TRANSGENIC PLANTS WITH ENHANCED AGRONOMIC TRAITS

Abstract
This invention provides transgenic plant cells with recombinant DNA for expression of proteins that are useful for imparting enhanced agronomic trait(s) to transgenic crop plants. This invention also provides transgenic plants and progeny seed comprising the transgenic plant cells where the plants are selected for having an enhanced trait selected from the group of traits consisting of enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil. Also disclosed are methods for manufacturing transgenic seed and plants with enhanced trait.
Description
INCORPORATION OF SEQUENCE LISTING

Two copies of the sequence listing (Copy #1 and Copy #2) and a computer readable form (CRF) of the sequence listing, all on CD-Rs, each containing the text file named 3126016US2.txt, which is 6,332,416 bytes (measured in MS-WINDOWS), were created on Jan. 9, 2015 and are herein incorporated by reference.


INCORPORATION OF COMPUTER PROGRAM LISTING

Two copies of the Computer Program Listing (Copy 1 and Copy 2) and a computer readable form (CRF) containing folders hmmer-2.3.2 and 32pfamDir, all on CD-Rs are incorporated herein by reference in their entirety. Folder hmmer-2.3.2 contains the source code and other associated files for implementing the HMMer software for Pfam analysis. Folder 32pfamDir contains 32 Pfam Hidden Markov Models. Both folders were created on CD-R on Jan. 9, 2015, having a total size of 2,031,616 (measured in MS-WINDOWS).


FIELD OF THE INVENTION

Disclosed herein are recombinant DNA useful for providing enhanced traits to transgenic plants, seeds, pollen, plant cells and plant nuclei of such transgenic plants, methods of making and using such recombinant DNA, plants, seeds, pollen, plant cells and plant nuclei. Also disclosed are methods of producing hybrid seed comprising such recombinant DNA.


BACKGROUND OF THE INVENTION

This invention employs recombinant DNA for expression of proteins that are useful for imparting enhanced agronomic traits to transgenic plants. Recombinant DNA in this invention is provided in a construct comprising a promoter that is functional in plant cells and that is operably linked to a DNA segment that encodes a protein. In some embodiments of the invention, such protein defined by protein domains e.g. a “Pfam domain module” (as defined herein below) from the group of Pfam domain modules identified in Table 10. In other embodiments of the invention, e.g. where a Pfam domain module is not available, such protein is defined a consensus amino acid sequence of an encoded protein that is targeted for production e.g. a protein having amino acid sequence with at least 90% identity to a consensus amino acid sequence as set forth in SEQ ID NO: 2201. In more specific embodiments of the invention the protein expressed in plant cells is a protein selected from the group of proteins identified in Table 1 and their homologs identified in Table 8.


Other aspects of the invention are specifically directed to plant cell nuclei and transgenic plant cells comprising the recombinant DNA construct of the invention, transgenic plants comprising a plurality of such plant cells, progeny transgenic seed, embryo and transgenic pollen from such transgenic plants. Such transgenic plants are selected from a population of transgenic plants regenerated from plant cells transformed with the recombinant DNA construct provided by the invention and express the protein by screening transgenic plants in the population for an enhanced trait as compared to control plants that do not have the recombinant DNA construct, where the enhanced trait is selected from group of enhanced traits consisting of enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil.


In yet another aspect of the invention the plant cell nuclei, plant cells, transgenic plants, seeds, and pollen further comprise recombinant DNA expressing a protein that provides tolerance from exposure to an herbicide applied at levels that are lethal to a wild type plant cell. Such tolerance is especially useful not only as an advantageous trait in such plants but is also useful in a selection step in the methods of the invention. In aspects of the invention such herbicide is a glyphosate, dicamba, or glufosinate compound.


Yet other aspects of the invention provide transgenic plants which are homozygous for the recombinant DNA and transgenic seed of the invention from corn, soybean, cotton, canola, alfalfa, wheat or rice plants.


This invention also provides methods for manufacturing non-natural, transgenic seed that can be used to produce a crop of transgenic plants with an enhanced Wait resulting from expression of stably-integrated, recombinant DNA construct provided by herein. More specifically the method comprises (a) providing a population of plants produced from a parental plant having a recombinant DNA construct of the invention; (b) screening this population of plants for at least one enhanced trait and the recombinant DNA construct, where individual plants in the population can exhibit the trait at a level less than, essentially the same as or greater than the level that the trait is exhibited in control plants which do not contain the recombinant DNA construct, where the enhanced trait is selected from the group of enhanced traits consisting of enhanced water use efficiency, enhanced cold tolerance, enhanced heat tolerance, enhanced high salinity tolerance, enhanced shade tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil; (c) selecting from the population one or more plants that exhibit the trait at a level greater than the level that the trait is exhibited in control plants; and (d) collecting seeds from selected plant selected from step c. The method further comprises (e) verifying that the recombinant DNA construct is stably integrated in said selected plants, and (f) analyzing tissue of a selected plant to determine the production of a protein having the function of a protein selected from SEQ ID NO: 96 through SEQ ID NO: 2166. In one aspect of the invention the plants in the population further comprise DNA expressing a protein that provides tolerance to exposure to a herbicide applied at levels that are lethal to wild type plant cells and the selecting is affected by treating the population with the herbicide, e.g. a glyphosate, dicamba, or glufosinate compound. In another aspect of the invention the plants are selected by identifying plants with the enhanced trait. The methods are especially useful for manufacturing corn, soybean, cotton, canola, alfalfa, wheat or rice seed.


Another aspect of the invention provides a method of producing hybrid corn seed comprising acquiring hybrid corn seed from a herbicide tolerant corn plant which also has stably-integrated, recombinant DNA construct comprising a promoter that is (a) functional in plant cells and (b) is operably linked to DNA that encodes a protein provided by the invention. The methods further comprise producing corn plants from the hybrid corn seed, wherein a fraction of the plants produced from the hybrid corn seed is homozygous for the recombinant DNA, a fraction of the plants produced from the hybrid corn seed is hemizygous for the recombinant DNA construct, and a fraction of the plants produced from the hybrid corn seed has none of the recombinant DNA construct; selecting corn plants which are homozygous and hemizygous for the recombinant DNA construct by treating with an herbicide; collecting seed from herbicide-treated-surviving corn plants and planting the seed to produce further progeny corn plants; repeating the selecting and collecting steps at least once to produce an inbred corn line; and crossing the inbred corn line with a second corn line to produce hybrid seed.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a consensus amino acid sequence of SEQ ID NO: 127 and its homologs.



