCATCATAATTATATATGCTA




168
CAACCCGGGCTACAACTAATGAAATTTGATCAACTGATCATCATTTTTGGTAAAGTTATACAAAAT





ATTATTTCGCTGATAAATTTTTCAGTCTTTCAAAAATGTGGTTTTTATTTTTATCACAAGTTATAT





CGTTTCAACT





RMB01
572
NO.
ATTGTCGTTGTCGATGCATCCTCCAGCTGCTCTTCAGGCCATGTTGTTGATGATCCTTTCATCGGG




169
GAGAAACAGCTGTCCATTTTCCCTATCTTCTTGTCCAAATCTGTGATGCAGTCGCTCAGGCTGTTC





CTGTTTGCCTGCCTCAGCCAAGGTATAGCTACAGACGCATTCTGCGAGATAAAACTCTCGCACGAC





TTGATTCTTTTCGGCTTTCCGGAAGACGGCTTCTTGCTAGGTAACTGAGAGTTATTATTCCACACA





TGAATCCCCGAGTCTTCTGTTGTTGACACGATGTGTTTACCGTCCAAAGTAAACGAGGCACGTGTT





GTGCAGACGCCAGAAGCTGCAAAAAAGGAAGTTAGCCAAAAGGTTATACATCTTAATTCTTAAGTA





GAACAAAAAAAAATAAGGCACTAATTGTCTCTAATACTAACCTTTAAGCTTGCAGATGACATCATC





ACCAGATATGATACGAATCTGTGAATCAGCACAGGTAACCATTACTTTGTCGGAGTCATTGGGAAA





ATACTCAAGACCAGTGATCCTTTTGCTTGGCACTTTCTTCTTCT





E35M62
215
NO.
AAAATTGCGAGGTTCAGGAATGCTGTTTACAGCGTTGATGAAGACTTGATAGGGGTCCGAAAGGGC




170
ATCATAGGACAAGTAGTTAGACATAGGATGTTCAGTACAAGAGTTCACTGAGTCACAGTGATAATC





TCGCAGGTAGCTTGGAGCCTTATGAACTCTGCGTGTAGAAGTGTCTGGAGGTCTGCTTGAAGAGTC





ACTAACAGGAGCTGGAG





RMB02
301
NO.
AATTTATGGGGTGTCAATTGAACCCCCTAAACTGCATGTAGGTCCGCCACGGGATGGAAATGAAAC




171
TAGTAAAATAATAACAATTTTAAAGATGCTGATAATAGTAAATAACCAATTAATTTGCATAATAAA





AATAATTACCATCAGGACGAGCATATAGTAAATCATGACAGGGTCCATGACATAGTTACATATGCA





TCTTTAAAAACTACTAGAACAATAGTCGATGAAATTGGAAATATTGAAAAACCTAACTTGAATGCA





AAATGATTTTATAAAGTTTTATGTTGCAAATCAGCCA





RMB03
459
NO.
GTTCTGGCTATGTCGAGACCACTGAACCACCATGCCTCATGTCTGAATCGTGAGCTCGACTTCTTC




172
TTCTTCTTCGTGGGTTTCGTCATCATCAACTCGCAACCGCCGTGAACATGCTCATTCTTAATCTAC





GATTCTCAGCCGTGTGTGCTATGAAACTCACATTGAGCTCCTAATCTCCACCGTAATCCTCCTTTC





TGTTACCATGATCTTAGACGTAATCAAAACGATGTAGAACCGGTGGCGTCATTCTCTGACACAGAT





CCAATTCAACAAGATCTCACCGGAATCCATGGTCATGACAAGCTCAACATCGTCGTCCAGAATCAA





GCCTTGTCGTCTCAGCTCACCTTTGGTCGGATTGAAATCTCGATCGAACACTAACAATGGTCATCT





TTAGCTTATTTGCATCTGGGTCCCTCAAATTTCAGTTATTTTCAGTCTGCCTCCAAACTCTGG





RMB04
168
NO.
GAGTTGTGGGTTTGGCCGTCTCTGCTGGGATTAGCACCCCTGGAATGTGTGCGAGTCTTGCGTATT




173
TTGATACGTATAGGCGTGCGAGATTGCCGGCGAATCTGGTTCAGGCGCAGAGAGATCTCTTTGGAG





CTCATACTTACGAGAGGATTGATCGTTCTGGTGCGT





RMB05
325
NO.
ATCAGAGCAAAAGAGTGCGTAGATGGGTTTTGAGTTTTGAAGGAGGAAACATTGGTTTCTCCATGC




174
ATTTTGAAGTTTGAGTGAGGATAATGTTTTCTGTTTTAGTTCGGCTCGGATAAAAATTGTGACCGC





TTTTTTTTGTTGTTGTTTTGATTTGGAATCTATTTTTTTGATGTTTTGGTCTGCCCATCCATATCT





AGATTATATAGTTAGATTATATAGTTGGATAGGAAAAGTTTTTTTTTTTGGGTCAACAGGATAGGA





AAAGTCTATCCAGTGAAAGTGGTGTTCAATCTAAATATTGATTTGGTTCTTCGGTATTTCG





RMB06
504
NO.
ACATCGGTCGAAGAAGTTCCTGCATCAATTAGTACGTGGAGTTATCTTTTGTCTCTTTCTATAAGA




175
GGCACTGGAAATCTCAAGACCATAACACAGCTCCACCAAAGCCTATATATGCTGGACTTAAGCTAC





ACAGATATTGAGAAGATTCCAGAGTGCAACAATGGCCTTGACGGGGTGGAATACCTTTATCTAGCT





GGCTGTAGAAGACTCACATCATTGCCAGAGCTCCCTGGTTCGCTCATATCCCTATTGGCAGAAAAT





TGTGAATCACTGGAGACCGTTTCTTCCCCGTTGAACACTCCAAAGGCACACCTCAATTTCACCAAC





TGCTTCAAACTGGACCAACAAACAAGAAGAGCCATTATGCAACCACGACCGTCTCTCTACAGGCTG





GCAATCTTACCAGGAAGGGAAATACCTGCAGAGTTTGATCACCGAGGTCATGAGACCACCATTGGT





CCTTTTTCTGCATCCTCCAGGTGTCAGGCTTGCCTCAAGATT





RMB07
537
NO.
AGCTTCTATTCAGCCAAAAGGTTTTGATTTTGACCAATTTAGAGATTTTGTATTGGATTCAGTTGT




176
ACTTGTGCACAAAAAGAAGTATTGGAATCAGTTAGGGTTCTAGCTTTTGCAAAGAACTTTATTTTT





CTTGTATCAGCTTCGATAATGTAGATCAAACTGAATAAATGTTAAACAAAATAATTATTCAAAGCA





AATACAATTATGCAGAACAAATGCACATTATATGTTTATCAAACAATTTACTAAATATCATATATA





TTAAATGTTAAACTCATTATTTAAGGCTAGCACAAAATTTGTACGTGGAAATTTATGCATGATATT





CTTAAAATTCATGTCCCTGGCAATGAGCAAAACATTTTCTATTCCCATGAGGATTTTCATGAGTAT





GTGGATGTGTATATGTACGTCCGCGACATCTGTATTTTTCATAACGTTTTCTGAAAAACAAAGAAA





AAGAAAGATTAACACAATTGAAAAACTAAAAAGTCAACTTGAAAATACTAAAATGAAATTTTCCAA





CGGTAATGC





RMB08
524
NO.
ACCAAAGACACCATAACGAGGGCCATGGGAAAAGGCACCGGCACGGTTGGCTAGATCGTGACTGGT




177
TACCTTAGCAAGATACGAGTTATCACCCGTGGCATAGTAGAGCCACGCTCCCCCCCATATGAGGTC





ATCCCAGTGATCTGCGCTTTTCCGCTTGGCGCTCATAGCCTCGGCGTAAAGGTAAACGGCTTTGGC





ACTGTTAACAAGTGTTGCAGAGTACTCGACTTGGTCACGGAATACGATCGAGGCTGAGGCCAGGGA





AGCTGCCATCTCTGCAGCGAGATGCGGGCAGTCTGTGTAACATAGATTGACAGACCTTTGGTAATC





AATGTCTTCTGGTCGCATCCAGCAGTATAGGTCACTAGTCACTTGGCTTCCTTGATTCATTCCTAT





CTGTGAAAAGAAAAACAAAAAAAGTTTAGGACTGAACCGAATTGAGTATGCAAGAAGGAAGGGAAA





CAAAACTTTTATACCTGATACACCATTTCATAGATCGTATCAGAACTGCTGCTAAAAGTGCG





RMB09
316
NO.
CCCACTCTTGTTACCTTCAGCACCCTGCTCCACGGATTATGTGTGGATGTAAGTTTGAGAACTTGC




178
TTATCTTTATTCATCTTGCGTACAAGGTATATAACAGAGTTCTTGTTACAACAGATTTCTACAGAC





TCCTATATTACAGGAAGATAATATATTTACAAAACAGATATGAGAATATCCGGAGTATATTCTTTC





ACCCTCCCGCAGTGAGAACGTCGGAGTCTCTGACGTTTAAGCTGGTTCTGAACGATCGGAAGAGGG





AAGTTGGCAAACCTTTTGTGAATATATCAGCGTACTGGTAGGCTGTGGGAAC





RMB10
358
NO.
ATTGGATTTGAATGAGATGGAAGATTTGGTGTCGGAAAATGGTATAAACAAAAAGATTTGTTATGC




179
AGAAAATCCCAATGAAGCTATGTCCAAGAAGAGCTGGAGATGCAACAGCTGTTTATGCTTCAACTG





AGAGAGCTGAGAAAGAACTCAAATGGAAGTAAGTCATTGGCTTTATCATTTTTCCGCATATAGATC





ATACAATCTTGCTTGTGAATCAAGATACAATAATATGTTCACTCTTTGCTACATAGAAGATTTTTA