FIGS. 2-5 are plasmid maps.





DETAILED DESCRIPTION OF THE INVENTION

In the attached sequence listing:


SEQ ID NO:1-95 are nucleotide sequences of the coding strand of DNA for “genes” used in the recombinant DNA imparting an enhanced trait in plant cells, i.e. each represents a coding sequence for a protein;


SEQ ID NO: 96-193 are amino acid sequences of the cognate protein of the “genes” with nucleotide coding sequences 1-95;


SEQ ID NO: 194-2166 are amino acid sequences of homologous proteins;


SEQ ID NO: 2167-2200 are nucleotide sequences of the elements in base plasmid vectors


SEQ ID NO: 2201 is a consensus amino acid sequence.


SEQ ID NO: 2202-2203 are nucleotide sequences of two base plasmid vectors useful for corn transformation;


SEQ ID NO: 2204 is a nucleotide sequence of a base plasmid vector useful for soybean and canola transformation; and


SEQ ID NO: 2205 is a nucleotide sequence of a base plasmid vector useful for cotton transformation.


As used herein a “plant cell” means a plant cell that is transformed with stably-integrated, non-natural, recombinant DNA, e.g. by Agrobacterium-mediated transformation or by bombardment using microparticles coated with recombinant DNA or other means. A plant cell of this invention can be an originally-transformed plant cell that exists as a microorganism or as a progeny plant cell that is regenerated into differentiated tissue, e.g. into a transgenic plant with stably-integrated, non-natural recombinant DNA, or seed or pollen derived from a progeny transgenic plant.


As used herein a “transgenic plant” means a plant whose genome has been altered by the stable integration of recombinant DNA. A transgenic plant includes a plant regenerated from an originally-transformed plant cell and progeny transgenic plants from later generations or crosses of a transformed plant.


As used herein “recombinant DNA” means DNA which has been genetically engineered and constructed outside of a cell including DNA containing naturally occurring DNA or cDNA or synthetic DNA.


As used herein “consensus sequence” means an artificial sequence of amino acids in a conserved region of an alignment of amino acid sequences of homologous proteins, e.g. as determined by a CLUSTALW alignment of amino acid sequence of homolog proteins.


As used herein “homolog” means a protein in a group of proteins that perform the same biological function, e.g. proteins that belong to the same Pfam protein family and that provide a common enhanced trait in transgenic plants of this invention. Homologs are expressed by homologous genes. Homologous genes include naturally occurring alleles and artificially-created variants. Degeneracy of the genetic code provides the possibility to substitute at least one base of the protein encoding sequence of a gene with a different base without causing the amino acid sequence of the polypeptide produced from the gene to be changed. Hence, a polynucleotide useful in the present invention may have any base sequence that has been changed from SEQ ID NO: 1 through SEQ ID NO: 95 in accordance with degeneracy of the genetic code. Homologs are proteins that, when optimally aligned, have at least 60% identity, more preferably about 70% or higher, more preferably at least 80% and even more preferably at least 90% identity over the full length of a protein identified as being associated with imparting an enhanced trait when expressed in plant cells. Homologs include proteins with an amino acid sequence that has at least 90% identity to a consensus amino acid sequence of proteins and homologs disclosed herein.


Homologs are identified by comparison of amino acid sequence, e.g. manually or by use of a computer-based tool using known homology-based search algorithms such as those commonly known and referred to as BLAST, FASTA, and Smith-Waterman. A local sequence alignment program, e.g. BLAST, can be used to search a database of sequences to find similar sequences, and the summary Expectation value (E-value) used to measure the sequence base similarity. As a protein hit with the best E-value for a particular organism may not necessarily be an ortholog or the only ortholog, a reciprocal query is used in the present invention to filter hit sequences with significant E-values for ortholog identification. The reciprocal query entails search of the significant hits against a database of amino acid sequences from the base organism that are similar to the sequence of the query protein. A hit is a likely ortholog, when the reciprocal query's best hit is the query protein itself or a protein encoded by a duplicated gene after speciation. A further aspect of the invention comprises functional homolog proteins that differ in one or more amino acids from those of disclosed protein as the result of conservative amino acid substitutions, for example substitutions are among: acidic (negatively charged) amino acids such as aspartic acid and glutamic acid; basic (positively charged) amino acids such as arginine, histidine, and lysine; neutral polar amino acids such as glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine; neutral nonpolar (hydrophobic) amino acids such as alanine, leucine, isoleucine, valine, proline, phenylalanine, tryptophan, and methionine; amino acids having aliphatic side chains such as glycine, alanine, valine, leucine, and isoleucine; amino acids having aliphatic-hydroxyl side chains such as serine and threonine; amino acids having amide-containing side chains such as asparagine and glutamine; amino acids having aromatic side chains such as phenylalanine, tyrosine, and tryptophan; amino acids having basic side chains such as lysine, arginine, and histidine; amino acids having sulfur-containing side chains such as cysteine and methionine; naturally conservative amino acids such as valine-leucine, valine-isoleucine, phenylalanine-tyrosine, lysine-arginine, alanine-valine, aspartic acid-glutamic acid, and asparagine-glutamine. A further aspect of the homologs encoded by DNA useful in the transgenic plants of the invention are those proteins that differ from a disclosed protein as the result of deletion or insertion of one or more amino acids in a native sequence.


“Percent identity” describes the extent to which the sequences of DNA or protein segments are invariant throughout a window of alignment of nucleotide or amino acid sequences. An “identity fraction” for a sequence aligned with a reference sequence is the number of identical components which are shared by the sequences, divided by a length of the window of alignment, wherein the length does not include gaps introduced by an alignment algorithm. “Percent identity” (“% identity”) is the identity fraction times 100. The alignment algorithm is preferably a local alignment algorithm, such as BLASTp. As used herein, sequences are “aligned” when the alignment produced by BLASTp has a minimal e-value.