CTGTTGGCATGAATAAAGGACTGATTCTTTGTGATTTTTGTTTTGTTTATTAGGGCACAATATGGA





GTGGATGAGATGTGCAGAGATCAATGGA





OPF10
496
NO.
AACTTTTTGTGTTTGATTTCTTGCAGATTTGGTTCGGTGGCATATCTTCAGCAAATCTGGTGGTTT




180
CAAGTGGATGGAGAAATCGATTTCCCGTTCCCAGCTGGAACCTACAGCGTCTTCTTCAGGCTTCAC





CTAGGCAAACCGGGAAAGCGGTTTGGGTTGGGAAGGTTTGCAACACTGAACAGATTCACGGTTGGG





AACATTAAACCGGTTCGGGTTTCAGATTTGGACTGAAGATGGTCAACACTCTTCGTCTCAATGCAT





GTTAACCGGATCGGGAAGCTGGAATCACTACCATGCTGGAGACTTGTGGGTTGGAAATCCCAAAAG





CTCGTCGATGACTAAGCTTAAGTTCCTCCATGACGCAGATCGATTGTACACATACCCAAGGGAGGG





TTGTGTGTGGATTCTGTGATTGTGTATCCGAGCTCGTGTAAGGACCGGTTGAGGCGGGTTTAAGTG





TCTAAACCGATGTTTGGTTTTGTTTAGAAGGAGT





RMB11
317
NO.
AAGCTTGTCTCCTACGTACTTCTTCTATGTTCAACCGATAATGTCCTTGTCAGTTTTCTTGTATAT




181
TTGATTTTACAGTTGTTCTGAAGATTTTTTATTTTTGGGTTCTTTATTGCTCTGAAGCTAAATTAT





CTTTTGTCGTTCTAATCTTTGTCATATAAGCTCCATCAAAGTCTTGTCACTCATGTATCACTCTCC





ACATAGAAAGAGAAACACGAGAATTGATGTTTTTTTTAATCGACGAATTGGATGTTTTAAAAAAAA





AAAATTCTCTTTTTTCTTTTTTGAAAATTTAGTGACGTGAAATATCTTTCTGA





RMB12
321
NO.
TGGACTAAGAAAGGGTCAGGTAATGGTTGTGGTTCTACCAAACGTGGCCGAGTATGGGATTATTGC




182
CCTTGGCATTATGTCCGCCGGTGGAGTTTTCTCCGGCGCTAATCCTACGGCTCTTGTCTCGGAGAT





CAAGAAGCAAGTTGAAGCTTCTGGTGCTAGAGGAATCATCACTGATTCTACTAACTTCGAAAAGGT





TAAGAATTTGGGTCTACCGGTAATATTGTTAGGTGAAGAGAAGATCGAAGGAGCAGTGAACTGGAA





AGATATTCTAGAAGCAGGAGATAAATGTGGAGATAACAACAGAGTAGAGATTCTTCG





RMC01
356
NO.
AGGAAGTGAGAGGCAGTTGGCCTCGTCACGGGTTTTAGAGTTTAGAAAGCGTGTGCTTGAAAGTGT




183
TCAGCAGCGCGCATAGGATCATTGTGACAGGGGGAGAGTAGCTCGACCTGTCCTTGGGTAGATTAG





GAATTGGTTCGTATCAAGTTCAGTTGAACGTTGTGTAATTCGAATTAGACAAGTCAAGTGTGATTG





TCTAAGAGATTCTTAATAAAACAAGTTGTGTGTTTGAGTATTGATCGAGTTCCATAAGGAATCGGT





GTCCACTTGGTTTTACATTTGGTATCAGAGCGGGTCACCTCTGTGGACTCACAGAGTCTACTCACA





GGTTGAGATCCTAGGACACCCATGGA





RMC02
479
NO.
TGCGTAACACTTCTTTGCTTCACTCGTGAACAGCTCCACTCCTGGAACTAACATTCTCCCTCTTTT




184
TATCTCAATGTGACTTCCCTGCTACCTGCAACAGAAACACACTAGAACACACATTCTGACAGGCAA





CACGATTATGATAGTCAGCAAATCAAGGAGAACACCCCAAGAGATTATCCTTAAATTTCATCATGA





AAACTAGGATATTACAGCCGATAGAAAAAGAGTTCACAGGTTCATGATAATTCAAATAAACACCGA





AACAAGGATTAAACATCTGAGCAACAACACATTCATTAGTCGTTGTCTTGGTTTGCCGAGGCTGAG





GTGCCACCGATGTCTCCATAATCTCCCCCTGCAGTGAAGCACAATGAGATAAAAAAACGAAAAGAA





GTTAGCAAGATCAAGAGTTACCAAGAAACCTCCCCAGAGAAACCTTACTCTTGAGCCGAATGTGAA





TGGCTTTGAGTTCTGCA





RMC03
266
NO.
AAGCTTATTTTCATCCTGCAATGTCAACAACATACATAAATCTACTCAGCTTCTCTATACACATAA




185
CACAAGAAAGTAAACACATATAGGCATAAGGCATGGTTGTTTTAAAAAGATATTTATAAGTATATA





CTTACGTCTTCAAAATGAAATATCATTTATACTTAAATCACGTTTAAATACACTATTTTTACTCTT





TCAAACAAATATACTATAGTTTACATAAACACAAATTTAACTATATAATTACTGTGATGATGGTGA





TG





E38M60
116
NO.
TCCATAGAAGAAACTCTTTGCAACTATTTTCCTTTGAANAATGAAATCAATCGTCTCTTCCACAAT




186
TTGCAGAAACGTAAAATCTATTTACACTCTCAGATTAGTAAGTGTGTCGA





RMC04
213
NO.
TATTTTGTCCTCGGTTAGATCTTCTGTTGTACATTCTGATGCTCAGAGTGAGAGTCACACATACAT




187
TTTCAGTTTCTAGGTTTTGTCTGTGATTCTGCAAGTGATGAAGTTATTGGTTTGGTGTTGAGCTTT





TTATTATGTGTGTGTCTCTGTCTTCACGTTTTGATGTATCTGCTGTTCGTTTTTTTAAAACCCTAA





CCAAACACAAAGGAA





RMC05
500
NO.
TGCGAGTTTAATCCGGACGCCAAAGACCTGACGAAGCTCGCCAAGAACATAGATTTCGCGTGCACT




188
TTCTCGGACTGTACCGCGCTCGGTTACGGGTCTTCTTGCAATGGTCTGGATGCGAACGGGAACGCT





TCGTATGCGTTTAACATGTATTTTCAGGTGAAGAACCAGGATGAGATGGCTTGTGTGTTCCAAGGT





TTGGCCAGAGTTACAGATAAGAATATATCTCAGGGACAGTGTGAGTTCCCTGTTCAGATTGTTGCT





TCTTCGTCTTCTTCTTCTTCTGTGTCTCTTTTTGTTTGGTTGATCATCGCTGGAGTTTTGTTTGTC





TTGATGTTTTGAGGTCCCTTATTGATTATATATATTTCTATTTTGGTCTATGTGATAATATGTTGG





ATTTGGGTTAATCGTACAAGACAAAGACAAAAACAAAACATTGTTGAAATAAGTCTAGCATGTAAG





TCGGTTAATTTGGTTATCTCTGAACCAGAATAACGCGG





RMC06
482
NO.
TTCCTCGGCAAGAACAACGCACCGATCACGATCAACATCTACCCTTTCTTGAGCCTCTACGGTAAC




189
GACGACTTCCCGCTCAACTACGCCTTCTTCGACGGTGCTCAACCGATAGACGACCACGGTGTTAGC





TACACGAACGTCTTCGACGCCAACTTCGACACTTTGGTGTCGTCTCTGAAAGCTGTTGGTCATGGA





GATATGCCGATTATAGTAGGAGAAGTTGGCTGGCCAACAGAGGGTGACAAACACGCTAACACCGGT





AACATATCTCTGAAACTAACATAGTGCTCAGGCCGTCTCGAATTATTTATGGACCATGTTAAAAAA





ATATTAATGATATATTTAATATATAATAGAATAGTTTTAAAAATTTATAGTTTTATATTATAACTT





ATATATTTATTTTAAAAATTCTTAATTTTTCTTTTGTTTTTCAACTTGGATCATGTTAGTTCCGTT





TGCACCTGCTGTTAGACGGC





RMC07
466
NO.
CCGTATTTGAAAACGTGGCGATCTATAAGATATTTTGTATGCGTCTTCCCGTCTTCCGAATTAATC




190
ATATAGCATTTTTGTATGGAACAGGGAATATACATGAAGGATAAGTTCTGAGCATCATTTTTTTAA





GACTGATTCATAGAACTAGTGATGTTGTGTTACTTGTCGCTTCTCTTGGTGCTCACGACTTTGCAT





GTATGGCTTTCTTTTGATCTGATGTTTATATCTGCTTTAGGTTTTACTTGGAGACCCAAGGGCAGG





ATCCAATCAGCCAGAGATGCAGAGCTCTATTGTCTTCCATGCAGGATACGTTGATTTTGTGAGTAT





TCCTTTACTTGTATGGGTTTTTACTCTCACGTTGTCTTTACGCATGATTTCAATATTACATTTTCT





TTTCTAGAATCTGATTTGAGAGATTTCCCTTGGCACCGTGTTTTCATATTCGACCCAAATTCACGG





TTGA





RMC08
547
NO.
GAGGCGAAAAGATAAACAAGGTTCAAACAAATAATTGACAATTCTTTGGACATACAAAAAATTATT




191
TAATTTTTCCAAATAAAACATAATTGTTGAACTTTTTTTTGAACTGAACATAATTGCTTAACTTAA





GAAGTAAATCTATTCATAATTGAGTTTTAACTGCAATTATTAAAAAAAATTTTGTAATATTTGATC