“Pfam” database is a large collection of multiple sequence alignments and hidden Markov models covering many common protein families, e.g. Pfam version 19.0 (December 2005) contains alignments and models for 8183 protein families and is based on the Swissprot 47.0 and SP-TrEMBL 30.0 protein sequence databases. See S. R. Eddy, “Profile Hidden Markov Models”, Bioinformatics 14:755-763, 1998. The Pfam database is currently maintained and updated by the Pfam Consortium. The alignments represent some evolutionary conserved structure that has implications for the protein's function. Profile hidden Markov models (profile HMMs) built from the protein family alignments are useful for automatically recognizing that a new protein belongs to an existing protein family even if the homology by alignment appears to be low.


Protein domains are identified by querying the amino acid sequence of a protein against Hidden Markov Models which characterize protein family domains (“Pfam domains”) using HMMER software, a current version of which is provided in the appended computer listing. A protein domain meeting the gathering cutoff for the alignment of a particular Pram domain is considered to contain the Pram domain.


A “Pram domain module” is a representation of Pfam domains in a protein, in order from N terminus to C terminus. In a Pfam domain module individual Pfam domains are separated by double colons “::”. The order and copy number of the Pfam domains from N to C terminus are attributes of a Pfam domain module. Although the copy number of repetitive domains is important, varying copy number often enables a similar function. Thus, a Pfam domain module with multiple copies of a domain should define an equivalent Pram domain module with variance in the number of multiple copies. A Pfam domain module is not specific for distance between adjacent domains, but contemplates natural distances and variations in distance that provide equivalent function. The Pfam database contains both narrowly- and broadly-defined domains, leading to identification of overlapping domains on some proteins. A Pfam domain module is characterized by non-overlapping domains. Where there is overlap, the domain having a function that is more closely associated with the function of the protein (based on the E value of the Pfam match) is selected. One protein is identified as containing a pfam domain when its scores is higher than the gathering cutoff disclosed in Table 12 by Pfam analysis disclosed herein


Once one DNA is identified as encoding a protein which imparts an enhanced trait when expressed in transgenic plants, other DNA encoding proteins with the same Pfam domain module are identified by querying the amino acid sequence of protein encoded by candidate DNA against the Hidden Markov Models which characterizes the Pfam domains using HMMER software. Candidate proteins meeting the same Pfam domain module are in the protein family and have cognate DNA that is useful in constructing recombinant DNA for the use in the plant cells of this invention. Hidden Markov Model databases for use with HMMER software in identifying DNA expressing protein with a common Pfam domain module for recombinant DNA in the plant cells of this invention are also included in the appended computer listing.


The HMMER software and Pfam databases are version 19.0 and were used to identify known domains in the proteins corresponding to amino acid sequence of SEQ ID NO: 96 through SEQ ID NO: 193. All DNA encoding proteins that have at least one of pfam domain modules of this invention can be used in recombinant DNA construct of this invention, e.g. for selecting transgenic plants having enhanced agronomic traits. The relevant Pfams modules for use in this invention, as more specifically disclosed below, are Homeobox, Myb_DNA-binding::MybDNA-binding, Myb_DNA-binding, zf-Dof, zf-C2H2::zf-C2H2, AP2, Response_reg::Myb_DNA-binding, B3, B3::Auxin_resp::AUX_IAA, HLH, NAM, B3::B3, AUX_IAA, KNOX1::KNOX2::ELK, GRAS, AT_hook::AT_HOOK::DUF296, TCP, SBP, zf-C2H2, B3::Auxin_resp, EIN3, bZIP2, zf-B_box::zf-B_box, zf-B_box::CCT, RWP-RK::PB1, F-box::TUB, CBFD_NFYB_HMF, GATA, SRF-TF, K-box, and SRF-TF::K-box.


As used herein “promoter” means regulatory DNA for initializing transcription. A “plant promoter” is a promoter capable of initiating transcription in plant cells whether or not its origin is a plant cell, e.g. it is well known that Agrobacterium promoters are functional in plant cells. Thus, plant promoters include promoter DNA obtained from plants, plant viruses and bacteria such as Agrobacterium and Bradyrhizobium bacteria. Examples of promoters under developmental control include promoters that preferentially initiate transcription in certain tissues, such as leaves, roots, or seeds. Such promoters are referred to as “tissue preferred”. Promoters that initiate transcription only in certain tissues are referred to as “tissue specific”. A “cell type” specific promoter primarily drives expression in certain cell types in one or more organs, for example, vascular cells in roots or leaves. An “inducible” or “repressible” promoter is a promoter which is under environmental control. Examples of environmental conditions that may affect transcription by inducible promoters include anaerobic conditions, or certain chemicals, or the presence of light. Tissue specific, tissue preferred, cell type specific, and inducible promoters constitute the class of “non-constitutive” promoters. A “constitutive” promoter is a promoter which is active under most conditions.


As used herein “operably linked” means the association of two or more DNA fragments in a DNA construct so that the function of one, e.g. protein-encoding DNA, is controlled by the other, e.g. a promoter.


As used herein “expressed” means produced, e.g. a protein is expressed in a plant cell when its cognate DNA is transcribed to mRNA that is translated to the protein.


As used herein a “control plant” means a plant that does not contain the recombinant DNA that expresses a protein that imparts an enhanced trait. A control plant is to identify and select a transgenic plant that has an enhance trait. A suitable control plant can be a non-transgenic plant of the parental line used to generate a transgenic plant, i.e. devoid of recombinant DNA. A suitable control plant may in some cases be a progeny of a hemizygous transgenic plant line that is does not contain the recombinant DNA, known as a negative segregant.


As used herein an “enhanced trait” means a characteristic of a transgenic plant that includes, but is not limited to, an enhance agronomic trait characterized by enhanced plant morphology, physiology, growth and development, yield, nutritional enhancement, disease or pest resistance, or environmental or chemical tolerance. In more specific aspects of this invention enhanced trait is selected from group of enhanced traits consisting of enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil. In an important aspect of the invention the enhanced trait is enhanced yield including increased yield under non-stress conditions and increased yield under environmental stress conditions. Stress conditions may include, for example, drought, shade, fungal disease, viral disease, bacterial disease, insect infestation, nematode infestation, cold temperature exposure, heat exposure, osmotic stress, reduced nitrogen nutrient availability, reduced phosphorus nutrient availability and high plant density. “Yield” can be affected by many properties including without limitation, plant height, pod number, pod position on the plant, number of internodes, incidence of pod shatter, grain size, efficiency of nodulation and nitrogen fixation, efficiency of nutrient assimilation, resistance to biotic and abiotic stress, carbon assimilation, plant architecture, resistance to lodging, percent seed germination, seedling vigor, and juvenile traits. Yield can also be affected by efficiency of germination (including germination in stressed conditions), growth rate (including growth rate in stressed conditions), ear number, seed number per ear, seed size, composition of seed (starch, oil, protein) and characteristics of seed fill.