AAATATCAAAATATATATTAAATTAAAATACTGAATGGATTATACATTTAATAGTAAATATTCGGT





TTGGTATAATATTTTGGGGAGAAATTTTAACTTTACTTAAAATTTAACATCACTTTTTAAATGATA





GTTATGTTTATAAACATCTTAATGTGATATATTCACTAATCACTGACAAGAACATGTGTTACAAAC





ATCTTAATGTGATATATTCACTAATCACTGACAAGAACATGTGTTACAATTCGCTGACAGCTCTAT





TGCCATCCATGCGCGATACGTCAATTTGCTTTACATTTATACATTTGCATTCTCTTCTTCTTTTTC





CTGAAACAGTTTTGGCGAT





RMC09
327
NO.
TCGGTTTTTCGAGGGTATCAAATTTAATTCTATTAGGATATTCTTAATTTTTAGGGAAATTAAGCC




192
TAATAACAAAAAAACTATAATTCACTAAATAACAAAATCCTCACTCTCACTCCTACTTTTCTTCTT





CCTATTTCTCTTTACTCTCATTCCTAAAAGTTAATTTCCATTTTTTGGGTTATTTGACAAATAAAC





CATAAATTTTAATTCGGATTCGTTTTAAGTTTTTTCCCAATTCAGTTCGGATATAGTAACACATCG





CAAACCCAGCTGAACCCACTAACACCGGATTATGTTCTAAAACAGGTTCGATTCTAAATCGGA





RMC10
466
NO.
TCCTGCAGTTTGAAATCCTTGGTAAATCCAATGATTTTAATATCAGACAATTAGATTTTAAAATAA




193
ATCAGATGAACTTCAAAATCAAATCAATGGATTATTATAAATCAACAAAATGGATTTGTAGTATTA





GTTTATGATAAAGTTAATAAATATAAAAATATATCTTTTTCATTTTTTTCTTATATGTTCTCAAAT





TCTCATAACATATAGAATATCCCCACCTATTTGTTGTAATAGTTGTTCTTAACTGATTGATATGTT





CTATATGCTGATTTTGGTTACAAGAAGTCAAGAACTTCTTCATCATTATTATTTTTAGATTTTTTT





CATCATCAAAATCTTTTTTTTTGGGGTTATTTGTAAAAAATGTGTAATTAAAAATATAATTTTTTG





AACTAGAAAATATGATATTAAANATAGTGATAATAGAATCGAGNACNCGGAAGTTGGTTTGGGGAA





ACTT





RMC11
273
NO.
AAGCTTAATAGCGACTTCTTCGTTAGTCTGAACATCAGTTCCTGTAACCACCAACAAGAGTCATCA




194
GAGATTCAACATACCTAATTGACGCCTAGTCTAGTCACACATGAATGAAAGAAAAAGTAGAAGAGT





GAGAGAGTGAGAAGAGGAAGAAGGAACCGAGGTAAATCTCTCCGAAAGAGCCGCTCCCGATTTTGC





GGCCAAGTCGGAACTTATTCCCAATACGAGACTCCATCTTCCCGAGAGAGAGAGAGAGAGAGACTA





GGGTTTTCA





RMC12
347
NO.
AATGGATGAACTCGAGACGGTTTATCTGACACAAGAAGCAAAACAAGTTAATCCATCAGTGAAAGT




195
TGTAATAACAATTGCAATACAGTGTACAAAGCAAGAGATACCATTTGATCAGCAAGCATGAGAACA





GTCTTCAAAGAAAACTTGCGGTTGCAATAGCCAAAGAGATCCTCAAGGCTAGGACCAAGCAAATCC





ATGACTAAGACATTGTAGTCACCCTCAACACCAAACCACTTAATGTTTGGAATCCCAGCTGGGCAT





TAAAAACGCAAAAAAGAAAATGAACAAAACTAATAATAAACTGTAAAAAGAAGAAGAAGAAGACAG





GAAACGAGGGGTTATCA





RMC13
382
NO.
TGTCAGCATTCAGCAGAAGCTTATTATGAGTTTAATAGCCGGAGAGAGGAAATGAATTAAACCTTC




196
ACGAATGAAAAGGTTGCGGAAGAGTCTCTTCAAATAAGCATAGTCTGGCTTATCATCAAACCTAAG





TGAGCGGCAGTAATGAAAGTAGGATGCAAACTCTGTTGGATGACCTCTGCATAACGTCTGAAAATA





ACACGGACTCAAAGTTACATTTCTATCTATATAATCAACCTTCTCTACTTCATCATTATTTCCTTC





GTACATAGACTCATATAAGTTTCTGAGAGTGCACAAGAACTTACTTCGATGGAAGTAGAAACCTTC





TTTTCACTAATCTTGTCGTATTTCTGTTTCTTGTTCCCAGCTTTCAATCCCT





RMC14
533
NO.
TTGACGGTTACCCAAAATACCGAGAAAAAATAATAATAAGCCTTTGAATGTAAATGCATTTTATTC




197
ATGATGATTCAACATTTCAAATTCAGGATAAAGAAATATAATAAAATAATAAATTCAAACAAAAAA





TAATAATAATAGATAATTACTAGTATTAATTTATGTTGATAAACTATTTTACTCATAAACTTTCGT





TGAATATGCTGTTTTAGTCGCAGTGTTAATCAACCATTATAATTGACAAATAGTAGACCTAAACTG





ACTTTAAAGTTTTTATTTAGCAAAAACACTTTTTCCACAAAATGGGTTTTTAACTTTTGAAATAAT





TATCAGAGATAAGGAACTTAAAATACTTCGGTTTGTTTTATCTATACAATGGAGAAGACCAATGAA





CCATATAATTTAAGCACTTTGGTATAAATAAATCTCTATCCCTCCCTTATATCAAATCTCTAACTT





CAAAGCCTTTCTTCAGAAGAATCATAGACTACCTTCAAATCCTCAAGAAGGGGTGAGGGTGAAGCA





ATCAA





RMC15
711
NO.
AAAGCATCCTTTGCAAGGGGATCTTCTATATGCTATTGAAAGAGTGTTGAAGCTTTCAGTCCCAAA




198
TCTATACGTGTGGCTCTGCATGTTCTACTGCTTCTTCCACCTTTGGTATGTATGCCGTGATCCTTT





CTCCAAAGATGAACAACAGAAAAAGGATATATCTCATGAAGAAATTGATAACATTAGTTTTCTCAC





ACAGTTTTGAGATGTAATTTCAGTTTCTGATCACAAATCTCTTTGCATTGTGTTCTTGTCCACAGG





TTAAACATATTGGCAGAGCTACTCTGCTTTGGGGACCGTGAGTTCTACAAAGATTGGTGGAATGCA





AAAAGCGTAGGAGATGTGAGTTGTCATTAACCTTTTGTTACTAAAGAACATTGACGTTTTATGTTG





TCACACATGACTAACCAAATTTCATGTATTCACTTTCTTCCTTTGTCAGTATTGGAGAATGTGGAA





TATGGTATGGCTCTCTTCCTAAAACATCGTCGTCTTCTTTTCTATACGAAACAGAAGCAGAAAGCT





AACGGAGAGCTTTTTGTTTTTGTTTTAACAGCCGGTTCATAAATGGATGGTTCGACATGTTTACTT





TCCGTGCCTGCGCATAAAGATACCAAAAGTGAGTGTGTATATGTAGATTAGTGATTTGAGATGATC





GAGATTGTTTTCTGTGTTTCATAGCTTTAACCATCCACTCATTTTTGGTTC





RMC16
400
NO.
AAATTGTTACAAAGTATGAGAAATGAATATATCAAATCATACTCTTAAAGTGATTTGTGTTTGGTT




199
TCAAAGTGAATGAATTTATTGAAATAATTTATACAATTGAAAGGGAAAAATAAGCTTATCTTATTG





GCTCTCTGCATTTTAATAATTTATTGAAATAATCTATACAATTAATAGGAAAAAATAAATTTACCT





TATTACCTTAATTAATTAAACAAAAAATAAAAATGTATGCATGTGTTATAATACATAGTATTCAAC





TATTACCAGCATAATTTATATTTAACTATTTTTATTAGTATTTTATAAAGGAGCCTAAAATTAATT





AAATAAAATATTAAAAATGCATGCTTATGTCATAATATATTTGTAGAGAATGAGTAAAATGTTTAC





TGAA





RMC17
554
NO.
TTTCCACACAAATCGGATTTAATAATTAAAAATCCAATAAAACTAAAATATTTGCTATTAACCTGT




200
TAATCTACTCTGGCAAAACCTAAAAGAAAAACTTATAATACTTTTTGAAAAATTAAATAAACTTCT





CTTATACTTTATATAAAGTACATAAAACTAAATAAATTATTTGATTTGTCATAGTATATTTTTAAA





TTACACATAAAGAAGAAGGTTTGTTTGTTATTAGTTATTCCTTTCATATATATATATATCTATCTT





ATTAAAACAGGAACATTACAACTTTTTCTAGGTGGATTTTTAAAGATGGACCTCATATATTTAAAT





TAAATGTCTCATTCTTTATATATAATATGTACCATACTCTAACTTTGCATTGATGTATTTCCTTAA





ATACAGTTCTTCTTTTTGTCCATATTCCATATATGATTTTTACATTTATTACATGTCGATTTAAAT





AAGATATATACTAAGAATACTAAAAATATTAATCGTTCTATAATTACCCTATACAATTCATTTTAA





ATTGATCAGTAAACTTTCATTGGCCA





RMC18
525
NO.
ACCAAACCGAGAACAAAATAGGTGTCTAAATTTTTAAAATACAAATTATATTCTTTCAAATATTAC




201
GTCTATTCGATTTCTAAATAACCGAGTATCCTGAAAGTACTATTTATAAGCTAAATTATCCATAAA





AATACCAGAATATTGTTTTCAAAATATTTAAAGTATTTGCATTATCTGATATTTTAACCCAACAAT





ATGAACTACCTAATATTAAATTGAAAATCCTAAATTATCCGATATATTTATCTATAAATTCGTGAT





TACCGGAAAACTCAGGACAAAGCAAAACTGAATTGGACCTATATTTTTCTGGAATATTAGTCGGTT





TCCAACTATACTACTAAAAAACAAACCAAAATAACAAAATAACAACACAACTAAAACCAGACCATT





TTGTAAATAATTGAACGGTTCCTGAATTTGTAGAACCATAACACAACTAAAACCAGACCTTTTTGT





AAATAATTGAACGGTTCCTAAATTTGTAGAACCAAAACACCAAAAAACCAAAGTATTCGAACC





RMC19
543
NO.
TGGAGGTGTCAAAGTGTGGCATCACATAAGAGTTTAAGAGTTTGTTGTGCTTTAGTTTTTGAGTGA




202
GTTTTCTAAGGCAATAAGAAGAGTTATTTCTTTACGAGCAAGCTTCTTAGTTTCTTAAGTTCTCTG





TTTCTACAGATTTTCTGTTTATATTACTTACTTGAAATATTCTTTTCCTATAAATTCTTATGCAAA





TTTTCAGAACAATCTTGTCTGCAGATACATTTTGATTTTATAGTCTGCGCAAGGCAAATACAGTTT





TGATTTAATGATACAGAACAGAGTGGGTTAGTTCCAGGTTTGGTCACGAACAATCATCTTTTACAT





TGGTCTATGTAAATCAAGTCATATCCAGAAAGCAGATAGGCTTGTTTAAGAGATGTGGGAGATGGG





TATTTGTACACACTGAGTTTTTTATAACACTTTTACCAAGGGTGTTTCTAGTGTTAACAATATCGA





TAAAGATCTTAGATCTCTATCTCTTCGCTACTATATGGAGAATAATCATCATGGTATTAAGCCAAA





TAAAGTGACTTGCG





RMC20
463
NO.
GAACCACGACTTTGGGTCTGANATTTAACGGGACAGAACAGAGTATACCAAGACTCATGGGTTACA




203
GTGACTCGTCTTATAACACTGNTCCANACNATGGGAAGAGCATCACAGGCCATGTATTCTACCTCA





ACGACAGCATGATCACTTGGTGTTCACAAAAACAAGAAATTGTTGCATTATCATCATGTGAGGCAG





AATTTATGGCAGGTACAGAAGCAGCCAAACAAGCTATATGGTTACAAGAGTTACTCGGTGAAATCT





TGGAGCAGTCGTGTGTAAAGGTGACTATACGGATCGATAATCAGTCTGCTATCGCTCTTACCAAGA





ATCCGGTCTTTCACGGAAGAAGCAAGCATATACATTCACGATACCACTTCATAAGAGAATGTGTTG





AAAAGGGACTGGTGAGTGTAGAACATGTTGCAGGGAGTCAACAGAAAGCCGACATTCTAACCAAAG





C





RMC21
269
NO.
GAGAATATTGGAAGAAAGCGGAATGAAAGACTGTAACTTGGTACACACGCCAATGGAGTTAGGACT




204
AAAGCTTTGCAGAGCCGATGAAGAGGAGGAGATTGATGCTACAATATATCGAAGAAACGTGGGGTG





TCTTAGGTATTTGCTTCACACCAGACCGGACCTAGCTTATACGGTTGGAGTTCTGAGCCGTTATAT





GTCGTCACCTAAAACTTCGCATGGAGCTGCCATGAAACATTGTTTGAGATACCTCAAAGGAACCAC





GACTT





RMC22
747
NO.
GCTCTACGAGTGAGGATCAAAGTCACGAGAATATGATCAAAGCAGAGCCTGCAGAAACAGAAACAT




205
TGAAGAAGAAGACAGTCATGAGAATCAAGAACCTGAAAGTGAGAATGAAGCGGTACCTCTAAGAAG





AAGCGTGAGACAAACCATGACACCTAAGTACCTGGAGGATTACGTTATGGTTGCGGAAGAAGAAGG





AGAGTTGCTGTTGCTAAGTATTAACAACGAACCTATTAACTTTGCAGAGGCAAGTGAGCGTGAAGA





ATGGATAGCAGCCTGCAAAGACGAGATAGCAAGCATAGAAAGAAACAGAGTATGGGATCTAGTTGA





TCTTCCACTCGGAGTAAAGCCTATTGGTTTACGTTGGATCTTCAAGATAAAGCGAAACTCGGATGG





ATCAATCAATAAGTTTAAAGCTCGACTGGTTGCAAAAGGGTATGTACAACAATATGGAATTGATTT





TGAAGAAGTATTTGCACCGGTGGCTCGTCTTGAGACTATAAGATTGCTTGTGGGTATAGCAGCTGC





AAAAGGATGGGAAGTACATCACCTAGATGTTAAAACGGCGTTCTTACATGGAGAATTAAAAGAGAC





CATTTATGTAACTCAACCAGAGGGCTTTGTGGTGAAAGGAAGTGAACGAAAGGTGTATAAACTCAA





TAACGCATTGTACGGATTGAGGCAAGCACCAAGGGCGTGGAACCATAAGTTGAATACTATTTTACT





TGAGCTTGGATTCCGAAAGTG





RMC23
219
NO.
AGCTTATAGGCTTCTAGACCCAAAATCTCGAAAGATAGTAGTAAGCCGAGATGTTGTTTTCGATGA




206
AACTAAAGGGTGGAATTGGGGTGAACAAAACAAGGAAGATGAAAATTTTACTGTCAGTCTTGGAGA





ATTCGGAAATCATGGTATTCAAAGCTCTACGAGTGAGGATCAAAGTCACGAGAATATGATCAAAGC





AGAGCCTGCAGAAACAGAAAC





RMC24
363
NO.
AGCTTTAATTCATGTATTTTTACAAATTTTGTTACTAGAAAAAAAAAAAATTTAGTATTAATTAAA




207
ATAATTAGTGACTAGTCAATTTTACTTATAACAAAATCTTTTTAGAAAAAATAAGAAAATCTTTAA





AAAATTCAAATATATTTTTAGAAAATACTGAATTAGTTTAGTAACAAAAAAATCAAAAATCATATA





ATCTTCCAAACTAAAAAATAATTGTGTAATTTTCTAAATGCCTCTTGACCAAGTATACAATTTAAA





AAATAAATTAAAACTCAAAATGATAATATTCCAAGTTTTATAAAATATAAAGTCATACAAGTTAAA





ATATAAATTTTTGAAATGTATCACAAAAAAATT





OPC2
678
NO.
CTGTAACTTTCAACCCAACTCGTAGAAGTAAGGACATCGTGATCAAAGATCCAGAGATGCTTCATC




208
AGCCTGCATCTCCAACCTCGTCCTGAATAAACACACACAGAGCTATGAAAGGGTACAAAAAAAAAC





AAGTACTTAGGCAGCTATCTGGAATCTAAACAGTTCAAGAAGGTTCTAGATGAAAACCCTAAGAAA





GAAAGAAAGATTCTGAATGCCACTCAAAGCATTAACAGTAGGAAGCTGACTTACTTTTGACCGAAA





CAGGCAGGAAGGTTAATGGAGGGGCACATGTCAATCACATAAAATAAAATGACACTTAACTTACAT





TAGCTTTAGTGGCCTCTGAAGTAAAGTATGTGGTGAGGAGGCCATTCAGTTTGGGTATAATATCAA





CTCTGCCACGGGATTGTCTTTGAGAAGACCCGTTGCTAATACTTCTTCCTGAAAAAAGCCAATTAA





CACAAGCTTTGATACCCAAAGACATAATTAAGATGTGAAGATATGGTTCATAGATAAGCTTTATAC





CTTCATTGCTTCAGATCTTGAAGGTGCGTCAACAGCAAGAACAGCTCTTCGAGCTCTTCGCACAGT





CTGTCCTACCAGTTCATATGGCAGCAATTCTCCTCTATGCTGCTGTGTGAACCTGAAGAAAGCTAA





GAAGAGTAATCCCCAAAA





RMC25
364
NO.
AAGCTTGATCAAAGATCACAGTCTTACAAAGAAACAGAAAACAATTTCAGTGAAAGAACAGTATTT




209
ACCTTATTTACTCTAAAATTTTTAAAACAGATTTTTTTCATGTTCAGTACCAACATAGATGGAATC





AAAAATATTATTAAATCATCATACTCCATCATGTATTACAAACTGGTGGATTTAGTATTTTTGAAG





ACCAGACATATGCTTAAAATCATAAGATTCCCGTTACTGCTACTGTGCTACACCAGTCTAGCCGGT





GACAGACACATAGCTGATATTGAAAGTTCCTTGAAGAACAATGAGTGTGGTCAGAAGTTGCAATTA





TATTGTTTGCAAACCTGTTGCTCATTAGTTTGTT





RMC26
201
NO.
CAGACCGTTCAAGTTCATGGCGAAGAGAGAAAGAGGGTTCAGTTTCGCATTGTTGACGAAGAGTTT




210
GTTTTCACAATTTTTTTATTTCGTTAGCTTATATACGTGATATTGGTTGCTTAGTTTAATAGTTTA





TATGCTTTTATATTGACAGAGGAAACAATATTGCATGCTGTCTTTGGGGATCATATGCCGAGCAAC