Increased yield of a transgenic plant of the present invention can be measured in a number of ways, including test weight, seed number per plant, seed weight, seed number per unit area (i.e. seeds, or weight of seeds, per acre), bushels per acre, tones per acre, tons per acre, kilo per hectare. For example, maize yield may be measured as production of shelled corn kernels per unit of production area, for example in bushels per acre or metric tons per hectare, often reported on a moisture adjusted basis, for example at 15.5 percent moisture. Increased yield may result from improved utilization of key biochemical compounds, such as nitrogen, phosphorous and carbohydrate, or from improved responses to environmental stresses, such as cold, heat, drought, salt, and attack by pests or pathogens. Recombinant DNA used in this invention can also be used to provide plants having improved growth and development, and ultimately increased yield, as the result of modified expression of plant growth regulators or modification of cell cycle or photosynthesis pathways. Also of interest is the generation of transgenic plants that demonstrate enhanced yield with respect to a seed component that may or may not correspond to an increase in overall plant yield. Such properties include enhancements in seed oil, seed molecules such as tocopherol, protein and starch, or oil particular oil components as may be manifest by alterations in the ratios of seed components.


A subset of the DNA molecules of this invention includes fragments of the disclosed recombinant DNA consisting of oligonucleotides of at least 15, preferably at least 16 or 17, more preferably at least 18 or 19, and even more preferably at least 20 or more, consecutive nucleotides. Such oligonucleotides are fragments of the larger molecules having a sequence selected from the group consisting of SEQ ID NO: 1 through SEQ ID NO: 95, and find use, for example as probes and primers for detection of the polynucleotides of the present invention.


Recombinant DNA constructs are assembled using methods well known to persons of ordinary skill in the art and typically comprise a promoter operably linked to DNA, the expression of which provides the enhanced agronomic trait. Other construct components may include additional regulatory elements, such as 5′ leaders and introns for enhancing transcription, 3′ untranslated regions (such as polyadenylation signals and sites), DNA for transit or signal peptides.


Numerous promoters that are active in plant cells have been described in the literature. These include promoters present in plant genomes as well as promoters from other sources, including nopaline synthase (NOS) promoter and octopine synthase (OCS) promoters carried on tumor-inducing plasmids of Agrobacterium tumefaciens and the CaMV35S promoters from the cauliflower mosaic virus as disclosed in U.S. Pat. Nos. 5,164,316 and 5,322,938. Useful promoters derived from plant genes are found in U.S. Pat. No. 5,641,876, which discloses a rice actin promoter, U.S. Pat. No. 7,151,204, which discloses a maize chloroplast aldolase promoter and a maize aldolase (FDA) promoter, and U.S. Patent Application Publication 2003/0131377 A1, which discloses a maize nicotianamine synthase promoter, all of which are incorporated herein by reference. These and numerous other promoters that function in plant cells are known to those skilled in the art and available for use in recombinant polynucleotides of the present invention to provide for expression of desired genes in transgenic plant cells.


In other aspects of the invention, preferential expression in plant green tissues is desired. Promoters of interest for such uses include those from genes such as Arabidopsis thaliana ribulose-1,5-bisphosphate carboxylase (Rubisco) small subunit (Fischhoff et al. (1992) Plant Mol Biol. 20:81-93), aldolase and pyruvate orthophosphate dikinase (PPDK) (Taniguchi et al. (2000) Plant Cell Physiol. 41(1):42-48).


Furthermore, the promoters may be altered to contain multiple “enhancer sequences” to assist in elevating gene expression. Such enhancers are known in the art. By including an enhancer sequence with such constructs, the expression of the selected protein may be enhanced. These enhancers often are found 5′ to the start of transcription in a promoter that functions in eukaryotic cells, but can often be inserted upstream (5′) or downstream (3′) to the coding sequence. In some instances, these 5′ enhancing elements are introns. Particularly useful as enhancers are the 5′ introns of the rice actin 1 (see U.S. Pat. No. 5,641,876) and rice actin 2 genes, the maize alcohol dehydrogenase gene intron, the maize heat shock protein 70 gene intron (U.S. Pat. No. 5,593,874) and the maize shrunken 1 gene.


In other aspects of the invention, sufficient expression in plant seed tissues is desired to affect improvements in seed composition. Exemplary promoters for use for seed composition modification include promoters from seed genes such as napin (U.S. Pat. No. 5,420,034), maize L3 oleosin (U.S. Pat. No. 6,433,252), zein Z27 (Russell et al. (1997) Transgenic Res. 6(2):157-166); globulin 1 (Belanger et al (1991) Genetics 129:863-872), glutelin 1 (Russell (1997) supra), and peroxiredoxin antioxidant (Per1) (Stacy et al. (1996) Plant Mol Biol. 31(6):1205-1216).


Recombinant DNA constructs prepared in accordance with the invention will also generally include a 3′ element that typically contains a polyadenylation signal and site. Well-known 3′ elements include those from Agrobacterium tumefaciens genes such as nos 3′, tml 3′, tmr 3′, tms 3′, ocs 3′, tr7 3′, for example disclosed in U.S. Pat. No. 6,090,627, incorporated herein by reference; 3′ elements from plant genes such as wheat (Triticum aesevitum) heat shock protein 17 (Hsp17 3′), a wheat ubiquitin gene, a wheat fructose-1,6-biphosphatase gene, a rice glutelin gene, a rice lactate dehydrogenase gene and a rice beta-tubulin gene, all of which are disclosed in U.S. published patent application 2002/0192813 A1, incorporated herein by reference; and the pea (Pisum sativum) ribulose biphosphate carboxylase gene (rbs 3′), and 3′ elements from the genes within the host plant.