TTG





RMC27
238
NO.
CCTTCTCCAAACCGGTAAACGGTTAGCCACCGCCGCGTCCCGTCGCCAGAGCATATCCTTATCCGA




211
CGACAGCTTCATCCTCTTCTCCTCCGCCGACGCCGCTTCCTCTTCTCTCACCGAATCCGAAAGCGT





CGCTCACGTGCTATCTCACATCAAGCTCCTCTTACGACGGCGCGCCGCCGCACTCGCCGCTCTCGA





CGCCGGACTCTACACCGAATCGATCCGTCATTTCTCAAAA





RMC28
623
NO.
AGACCAAGAGGAAGCGTAGCTTCCGCCTTCCCCTTCCTGATGTTATGAGTGGTCCTACGATATCCA




212
TGGACCACTTCATGAACGGGACGGAGCGGATATTGAGGATAGTTTTTCCGCAGGCTGATGTATAAT





CGGTGTATGCCTTTGGCATTTATCACATGAAGAGGAGTAAACCTCACAGTCAGCGATAATGGTGGG





CCAGAAATAGCCCTGTCTTTTGATTCAGATAGCTAGAGCTCTGCCCCCAAGGTGGTTTCCACAGGA





GCCGTCGTGCATTTCTTTCATAAGATTGATAGCATCGAGACCATGGACGCATTTTAGGTAAGGTCC





GGAAATACTTCGTTTATGGAGGGCTGACTCGATTATGCAGTATCTTGCGCTTAATGCTTTGAGTTT





TCGGGCCTTACCCTCCAAGATGTACTGCATGATTGGTATTCTCCAATCCTCTCTCCCAAAGATTTT





TTCATGAAGAGATGAGGGCGGGTGTTGTTCAGGTCCCTGTGTGTCGTGACCTGATGTCTTATTGCC





CCCGGAGATATTGGTCGGATTAGGCTCGAAGGAGTCTGAATTCTGAGGAATATCTCCAGTTCTGGT





GTTGTTCTCCGGAGTCTGGGTTGTTTCTT





RMC29
198
NO.
CAATGATTTATACTTCGTTTTTGCTTTTTTTTTTTGTTTTTGNGAGCAGGTGGATGCCGTGGTGTA




213
CCTAGTGGATGCATACGACAAGGAGAGATTCGCAGAATCGAAAAAGGAACTGGACGCACTTCTCTC





AGACGAATCTTTAGCCACCGTCCCCTTCCTCATCCTAGGAAACAAGATAGACATACCGTACGCTGC





RMC30
525
NO.
CATTTGGTTTGTCCGTGTGTCCCATATGATTCAAAATCTGAGAGCTTATTATGTCTATATAAAACA




214
CCTTATTAAAATTAAGGTCAATATCTCATAGGATTGTGTATAGATTCGGCTGTGTGTACTTAGCTA





CTCAAGTAATTAGAGCCCCACTTATCTTATCCACTTTCACTAATAAATCACTCGTGCTTGAATAAA





GAAGCTGGAACCGCTTAATTTTTATCAAAATCAAATACCGGTTTAACAGCCGCCGAGATGCACATT





CTCGACACCGGAGCTCGTTTCTCCGCCGTTAGATTCTCACCGGTATTCAATCCTACTCCCCGCAGA





AGATACGTCATCGTAAGGTATCTTCTTCATTTCTCCATCTTCTTCTACTTCACACTGAGTTGTCTC





TCTCTCGCTGCATCCAAATCATTGAGTCTCTCTCTCTCTCAGGGCCAATCTCCCGTTTCCGAAGCA





TCAAGCTAAGTACCACAAAGAGCTCGAAGCCGCCATCGATGCTGTTGAAAGAGGTTGTCGCCT





RMC31
379
NO.
CATTTTCTTTAACAACGCGCTTTTGATTTCCATTGACCGTACTTTGAAAAACACTCAATTCGGCCC




215
ATCACATGTCATACCTTTTTCTCAGCAATAGTTCATTTCGTATTTTATTAACTATTTTAGCTCTGT





TCTGATCATACATCTATATATATGGATCATATACAATATGAAATAGGAGTCAAACATGAAGCTCCG





AAGAAACAAACATCCTAAGCAGCAACGGCTAGCAACATAGCCTAGTTGGCCACCTACTTTAATAGT





TTTAAACGACGACTAAGAAAAATATAAAATGAGCACACCGTCTTTTAAAATATTCCATGTGGTGAT





GTATCCACGGTTTGCACACCTTCCTAACCGTACTACATGTCGCCGTCGT





RMC32
446
NO.
TCTCTCACACTTTCTCTCACCAGATCTAAAGCTGACCACAGTCAGCGATCACAACCTTCTTCGAGG




216
TCCTTCCACTGTCAGATCCAACCTTCTCAATGTTCCTAACGACATCCATCCCTTCGACAACCTGAC





CGAACACAACGTGCTTCCCATCCAGCCACGACGTCTTCTCAGTGCAGATGAAAAACTGAGATCCGT





TCGTGTTCGGACCAGCGTTGGCCATGGACAGGATGCCCGGACCGGTGTGTTTCTTGACAAAGTTCT





CGTCCTTGAACTTCATGCCGTAGATCGACTCTCCCCCGGTCCCGTTCCCGGCGGTGAAATCTCCTC





CCTGGCACATGAACTTGGGGATCACGCGGTGGAAGGCCGAGCCCTTGTAGTGGAGCGGCTTTCCGG





ATTTGCCGACTCCCTTCTCNCCGGTGCAGAGGGCGCGGAAATTCTCGGCG





RMC33
275
NO.
CAAATCAATACCATTAAAAGTGGATCATTATCATTTTATACCATTAATGAAAATTTCATGTTTTTC




217
AAAAATATCCTAATTTTACAAAGGATTATTAACTTTCATTAATAGCATTTTTGTCTTTTGATTTTG





GTCATGCAGACATAAATTTAAATAGATCAATGAATAATGAGCTTACACATACTTACTTATAAAATA





TGCTATTTTTTATTTTATATAAATATTCTAATTTTAAATATTATACATATATATTGTGAAAGGAAA





TTAATCAAAAA





E33M47
122
NO.
AATAGAGGGAGAGGATGAAAGAACCACAACCGCATACAGATACACATGTGTTAGTATATGAAAACG




218
CACGTATGTTTTATAAATAAAATCCCTTACTTTATAACAAAACCTGTTAGGTAGCT





E32M50
252
NO.
TCACATTAGTAAAACGATTGTCCACCCAATTATAACCAAAAGCGGATCCCTATTCGTTACCCGTAA




219
ACCATAAACACATTTTTTTTCTATTTTCTAAAACCACACGATGTATCTCTTCTTTTCTAGAATTAG





TGTTCATAGAAAGTGAGTCATGATTACTTTTCAAGACGAAAAATCGATCTGAGGAAGTTTTCTAAG





ATGAGTACGTGCGGTTCCTTTTTAGGACCACAAACGGAGTCCAAAAAATCAATC





OPN20 
587 
NO.
CCTTAGTTTAGTTGTAGGTGGTGGAAACATATATGGACGACGGTTTCTGTTCTCACCTGTCGTCTG




220
TTTTCTTCTTAATTTTTGCTCTCAGATCATCAGAGTTTGGTGGGAATGGTTAAATCGGACACTTCC





TTATTTGGAATTTACCATTGGGAAGCATCAGAGGGAGGGAACTGAGAGTATGCTTGGAGGGATGGA





ACTGTCTTGTGTAGCCTTCTGAATCAGCTTAGTCCTGGTTCTGTGACAACGGTACTTATGAATTTC





TATTTACTAGGATAATGTACCTTGTCGTTTTCTTTTTTTTTCTTCCTTGTCTTTGTCATTTGTTGC





TAGCAGGGCCGGCTCTGAGAATTCGGGGGATATAGACGGTTTAAGAAGGAATTTATAAATTTGGGG





GCTGAAATTCCTATTTATATAAACTGGGGGTCTATCCATATATAATTTTTCAAAAAAATTTCGGGG





GCTTAAAGGCTAATGTCTCATCCGGCTTGGCTCAGGGCCGGACCTGGTTGCTACCCTCACACTCTT





CGGATATTTATATAGGGAGGCAGCTTTGAGCCTGCTTATGTTAAAATTGAGCGGTTTCT





OPH15 
637
NO.
CCTTGGCTATGTGCTTATGTATTTTCTTCGTGGAAGGTATATATCTGCTTCCCATTTGCTTTTATT




221
TGGTTTCCATTTCACCTTACCCTCTGTTTCTTCTTGCTAGTCTGCCTTGGCAAGGCCTTCGTGCGG





GTACGAAGAAGCAGAAGTATGACAAGATCAGCGAAAAGAAAAGGCTTACACCCGTTGAGGTAATTA





GTCTTAAAAGGCACCTGAAGTGTCATTTACTTATCAAAAGATATAATTTATTATCTCCATTGACAG





GTTCTCTGTAAATCCTTTCCACCCGAGTTCACATCGTACTTTCTCTATGTACGATCATTGCGGTTT





GAAGACAAACCAGATTATCCATACCTAAAGAGGCTTTTCAGGGATCTTGTTCATCCGAGAAGGTTG





GGGAAAACTACTTATGCTTTAATATTTCACATAAACACACAATATGTAAAGTTTTTTTTATAATGT





TATAATATATTTGCAGGTTATCAGTTTGACTATGTATTTGATTGGACAATCTTGAAGTATCCACAG





TTCGGTTCAAGCTCCAGCTCCAGCTCCAAACCAAGAGTAAGTAACTATCATTTTCAATTCCTCTTG





AGCATACTATCAAACAAACCCTCACGATTGTCTCTGTGTTTTA





IN6RS4
235 
NO.