Constructs and vectors may also include a transit peptide for targeting of a gene to a plant organelle, particularly to a chloroplast, leucoplast or other plastid organelle. For descriptions of the use of chloroplast transit peptides see U.S. Pat. No. 5,188,642 and U.S. Pat. No. 5,728,925, incorporated herein by reference. For description of the transit peptide region of an Arabidopsis EPSPS gene useful in the present invention, see Klee, H. J. et al (MGG (1987) 210:437-442).


Transgenic plants comprising or derived from plant cells of this invention transformed with recombinant DNA construct can be further enhanced with stacked traits, e.g. a crop plant having an enhanced trait resulting from expression of DNA disclosed herein in combination with herbicide and/or pest resistance traits. For example, genes of the current invention can be stacked with other traits of agronomic interest, such as a trait providing herbicide resistance, or insect resistance, such as using a gene from Bacillus thuringensis to provide resistance against lepidopteran, coliopteran, homopteran, hemiopteran, and other insects. Herbicides for which transgenic plant tolerance has been demonstrated and the method of the present invention can be applied include, but are not limited to, glyphosate, dicamba, glufosinate, sulfonylurea, bromoxynil and norflurazon herbicides. Polynucleotide molecules encoding proteins involved in herbicide tolerance are well-known in the art and include, but are not limited to, a polynucleotide molecule encoding 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) disclosed in U.S. Pat. Nos. 5,094,945; 5,627,061; 5,633,435 and 6,040,497 for imparting glyphosate tolerance; polynucleotide molecules encoding a glyphosate oxidoreductase (GOX) disclosed in U.S. Pat. No. 5,463,175 and a glyphosate-N-acetyl transferase (GAT) disclosed in U.S. Patent Application publication 2003/0083480 A1 also for imparting glyphosate tolerance; dicamba monooxygenase disclosed in U.S. Patent Application publication 2003/0135879 A1 for imparting dicamba tolerance; a polynucleotide molecule encoding bromoxynil nitrilase (Bxn) disclosed in U.S. Pat. No. 4,810,648 for imparting bromoxynil tolerance; a polynucleotide molecule encoding phytoene desaturase (crtl) described in Misawa et al, (1993) Plant J. 4:833-840 and in Misawa et al, (1994) Plant J. 6:481-489 for norflurazon tolerance; a polynucleotide molecule encoding acetohydroxyacid synthase (AHAS, aka ALS) described in Sathasiivan et al. (1990) Nucl. Acids Res. 18:2188-2193 for imparting tolerance to sulfonylurea herbicides; polynucleotide molecules known as bar genes disclosed in DeBlock, et al. (1987) EMBO J. 6:2513-2519 for imparting glufosinate and bialaphos tolerance; polynucleotide molecules disclosed in U.S. Patent Application Publication 2003/010609 A1 for imparting N-amino methyl phosphonic acid tolerance; polynucleotide molecules disclosed in U.S. Pat. No. 6,107,549 for impartinig pyridine herbicide resistance; molecules and methods for imparting tolerance to multiple herbicides such as glyphosate, atrazine, ALS inhibitors, isoxoflutole and glufosinate herbicides are disclosed in U.S. Pat. No. 6,376,754 and U.S. Patent Application Publication 2002/0112260, all of said U.S. patents and patent application Publications are incorporated herein by reference. Molecules and methods for imparting insect/nematode/virus resistance are disclosed in U.S. Pat. Nos. 5,250,515; 5,880,275; 6,506,599; 5,986,175 and U.S. Patent Application Publication 2003/0150017 A1, all of which are incorporated herein by reference.


Plant Cell Transformation Methods

Numerous methods for transforming plant cells with recombinant DNA construct are known in the art and may be used in the present invention. Two commonly used methods for plant transformation are Agrobacterium-mediated transformation and microprojectile bombardment. Microprojectile bombardment methods are illustrated in U.S. Pat. No. 5,015,580 (soybean); U.S. Pat. No. 5,550,318 (corn); U.S. Pat. No. 5,538,880 (corn); U.S. Pat. No. 5,914,451 (soybean); U.S. Pat. No. 6,160,208 (corn); U.S. Pat. No. 6,399,861 (corn), U.S. Pat. No. 6,153,812 (wheat) and U.S. Pat. No. 6,365,807 (rice), and Agrobacterium-mediated transformation is described in U.S. Pat. No. 5,159,135 (cotton); U.S. Pat. No. 5,824,877 (soybean); U.S. Pat. No. 5,463,174 (canola); U.S. Pat. No. 5,591,616 (corn); U.S. Pat. No. 6,384,301 (soybean); U.S. Pat. No. 7,026,528 (wheat) and U.S. Pat. No. 6,329,571 (rice), all of which are incorporated herein by reference. For Agrobacterium tumefaciens based plant transformation system, additional elements present on transformation constructs will include T-DNA left and right border sequences to facilitate incorporation of the recombinant polynucleotide into the plant genome.


In general it is useful to introduce recombinant DNA randomly, i.e. at a non-specific location, in the genome of a target plant line. In special cases it may be useful to target recombinant DNA insertion in order to achieve site-specific integration, for example, to replace an existing gene in the genome, to use an existing promoter in the plant genome, or to insert a recombinant polynucleotide at a predetermined site known to be active for gene expression. Several site specific recombination systems exist which are known to function implants include cre-lox as disclosed in U.S. Pat. No. 4,959,317 and FLP-FRT as disclosed in U.S. Pat. No. 5,527,695, both incorporated herein by reference.


Transformation methods of this invention are preferably practiced in tissue culture on media and in a controlled environment. “Media” refers to the numerous nutrient mixtures that are used to grow cells in vitro, that is, outside of the intact living organism. Recipient cell targets include, but are not limited to, meristem cells, callus, immature embryos and gametic cells such as microspores, pollen, sperm and egg cells. It is contemplated that any cell from which a fertile plant may be regenerated is useful as a recipient cell. Callus may be initiated from tissue sources including, but not limited to, immature embryos, seedling apical meristems, microspores and the like. Cells capable of proliferating as callus are also recipient cells for genetic transformation. Practical transformation methods and materials for making transgenic plants of this invention, for example various media and recipient target cells, transformation of immature embryo cells and subsequent regeneration of fertile transgenic plants are disclosed in U.S. Pat. Nos. 6,194,636 and 6,232,526, which are incorporated herein by reference.


The seeds of transgenic plants can be harvested from fertile transgenic plants and be used to grow progeny generations of transformed plants of this invention including hybrid plant lines for selection of plants having an enhanced trait. In addition to direct transformation of a plant with a recombinant DNA; transgenic plants can be prepared by crossing a first plant having a recombinant DNA with a second plant lacking the DNA. For example, recombinant DNA can be introduced into first plant line that is amenable to transformation to produce a transgenic plant which can be crossed with a second plant line to introgress the recombinant DNA into the second plant line. A transgenic plant with recombinant DNA providing an enhanced trait, e.g. enhanced yield, can be crossed with transgenic plant line having other recombinant DNA that confers another trait, for example herbicide resistance or pest resistance, to produce progeny plants having recombinant DNA that confers both traits. Typically, in such breeding for combining traits the transgenic plant donating the additional trait is a male line and the transgenic plant carrying the base traits is the female line. The progeny of this cross will segregate such that some of the plants will carry the DNA for both parental traits and some will carry DNA for one parental trait; such plants can be identified by markers associated with parental recombinant DNA, e.g. marker identification by analysis for recombinant DNA or, in the case where a selectable marker is linked to the recombinant, by application of the selecting agent such as a herbicide for use with a herbicide tolerance marker, or by selection for the enhanced trait. Progeny plants carrying DNA for both parental traits can be crossed back into the female parent line multiple times, for example usually 6 to 8 generations, to produce a progeny plant with substantially the same genotype as one original transgenic parental line but for the recombinant DNA of the other transgenic parental line


In the practice of transformation DNA is typically introduced into only a small percentage of target plant cells in any one transformation experiment. Marker genes are used to provide an efficient system for identification of those cells that are stably transformed by receiving and integrating a transgenic DNA construct into their genomes. Preferred marker genes provide selective markers which confer resistance to a selective agent, such as an antibiotic or herbicide. Any of the herbicides to which plants of this invention may be resistant are useful agents for selective markers. Potentially transformed cells are exposed to the selective agent. In the population of surviving cells will be those cells where, generally, the resistance-conferring gene is integrated and expressed at sufficient levels to permit cell survival. Cells may be tested further to confirm stable integration of the exogenous DNA. Commonly used selective marker genes include those conferring resistance to antibiotics such as kanamycin and paromomycin (nptH), hygromycin B (aph IV) and gentamycin (aac3 and aacC4) or resistance to herbicides such as glufosinate (bar or pat) and glyphosate (aroA or EPSPS). Examples of such selectable markers are illustrated in U.S. Pat. Nos. 5,550,318; 5,633,435; 5,780,708 and 6,118,047, all of which are incorporated herein by reference. Selectable markers which provide an ability to visually identify transformants can also be employed, for example, a gene expressing a colored or fluorescent protein such as a luciferase or green fluorescent protein (GFP) or a gene expressing a beta-glucuronidase or uidA gene (GUS) for which various chromogenic substrates are known.


Plant cells that survive exposure to the selective agent, or plant cells that have been scored positive in a screening assay, may be cultured in regeneration media and allowed to mature into plants. Developing plantlets regenerated from transformed plant cells can be transferred to plant growth mix, and hardened off, for example, in an environmentally controlled chamber at about 85% relative humidity, 600 ppm CO2, and 25-250 microeinsteins m−2 s−1 of light, prior to transfer to a greenhouse or growth chamber for maturation. Plants are regenerated from about 6 weeks to 10 months after a transformant is identified, depending on the initial tissue. Plants may be pollinated using conventional plant breeding methods known to those of skill in the art and seed produced, for example self-pollination is commonly used with transgenic corn. The regenerated transformed plant or its progeny seed or plants can be tested for expression of the recombinant DNA and selected for the presence of enhanced agronomic trait.


Transgenic Plants and Seeds

Transgenic plants derived from the plant cells of this invention are grown to generate transgenic plants having an enhanced trait as compared to a control plant and produce transgenic seed and pollen of this invention. Such plants with enhanced traits are identified by selection of transformed plants or progeny seed for the enhanced trait. For efficiency a selection method is designed to evaluate multiple transgenic plants (events) comprising the recombinant DNA, for example multiple plants from 2 to 20 or more transgenic events. Transgenic plants grown from transgenic seed provided herein demonstrate improved agronomic traits that contribute to increased yield or other trait that provides increased plant value, including, for example, improved seed quality. Of particular interest are plants having enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil.


Table 1 provides a list of protein encoding DNA (“genes”) that are useful as recombinant DNA for production of transgenic plants with enhanced agronomic trait, the elements of Table 1 are described by reference to:


“PEP SEQ ID NO” identifies an amino acid sequence from SEQ ID NO: 96 to 193.


“NUC SEQ ID NO” identifies a DNA sequence from SEQ ID NO: 1 to 95.


“BV id” is a reference to the identifying number in Table 4 of base vectors used for construction of the transformation vectors of the recombinant DNA. Construction of plant transformation constructs is illustrated in Example 1.


“Gene Name” is a common name for protein encoded by the recombinant DNA.


“Annotation” refers to a description of the top hit protein obtained from an amino acid sequence query of each PEP SEQ ID NO to GenBank database of the National Center for Biotechnology Information (ncbi). More particularly, “gi” is the GenBank ID number for the top BLAST hit;


“Description” refers to the description of the top BLAST hit;


“% id” refers to the percentage of identically matched amino acid residues alone the length of the portion of the sequences which is aliened by BLAST (−F T) between the sequence of interest provided herein and the hit sequence in GenBank.