CATTGATACATGAATGCAAAGAAGAAAAGTCCAGACCTTTGTTCACATTTTGGCCTCCAGGACCAC




222
CGCTTCTAGCAAAGTTAAGCGTAACATGGTCTGCAAGTATATACCAAACAGATAAACAAATGAAAC





CATGAGTATGAACAGATCGAACTATAATTGTAATTCCATCAAAATCAGTATAAAATAGAGTTCTAT





AATAACATTTGTAGCATTGTCTGTAAATGTTTTCATC





E33M58 
281
NO.
CTGCATAAAATTATCGAAGACAGATAACACAAAGAAAGGACATAATTGTTACATTGAAACAACATT




223
GTTATTGTTACATGTAATTCCAACCCACTGGGTTCCACAAGGATCAGAGCCTTTCCAGTTCTCAGG





AAACCTGGTCCATTCACTCTTCAAGGCTTGTAATGCAGAAGCTGCGCCAATTTTGAAAAGAAATAA





AATATTCCTATATCTGTCTGAATAACTCGGATCATGATCTAATATACTTACCGTCTAAAGGATTTG





TTAGCGCTGAAACAGAA





E32M59A
406
NO.
CTTTGTCATTGTGTGTGTGTGTGTGTGTGTACCGGGCCGATCTTTGTCATTGTGTGTCATTTTTAG




224
CTGCAACAATGCATTTGAAAAAGCTGGAAAGAGACGAGAATCTAGTGGCTGCATTCTCTTACATCC





ATTGTGGATGAGCTCCAACTGTCCAACAGGCTTTGAAAGAGTTTGGTATAAATGATTCACATCTTG





ATGAAATGATCAAAGACATTGATCAAGACAATGTGAGTAGCTATCTTTACAGCTTTCATTAGAGAG





ATGCTTATGGTGTATGGTTTTTGTAGGATGGACAAATAGACTATGGACAGTTTGTGGCAATAATGA





GAAAAGGTAATGGCAGTGGAGGGATTGGTAAGAGAACAATGAGACACACTCCACTTGGCAAATTGG





AAATCATATT





E32M59B
350 
NO.
AATTCTTGCTCCATTATGATTTCACCAAGTCAACAAAATCTTCTTTCTACTAGTGCGATAGATCAC




225
TAAGCAGCGTAGTACAACAACCACATGGGAGGGAACACGATAATGAACAAACCTGTTGAATATTGA





TGCGGCGGGTGGGTGCTCAAGAAGCTTACTCGTGAAATCGAGTCTTGCAAAGAAACCTAAGCTGAG





TGTGAGTAATGAATTTATACATAAAATATAAATGGGCCTGAACTCCAAGCTTATTCCAAGTACTAT





GGGCTTTAGGCCGTAATTCTGTAAGCAAAATAAAGCCCAAATAATCTTTTGATTTTTCTTTTTTTC





TTTTTCCTGATCGTCTTGTG





OPH03
591
NO.
TCCACTCCTAGTTCACAATCTATTTTTTTCTTTTAAAAACATAGTAAACATACAATATAACTAATA




226
GTATTTTATACGTACTATCATATAAATAATCACATATATTATATTTCTAAAATTAATGTGAAGTAC





AAACACTTGTTACAATTTTGTTTGAAAGATTTTATTTGTATATTAGAAGAAACTTGTTACAATATC





CTTCTTTAAAAAATCATGTGCAATTTTTTTAAAAAAATATGGTTAAAGATTGGAGCTGGTTAAAGA





TGGTTAGACAGAAGATAAATACTCTTTAACCATAACACAACCCATTAAAATGTTGAAAAAAAGAAA





GGTATAGGGCTTTAATAATGAAAGATCCGTGAGATGCAAGATTAATATATAATCCAAACTCAATGT





TTAATACCAGTGGCATTCTGATGTAAATAATGAGAAAAATTTAGGGTTATTTCTCATTTGCACTTC





ACTTTTAATAGGATAGATAAGACCATGCTTTAAAAAATTGTTAGTAGTGTAGACAGATATGGTGTT





TGTTAGATATATCGATCAATTTCAGATGTTTTTGTCCCTTGTGTATTCCAACATTTTGTATA





RME01
454
NO.
TCCATTGCAGAATTCACCTGCGGAATGTAATTTCCTTCACCTAGTCGTCCACCTGCAACACAATCC




227
GCAAGGGTGTGTTGTAGCTTCTCCATTCCTTGAGATAAAGCGTCTTCAGCTTGCTGGCAAGATTGT





CTTAGATTGCATACATCTAGAATCTGCTGATCCGTCATGACATCAAAATGTGGCAAAAGAACCTGC





AAAACAAAGATTTAAAAACATTGTATTAGATACAACGTTCCAAGTCAAAAGTTAGAAGAGATCTTA





AATAATATATAAAGAGAACGGCCTATAAGATTGATTTTTAGGTTAACACATTATTTTAGTTGTGTT





TATTTTGATTGTTCTTTGTTACTTGTTTTCTACCTTGATAAGATCCGAGGGTCGAAAGCCGCCAAT





CCATATGAAAAAACGTTCTGCAGAAGTTCTCCACATTCCCGACATGACGAAGAAAACA





RME02
233
NO.
CTTGAGGGAAGGAGACGAGATGAGAGTCGTCATCAAAGATTCTACAGTGAAGAAGAAGAAGAAGAT




228
ATTTTCGTCTCTTGCTAACGGAGAAAGAGAGAGTGAAGTGAAGTGTGTGATATATCACGTGATCAT





CACGTGTGTTGATATCTTCGTCAATGGCGCCATTTTTCAAGGCCGTATTTTGGGCTTTTAGTGATG





GCCCCCAAATTTTTAAAAAACCCATGACCCAAAAT





RME03
533
NO.
ATATCCTTAAACCCTTGCGCAATCTTCTGATCTTCTCCCACTGGCCTTTTAGCCTTCGCCTTTGCA




229
GCTTTAACACCAACAGGCCTTTCCATAGCGTCATCATCCCCATTAACACTTGGCATAGAGCCTGAT





GCCTGAAAAGATTGTTCTTCCCCCACCCTCTTTCTTTTCGAACCTGAGCTTTGTTGACTAGTTCCT





TGAGTCCCACACCATTTCTGATCATTCCTAAGCTCTCTCCACGCATGTTCCAATGAGAACTTCACA





TTGTAATCGCTGAAGAATATTGCATATGCTGCTTTCAAGACGTCATCTTCATTCTGCCCACTGCTC





CTCTGTTTTGTGGCAGCTTCAAATGACCCCACAAACTAGCAGACTCCTTCATTTATCTTCCCCCAC





CTTTGCTTACAGTGGGTCAGCTCTCTTGGAGGCAAACCAACCACCTTTGGACTTGCGTTGTAGTAA





GCCGTGATCCTCTTCCAAAAGGTTCCTGCTTTTTGCTCATTTCCAACGAGTGGGTCCTTGGAGGTA





TTCAA





RME04
699
NO.
GGTCTCAGGTTTTGTGGGAGTAATATCGGTTACCTCTTTTCCTATTACTTTGTCCTGTATAGAAAA




230
ATACTCATACCCATTATCATTTCCCTTGCGTAGAACTATATTTTATATAAATAGTTCTATTTTTTT





TTTAAATGAGTCGTTGAAACTTAGAACGCAAGAAAAGCTTTTATCTTTTGATCATGTCCTAATTCA





TAAGAAGATATCATTTATTTTTATAAAATATCAAGTTATATCTAACGATTCTTAAACATGGTCGAA





TGTTCAGAAATAAAAATGAAGTCTTTCCAATAATAAATAAAATCTCTTCTAAAAATATTTATTTTC





AAAACAAACATGTTTATGTTTTTTTTTTTTGTTTTTTGTTTTTTTTTGAGAATTCAAAACAGCCAT





GTTCTGATTGTATAACCCACTTACGTACAAACATTTAAATGATTTACGTACAGATAAATGTGGAAA





ACGTTACCTCGTGAAACAAGGGACTGAGAGATTGGCTTTTGCCGTGTTCCTTCTTCACATCATCTT





CAACCAGAATCTCTTTTCCTTTCTCGCTCCGTCGTGCCGTAAGCAGCTGTATCAACCGCCTCGTTA





GGAGCATTGCTCTGGCTCTTTTCCGCCGTAATCTTGTTATGATCACTCGGAGCCGCCATATCTCTC





TCAACCGGAACCATATCCTCCTCGGAATCTTTGAGAACC





RME05
477
NO.
CTTGGTCACACCCATCTTCTCTCTGCGTAAATGTTATGCAGAGTTTGCAAAAGCATTTGTCCCTTG




231
GTGTGAGAATCCTCTGTGTGCTCTAAATGGACCCGGTTCGAATATATTCGATACTATCCATAAACA





CATCACAAACCAAGTAAGTTCTTTTCTTCTAATGGGCTGATGATGTCCATTTAGTTTCCGTCCATT





TTCCGATTTAACTTTAACGTAACGTTTATATGTCCATGCATAAGGACAATTAAGATACAAAGATAA





ATGAATCAGCCAATATGGAAATATAATTATTTATTTCCCTTGTTGTGTAATATCCCCTGCTTGATT





CAGTATCAAAAACATTGAATATGCTTCCAAATAAATATATTTGAATATATATTCTACTACAAAACA





TATCAATTTACGTCGTCTTAGGAAACCCTTATTTAATCAAATCTTTGTCTCTCTTTCTGGCCGCAG





AGAGTTTATCGGACA





RME06
480
NO.
ATCAACCACGTTCATCCATGGATTTCTGGAAAAGGTATCAAATAAGAGGAAGAAGAAGATGGAGAA




232 