TABLE 1







Nuc
Pep




seq
seq

Annotation














ID
ID

BV

%
GenBank



NO
NO
Gene ID
ID
Gene Name
ID
ID
Desciption

















1
96
PHE0004633_5508
4
corn putative
68
50947455
ref|XP_483255.1|putative






transcription factor


transcription factor RAU1






RAU1


[Oryza sativa (japonica









cultivar-group)]


2
97
PHE0004738_5674
1
rice NAM protein
82
55771315
dbj|BAD72224.1|unknown









protein [Oryza sativa









(japonica cultivar-group)]


3
98
PHE0004814_5801
13
corn KNOX family
75
51535639
dbj|BAD37613.1|KNOX









family class 2









homeodomain protein









[Oryza sativa (japonica









cultivar-group)]


4
99
PHE0004817_5809
4
corn PIF3-like
69
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family


[Oryza sativa









(japonica cultivar-group)]


5
100
PHE0004817_5810
13
corn PIF3-like
69
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family gene


[Oryza sativa









(japonica cultivar-group)]


6
101
PHE0004821_5819
12
corn PIF3-like
61
55296133
dbj|BAD67851.1|basic






family gene


helix-loop-helix protein









SPATULA-like [Oryza










sativa (japonica cultivar-










group)]


7
102
PHE0004828_5826
4
soy PIF3-like
53
92897142
gb|ABE93546.1|Helix-loop-






family gene


helix DNA-binding









[Medicago truncatula]


8
103
PHE0004817_5901
12
corn PIF3-like
69
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family gene


[Oryza sativa









(japonica cultivar-group)]


9
104
PHE0004861_5910
4
rice putative
87
34899818
ref|NP_911255.1|putative






SCARECROW


SCARECROW protein






protein


[Oryza sativa (japonica









cultivar-group)]


10
105
PHE0004863_5912
4
corn putative AT-
61
50916020
ref|XP_468474.1|putative






hook protein


AT-hook protein 1 [Oryza










sativa (japonica cultivar-










group)]


11
106
PHE0002062_5913
4
corn R2R3 Myb
59
50946113
ref|XP_482584.1|putative






protein


typical P-type R2R3 Myb









protein [Oryza sativa









(japonica cultivar-group)]


12
107
PHE0002531_5926
17
corn DNA-binding
78
95102176
gb|ABF51012.1|DOF1 [Zea






protein MNB1a



mays]



13
108
PHE0004914_5971
4
soy syringolide-
93
19911577
dbj|BAB86892.1|syringolide-






induced protein


induced protein 1-3-1A









[Glycine max]


14
109
PHE0004924_5982
4
soy TCP family
74
18396089
ref|NP_566164.1|PTF1






transcription factor


Plastid Transcription Factor









1 [Arabidopsis thaliana]









gb|AAM62743.1|unknown









[Arabidopsis thaliana]


15
110
PHE0004925_5983
4

Arabidopsis

94
15230904
ref|NP_191351.1|DNA






squamosa


binding/transcription factor






promoter-binding


[Arabidopsis thaliana]






protein


sp|Q9M2Q6|SPL15_ARATH









Squamosa promoter -









binding-like protein 15


16
111
PHE0004938_5994
4

Arabidopsis

96
15228553
ref|NP_186995.1|RGL2






gibberellin-


(RGA-LIKE 2);






responsive


transcription factor






modulator


[Arabidopsis thaliana]









sp|Q8GXW1|RGL2_ARATH









DELLA protein RGL2









(RGA-like protein 2)









(Scarecrow-like protein 19)


17
112
PHE0004957_6019
4
corn C2H2-type
68
50933653
ref|XP_476354.1|C2H2-type






zinc finger protein


zinc finger protein-like









protein [Oryza sativa









(japonica cultivar-group)]


18
113
PHE0004958_6020
4
corn putative
50
50940107
ref|XP_479581.1|putative






ascorbate oxidase


ascorbate oxidase promoter-






promoter-binding


binding protein AOBP






protein


[Oryza sativa (japonica









cultivar-group)]









ref|XP_506580.1|









PREDICTED









OSJNBa0060O17.31 gene









product [Oryza sativa









(japonica cultivar-group)]


19
114
PHE0004959_6021
4
corn putative
41
56567581
gb|AAV98700.1|BTH-






EREBP-type


induced ERF transcriptional






transcription factor


factor 1 [Oryza sativa









(indica cultivar-group)]


20
115
PHE0004974_6040
4
corn auxin
74
108864436
gb|ABG22499.1|Auxin






response factor


response factor 2, [Oryza










sativa (japonica cultivar-










group)]


21
116
PHE0004975_6041
4
corn auxin
67
77555450
gb|ABA98246.1|Auxin






response factor


response factor 2, [Oryza










sativa (japonica cultivar-










group)]


22
117
PHE0004987_6056
4
soy transfactor-like
63
77403669
dbj|BAE46413.1|MYB-CC






protein


type transfactor [Solanum










tuberosum]



23
118
PHE0005005_7034
4
corn putative Myb-
52
37536868
ref|NP_922736.1|putative






related protein


Myb-related protein [Oryza










sativa (japonica cultivar-










group)]


24
119
PHE0004877_7030
12
corn response
76
56784051
dbj|BAD82798.1|putative






regulator ARR11


response regulator 11









[Oryza sativa (japonica









cultivar-group)]


25
120
PHE0006057_7048
13
wheat PIF3-like
40
109134123
dbj|BAC41905.1|putative






family gene


bHLH transcription factor









bHLH016 [Arabidopsis










thaliana]



26
121
PHE0006057_7053
12
wheat PIF3-like
40
109134123
dbj|BAC41905.1|putative






family gene


bHLH transcription factor









bHLH016 [Arabidopsis










thaliana]



27
122
PHE0006070_7067
4
corn putative
64
54291039
dbj|BAD61716.1|transcription






transcription factor


factor-like [Oryza sativa









(japonica cultivar-group)]


28
123
PHE0006073_7072
4
corn putative bZIP
64
54291039
dbj|BAD61716.1|transcription






transcription factor


factor-like [Oryza sativa









(japonica cultivar-group)]


29
124
PHE0006004_7082
4
soy NAM like
51
15224202
gb|AAD22369.1|NAM (no






protein


apical meristem)-like









protein [Arabidopsis










thaliana]










sp|Q9SK55|NAC42_ARATH









Putative NAC domain-









containing protein 42









(ANAC042)


30
125
PHE0006022_7105
4
soy transcription
82
18643341
gb|AAL76272.1|transcription






factor EIL1


factor EIL1 [Vigna










radiata]



31
126
PHE0006023_7240
4

Arabidopsis bHLH

92
15241896
ref|NP_201067.1|DNA






family protein


binding/transcription factor









[Arabidopsis thaliana]