AAAGGGCATCAAGTTAAGAAAACAAGTTTTTTTTGTTCGAATTGAACGTTTGATTAAATCTACAAA





CTAAGTGGATCTAAGAAGAAGTGCCCAAGAAGAAGAACAAGGAGATCGAGTAGCAGAGAACAAGCT





ACAAAGAAGTGAGAAGAAGAAGAAGAGACTTGAGCCACAAGAAACAAAAAAGTGAAGAAGAAAGGT





GAGTGTGAGAACAAAAACAGAGTAAGTGAGTAACCAAGAACAAAGAGAGTAACAGAGAATAAGCTA





CAAAGAAGTGAGAAGAAGAAGATACTTGAGCCACGAGAAACAGAAAAGTGAAGAAGAAGTGTGAAT





GTGAGAACAAAAACAGAGAGTAAGTGAGTGAACAAGAGAAACAAAGATGATGGAGAGGCTGGGCTG





GCCGAGAGTATTTGAGTT





RME07
579 
NO. 
ATTTACCAAATGGATCACTCTGGATATTTGGGTTAGAATTTAATTTTAAATTTGTTAATGGGACAT




233 
TATGTCAATTAACTTATTTAGTTAATTTTATTCTTGATAAACCCAAACAAAATATATTAAAATTTG





GTGACTTGGTCAAAGTCACAATATTACTTTGCAAACTAACCTTCAAGATCAAGGAAATCAATTCCA





TAATTAGAATTGATATGTACGTTAGTTGACTCCTTTAATTTGCATAACGTGTACTTTCTCTTCAAG





TTATAAAAAGAGATCACTTGTGCAGTTTTCTACGCACGGAGAAATAACAATTCTCCATATTTCTTT





TTTCTTTTGATTTGTTATTTTGAGTCTGAGAGTATACACAAAACTAGTTTCGTCGGGCTTCTGATA





GAGTGACGCAAATCAGAATATTTTTTGCATTTGTATCTTGGGACTCATTACGTTATTGAACCGTCG





CACTACGAGCGTATTTTGAATTAAAGAAAGAGATCTCGCCTCTGTAGTTGAATCATCATTTTCTTA





ATCTTTGGTATAATCTTATCAAATTTATTCTTTACAATGTTCAATTCTCGG





RME08
496 
NO. 
CAATTCCACAACGTAGCAGAGCTTTGAAACGGAATAGATATCTGACTTTTCTAAAATTTGGTCAGA




234 
TTGAACCAAATATTACACATGTGAAATTCGGTAATTAGTTAATATTTAAGAACTAAAAGTCGAGAG





AAAGAGGCAGGCGGAAACGAGAGGTGGGAAGGATTGGATACTTCCACGCAAAAGGGTATCTTCTTT





TTTTTCCTCCTCGGATACTTCCGATCATGTTATTAATTTGAGGTTCTTAATTTTTGATTTGACAGT





TTTTTTTGTTTTAATTAAACTAAGAACCGACAGTTTTTTTTTGTTTTTTTTTCATAATTAGTAAAG





GGTTCTTTGGGTGGAGTTCTTACCGAAATATAAGACTATGATTAATCCGGGTTTTTAGGCTGGGGT





TCTTAGCTTTGGTTAAGAACCATTTCTTAGCTTTTAACTAAAAAAAACTAAAAACCTGCTCTCAAA





AAATAGATATAAGAGCCGGTTCTTAGTCGAAAAG





RME09
574 
NO. 
AGCTTGGACTATGCCGTTTGCGTTCTGTACAAGAGAGAAGAAATGGTGTGAGTTTGCAGAGCCTGT




235 
TGATGGCGAATCAACAAAGTTTCTTCAAGAACTAGCCAAGAATTATAACATGGTGATTGTGAATCC





TATCCTCGAAAGAGATATGGATCACGGTGAAGTACTTTGGAACACAGCTGTGATTATAGGGAACAA





TGGAAACATCATTGGCAAACATAGGAAGGTTAACTTGCACTACAAGTCTCTTTTTGCTTCTGTCTT





TTCTCTTGTGAGCTAACTTGTACTTCTTGGTTTGCTAGAACCACATACCGAGGGTGGGAGATTTTA





ACGAGAGCACGTATTACATGGAAGGAGACACTGGACATCCTGTGTTTGAGACGGTGTTTGGGAAAA





TTGCAGTCAATATATGTTATGGAAGACACCATCCTCTAAACTGGTTAGCTTTTGGTCTAAATGGTG





CTGAGATTGTCTTCAACCCTTCAGCTACTGTTGGTGAACTCAGTGAACCAATGTGGCCTATTGAGG





TTTAACTCCTAACTCCCCATTTTTCACACATAGCCGGTCCTGAAAT





RME10
570
NO.
TCGAGAATCCTCTACAAACGCACACCTTGGACATGCTCAGAACGGATATTAAAATCGACAAAACCG




236
CCGCACCAGTCATGAACTGGCATTGGTTTCTTTGTGTCTTCCCCATTTTTAACAGCGGAAACACAC





CTCATGAACATGTTACGATTCACTCTGCTGTGTACAAGCAGAGCTCGTAAACCTGTCCTCGCAGCT





AGTTGACTCATGACTCGATACACACACTCGTTTCAGATCATATGGTCTAATGGATTTGGATATTAT





TCACTTCTCGGTAAGTCTTGCAGATGTTAGGAGAAAGGAGAAAATGTGACAGCAGCTGTGTTCGCG





GCAAGTGCTGCTAAGTACACGTGGTTCGAGTCTAACCGTTGTTTCATACTAAAAATATTTCTTCTA





ACGGTCGTGATTTGATCATTTGAGTAGTGCAAGCAAGCGTAGGTGAATACACTAACCAGGGTGCTT





AAGTGGGGTGCTTAATAATTTTTGGATTTAAAACAAAAAAAAATATCCTAAAAAATAAAAAATGCT





ACTTGAGGGGTACTTAATTAAGCTGTCGAATAAGTGGTGCTT





IN10RS4
288
NO.
CAGAACACAGTTCTATGACACTGTCGATAGTAACATCCTCTGCAAGTACCAAAGAGATAGCAAATG




237
AAACTATGTAAACAAATCAAAATTCTAAATTTCTCCATCACAAGGACCTACAGAATAGAGTTATCA





TAACATTTTCTGTAAATATTTCCATCAAAATGACTAGAGAACAGAGTTCTTATAACATTATCTGTA





AATGTTCCAACAAAACCACTACATAGCAGAGTTCTTATAACATTGTCTGTAAATGTCCAATCAAAA





CCACTACAGAACAAAGCTCCTATA
















TABLE 5





Summary of Pedigree Leading to SRF Lines




















Line
Gnrtn
Pedigree
Genotype
Phtp
Female





01SM001
M1F1
M143/96DHS60
Rf{circumflex over ( )}1rf/rfrf
S
SNH09984-M143


01SM002
M1F1
M336/96DHS60
Rf{circumflex over ( )}2rf/rfrf
S
SNH09984-M336


01SM005
M1F1
M662/96DHS60
Rf{circumflex over ( )}5rf/rfrf
S
SNH09984-M662


02SM008
M2F1
01SM001-23/NS4302MC
Rf{circumflex over ( )}1Rf/rfRf
F
01SM0001-23


02SM009
M2F1
01SM002-15/NS4302MC
Rf{circumflex over ( )}2Rf/rfRf
F
01SM0002-15


02SM011
M2F1
01SM005-02/NS4302MC
Rf{circumflex over ( )}5Rf/rfRf
F
01SM0005-02


02SM086
M3F1
96DHS60/02SM020)X
Rf{circumflex over ( )}1rf/rfRf
F
96DHS60


02SM087
M3F1
96DHS60/02SM024)X
Rf{circumflex over ( )}2rf/rfRf
F
96DHS60


02SM088
M3F1
96DHS60/02SM034)X
Rf{circumflex over ( )}5rf/rfRf
F
96DHS60


03SM104
M3F2
02SM086)A6
rfrf/Rf{circumflex over ( )}1rf/Rf{circumflex over ( )}1Rf{circumflex over ( )}1
F
02SM086-16


03SM113
M3F2
02SM087)7
rfrf/Rf{circumflex over ( )}2rf/Rf{circumflex over ( )}2Rf{circumflex over ( )}2
F
02SM087-07


03SM118
M3F2
02SM088)9
rfrf/Rf{circumflex over ( )}5rf/Rf{circumflex over ( )}5Rf{circumflex over ( )}5
F
02SM088-09


04SM140
M4F1
NS4304MC/03SM104)X
Rf{circumflex over ( )}1Rf
F
NS4304MC


04SM141
M4F1
NS4304MC/03SM113)X
Rf{circumflex over ( )}2Rf
F
NS4304MC


04SM142
M4F1
NS4304MC/03SM118)X
Rf{circumflex over ( )}5Rf
F
NS4304MC


04SM166
M5F1
NS2173FC/04SM140)X
rfRf{circumflex over ( )}1/rfRf/rfRf*
S/F
NS2173FC


04SM167
M5F1
NS2173FC/04SM141)X
rfRf{circumflex over ( )}2/rfRf/rfRf*
S/F
NS2173FC


04SM168
M5F1
NS2173FC/04SM142)X
rfRf{circumflex over ( )}5/rfRf/rfRf*
S/F
NS2173FC


05SM194
M6F2
04SM166)1439
rfrf/rfRf1439/Rf1439Rf1439
S/F
04SM166-1439


05SM197
M6F2
04SM166)1815
rfrf/rfRf1815/Rf1815Rf1815
S/F
04SM166-1815


05SM198
M6F2
04SM166)1931
rfrf/rfRf1931/Rf1931Rf1931
S/F
04SM166-1931


05SM205
M7BC0
04SM166-1439/NS1822BC
rfrf/rfRf1439
S/F
NS1822FC


05SM208
M7BC0
04SM166-1815/NS1822BC
rfrf/rfRf1815
S/F
NS1822FC


05SM209
M7BC0
04SM166-1931/NS1822BC
rfrf/rfRf1931
S/F
NS1822FC


05SM234
M8BC1
NS1822FC/05SM205)X
rfrf/rfRf1439
S/F
NS1822FC


05SM235
M8BC1
NS1822FC/05SM208)X
rfrf/rfRf1815
S/F
NS1822FC


05SM236
M8BC1
NS1822FC/05SM209)X
rfrf/rfRf1931
S/F
NS1822FC


06SM330
M9BC2
NS1822FC/05SM234)X
rfrf/rfRf1439
S/F
NS1822FC


06SM331
M9BC2
NS1822FC/05SM235)X
rfrf/rfRf1815
S/F
NS1822FC


06SM332
M9BC2
NS1822FC/05SM236)X
rfrf/rfRf1931
S/F
NS1822FC


06SM341
M6DHS1
(05SM194DH)1
Rf1439Rf1439
F
05SM194DH1


06SM350
M6DHS1
(05SM197DH)i7
Rf1815Rf1815
F
05SM197DH97


06SM351
M6DHS1
(05SM198DH)1
Rf1931Rf1931
F
05SM198DH1


06SM399
M10BC3
NS1822FC/06SM330)X
rfrf/rfRf1439
S/F
NS1822FC


06SM400
M10BC3
NS1822FC/06SM331)X
rfrf/rfRf1815
S/F
NS1822FC


06SM401
M10BC3
NS1822FC/06SM332)X
rfrf/rfRf1931
S/F
NS1822FC


06SM403
BC2S1
06SM330)X
rfrf/rfRf1439/Rf1439Rf1439
S/F
06SM330blk


06SM404
BC2S1
06SM331)X
rfrf/rfRf1815/Rf1815Rf1815
S/F
06SM331blk


06SM405
BC2S1
06SM332)X
rfrf/rfRf1931/Rf1931Rf1931
S/F
06SM332blk


06SM408
M6DHS2
06SM342)1
Rf1439Rf1439
F
06SM342-1


06SM410
M6DHS2
06SM350)1
Rf1815Rf1815
F
06SM350-1


06SM412
M6DHS2
06SM354)1
Rf1931Rf1931
F
06SM354-1


06SM414
M11BC4
NS1822FC/06SM399)X
rfrf/rfRf1439
S/F
NS1822FC


06SM415
M11BC4
NS1822FC/06SM400)X
rfrf/rfRf1815
S/F
NS1822FC


06SM416
M11BC4
NS1822FC/06SM401)X
rfrf/rfRf1931
S/F
NS1822FC


06SM420
BC2S2
06SM403)3
Rf1439Rf1439
F
06SM403-3


06SM426
BC2S2
06SM404)2
Rf1815Rf1815
F
06SM404-2


06SM432
BC2S2
06SM405)7
Rf1931Rf1931
F
06SM405-7


06SM438
BC4S1
06SM414)X
rfrf/rfRf1439/Rf1439Rf1439
S/F
06SM414blk


06SM439
BC4S1
06SM415)X
rfrf/rfRf1815/Rf1815Rf1815
S/F
06SM415blk


06SM440
BC4S1
06SM416)X
rfrf/rfRf1931/Rf1931Rf1931
S/F
06SM416blk


07SM441
BC4S2
06SM438)X
Rf1439Rf1439
F
06SM438blk


07SM442
BC4S2
06SM439)X
Rf1815Rf1815
F
06SM439blk


07SM443
BC4S2
06SM440)X
Rf1931Rf1931
F
06SM440blk












Marker

















Line
Genotype
Male
Genotype
Y5N
OPC2
RMB12
RMA07
CMS







01SM001
Rf{circumflex over ( )}1rf
96DHS60
rfrf
+
±


+



01SM002
Rf{circumflex over ( )}2rf
96DHS60
rfrf
+
±

±
+



01SM005
Rf{circumflex over ( )}5rf
96DHS60
rfrf
+


±
+



02SM008
Rf{circumflex over ( )}1rf
NS4302MC
RfRf
±
+
+
+
+



02SM009
Rf{circumflex over ( )}2rf
NS4302MC
RfRf
±
+
+
+
+



02SM011
Rf{circumflex over ( )}5rf
NS4302MC
RfRf
±
+
+
+
+



02SM086
rfrf
02SM008-6
Rf{circumflex over ( )}1Rf
+
+
±
±




02SM087
rfrf
02SM009-6
Rf{circumflex over ( )}2Rf
+
+
±
+




02SM088
rfrf
02SM011-7
Rf{circumflex over ( )}5Rf
+
±
±
+




03SM104
Rf{circumflex over ( )}1rf
02SM086-16
Rf{circumflex over ( )}1rf
±
+






03SM113
Rf{circumflex over ( )}2rf
02SM087-07
Rf{circumflex over ( )}2rf
±
+

+




03SM118
Rf{circumflex over ( )}5rf
02SM088-09
Rf{circumflex over ( )}5rf
±


+




04SM140
RfRf
03SM104blk
Rf{circumflex over ( )}1Rf{circumflex over ( )}1

+
+
+
+



04SM141
RfRf
03SM113blk
Rf{circumflex over ( )}2Rf{circumflex over ( )}2

+
+
+
+



04SM142
RfRf
03SM118blk
Rf{circumflex over ( )}5Rf{circumflex over ( )}5

+
+
+
+



04SM166
rfrf
04SM140blk
Rf{circumflex over ( )}1Rf
+
+
±
±
+



04SM167
rfrf
04SM141blk
Rf{circumflex over ( )}2Rf
+
+
±
+
+



04SM168
rfrf
04SM142blk
Rf{circumflex over ( )}5Rf
+
±
±
+
+



05SM194
rfRf1439
04SM166-1439
rfRf1439
±

±

+



05SM197
rfRf1815
04SM166-1815
rfRf1815
±

±

+



05SM198
rfRf1931
04SM166-1931
rfRf1931
±

±

+



05SM205
rfrf
04SM166-1439
rfRf1439
±

±

+



05SM208
rfrf
04SM166-1815
rfRf1815
±

±

+



05SM209
rfrf
04SM166-1931
rfRf1931
±

±

+



05SM234
rfrf
05SM205blk
rfRf1439
±

±

+



05SM235
rfrf
05SM208blk
rfRf1815
±

±

+



05SM236
rfrf
05SM209blk
rfRf1931
±

±

+



06SM330
rfrf
05SM234blk
rfRf1439
±

±

+



06SM331
rfrf
05SM235blk
rfRf1815
±

±

+



06SM332
rfrf
05SM236blk
rfRf1931
±

±

+



06SM341
Rf1439Rf1439
05SM194DH1
Rf1439Rf1439


+

+



06SM350
Rf1815Rf1815
05SM197DH97
Rf1815Rf1815


+

+



06SM351
Rf1931Rf1931
05SM198DH1
Rf1931Rf1931


+

+



06SM399
rfrf
06SM330blk
rfRf1439
±

±

+



06SM400
rfrf
06SM331blk
rfRf1815
±

±

+



06SM401
rfrf
06SM332blk
rfRf1931
±

±

+



06SM403
rfRf1439
06SM330blk
rfRf1439
±

±

+



06SM404
rfRf1815
06SM331blk
rfRf1815
±

±

+



06SM405
rfRf1931
06SM332blk
rfRf1931
±

±

+



06SM408
Rf1439Rf1439
06SM342-1
Rf1439Rf1439


+

+



06SM410
Rf1815Rf1815
06SM350-1
Rf1815Rf1815


+

+



06SM412
Rf1931Rf1931
06SM354-1
Rf1931Rf1931


+

+



06SM414
rfrf
06SM399blk
rfRf1439
±

±

+



06SM415
rfrf
06SM400blk
rfRf1815
±

±

+



06SM416
rfrf
06SM401blk
rfRf1931
±

±

+



06SM420
Rf1439Rf1439
06SM403-3
Rf1439Rf1439


+

+



06SM426
Rf1815Rf1815
06SM404-2
Rf1815Rf1815


+

+



06SM432
Rf1931Rf1931
06SM405-7
Rf1931Rf1931


+

+



06SM438
rfRf1439
06SM414blk
rfRf1439
±

±

+



06SM439
rfRf1815
06SM415blk
rfRf1815
±

±

+



06SM440
rfRf1931
06SM416blk
rfRf1931
±

±

+



07SM441
Rf1439Rf1439
06SM438blk
Rf1439Rf1439


+

+



07SM442
Rf1815Rf1815
06SM439blk
Rf1815Rf1815


+

+



07SM443
Rf1931Rf1931
06SM440blk
Rf1931Rf1931


+

+









Claims
  • 1. A Brassica plant comprising a fertility gene for Ogura cytoplasmic male sterility, wherein the fertility gene is on a Raphanus fragment introgressed from Raphanus sativa, and the Raphanus fragment lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33.
  • 2. The Brassica plant of claim 1 wherein the Raphanus fragment lacks the OPC2 marker.
  • 3. (canceled)
  • 4. The Brassica plant of claim 1 wherein the Raphanus fragment comprises a molecular marker selected from the group consisting of RMB01, E35M62, RMB02, RMB03, RMB04, RMB05, RMB06, RMB07, RMB08, RMB09, RMB10, OPF10, RMB11, RMB12, RMC01, RMCO2, RMCO3, E38M60, RMC04, RMCO5, RMC06, RMC07, RMC08, RMC09, RMC10, RMC11, RMC12, RMC13, RMC14, RMC15, RMC16, RMC17, RMC18, RMC19, RMC20, RMC21, RMC22 AND RMC23.
  • 5. (canceled)
  • 6. (canceled)
  • 7. (canceled)
  • 8. The Brassica plant of claim 4 designated R1815, representative seed of which have been deposited under NCIMB Accession Number 41511, or a descendent or a plant produced by crossing R1815 with a second plant.
  • 9. A progeny or descendent plant of the Brassica plant of claim 8, wherein the progeny or descendent plant comprises a Raphanus fragment which lacks a marker selected from the group consisting of RMA01, RMA02, RMA03, RMA04, RMA05, RMA06, RMA07, RMA08, RMA09, RMA10, RMC24, OPC2, RMC25, RMC26, RMC27, RMC28, RMC29, RMC30, RMC31, RMC32 and RMC33.
  • 10-14. (canceled)
  • 15. A plant cell from the Brassica plant of claim 1.
  • 16. A part of the Brassica plant of claim 1.
  • 17-42. (canceled)
  • 43. A Brassica plant comprising the recombination event of R1815.
  • 44. (canceled)
CROSS REFERENCE

This application is a Divisional of U.S. application Ser. No. 13/904,135, filed May 29, 2013, now Allowed, which is a Divisional of U.S. application Ser. No. 12/366,155, filed Feb. 5, 2009, now U.S. Pat. No. 8,466,347, which claims the benefit U.S. Provisional Application No. 61/054,857 filed May 21, 2008, now expired and U.S. Provisional Application No. 61/026,604, filed Feb. 6, 2008, now expired, all of which are incorporated herein by reference.

Provisional Applications (2)
Number Date Country
61026604 Feb 2008 US
61054857 May 2008 US
Divisions (2)
Number Date Country
Parent 13904135 May 2013 US
Child 14279640 US
Parent 12366155 Feb 2009 US
Child 13904135 US