32
127
PHE0006191_7251
8
EEM7
60
50936701
ref|XP_477878.1|hypothetical









protein [Oryza sativa









(japonica cultivar-group)]


33
128
PHE0006237_7261
18
Lycopersicon
86
18650662
gb|AAL75809.1|ethylene






SHN1


response factor 1









[Lycopersicon esculentum]


34
129
PHE0006237_7274
17

Lycopersicon

86
18650662
gb|AAL75809.1|ethylene






SHN1


response factor 1









[Lycopersicon esculentum]


35
130
PHE0006237_7268
6

Lycopersicon

86
18650662
gb|AAL75809.1|ethylene






SHN1


response factor 1









[Lycopersicon esculentum]


36
131
PHE0006237_7277
5

Lycopersicon

86
18650662
gb|AAL75809.1|ethylene






SHN1


response factor 1









[Lycopersicon esculentum]


37
132
PHE0006237_7284
11

Lycopersicon

86
18650662
gb|AAL75809.1|ethylene






SHN1


response factor 1









[Lycopersicon esculentum]


38
133
PHE0004816_7303
4
corn PIF3-like
82
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family gene


[Oryza sativa









(japonica cultivar-group)]


39
134
PHE0006291_7319
17
soy putative
42
15227152
ref|NP_182310.1|transcription






CONSTANS-like


factor/zinc ion binding






B-box zinc finger


[Arabidopsis thaliana]






protein


40
135
PHE0004816_7421
12
corn PIF3-like
82
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family gene


[Oryza sativa









(japonica cultivar-group)]


41
136
PHE0004816_7418
4
corn PIF3-like
82
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family gene


[Oryza sativa









(japonica cultivar-group)]


42
137
PHE0003673_7430
4
corn response
76
56784051
dbj|BAD82798.1|putative






regulator like


response regulator 11









[Oryza sativa (japonica









cultivar-group)]


43
138
PHE0003664_7436
4
soy AP2/EREBP
48
15227980
gb|AAT44934.1|putative






transcription factor


AP2/EREBP transcription






like


factor [Arabidopsis thaliana]


44
139
PHE0004816_7445
13
corn PIF3-like
82
50928761
ref|XP_473908.1|OSJNBa0058K23.6






family gene


[Oryza sativa









(japonica cultivar-group)]


45
140
PHE0002149_7487
4
corn DNA-binding
66
50941323
ref|XP_480189.1|putative






protein


LHY protein [Oryza sativa









(japonica cultivar-group)]


46
141
PHE0006290_7498
4
corn putative
70
50912285
ref|XP_467550.1|zinc-finger






CONSTANS-like


protein [Oryza sativa






B-box zinc finger


(japonica cultivar-group)]






protein


47
142
PHE0006423_7664
4
soy Myb61
56
92873337
gb|ABE81808.1|Homeodomain-









related [Medicago










truncatula]



48
143
PHE0006384_7737
9
rice R2R3 Myb
55
50946113
ref|XP_482584.1|putative






protein


typical P-type R2R3 Myb









protein [Oryza sativa









(japonica cultivar-group)]


49
144
PHE0006384_7789
13
rice R2R3 Myb
55
50946113
ref|XP_482584.1|putative






protein


typical P-type R2R3 Myb









protein [Oryza sativa









(japonica cultivar-group)]


50
145
PHE0006507_7828
17
Corn NFB1_23C
98
50916531
gb|ABF96585.1|CCAAT-









binding transcription factor









subunit A [Oryza sativa









(japonica cultivar-group)]


51
146
PHE0006509_7846
19

Arabidopsis

60
62856979
gb|AAY16440.1|squamosa






Gm2010


promoter binding-like









protein [Betula platyphylla]


52
147
PHE0006384_7839
19
rice R2R3 Myb
55
50946113
ref|XP_482584.1|putative






protein


typical P-type R2R3 Myb









protein [Oryza sativa









(japonica cultivar-group)]


53
148
PHE0006448_7859
17

Arabidopsis

99
15217662
ref|NP_176634.1|transcription






transcription factor


factor [Arabidopsis










thaliana] gb|AAN41333.1|










unknown protein









[Arabidopsis thaliana]


54
149
PHE0006504_7876
17
maize tubby 4
69
55733806
gb|AAV59313.1|putative









tubby protein [Oryza sativa









(japonica cultivar-group)]


55
150
PHE0006057_7929
15
wheat P1F3-like
40
109134123
dbj|BAC41905.1|putative






family gene


bHLH transcription factor









bHLH016 [Arabidopsis










thaliana]



56
151
PHE0003473_7927
9
soy Zinc finger
50
87162706
gb|ABD28501.1|Zinc finger,






protein like


C2H2-type [Medicago










truncatula]



57
152
PHE0002531_7985
45
corn DNA-binding
78
95102176
gb|ABF51012.1|DOF1 [Zea






protein MNB1a



mays]



58
153
PHE0004463_8059
15
soy ethylene
48
15238727
ref|NP_197901.1|DNA






response factor


binding/transcription factor









[Arabidopsis thaliana]


59
154
PHE0001067_8154
10

Arabidopsis

89
15237035
ref|NP_195280.1|DNA






homeodomain


binding/transcription factor






transcription factor


[Arabidopsis thaliana]









sp|O81788|WOX13_ARATH









WUSCHEL-related









homeobox 13


60
155
PHE0006350_8201
15
GIA/RGA-like
46
63054405
gb|AAY28970.1|GIA/RGA-






gibberellin


like gibberellin response






response modulator


modulator [Gossypium










hirsutum]



61
156
PHE0006605_8233
17

Arabidopsis Zinc

74
15230393
ref|NP_190677.1|transcription






finger (GATA


factor [Arabidopsis






type) family



thaliana]







protein


62
157
PHE0006546_8310
8
Response regulator 9
61
55771374
dbj|BAD72541.1|putative









response regulator 9 [Oryza










sativa (japonica cultivar-










group)]


63
158
PHE0006527_8369
17
NFB1-Q185H
97
50916531
gb|ABF96585.1|CCAAT-









binding transcription factor









subunit A [Oryza sativa









(japonica cultivar-group)]


64
159
PHE0004938_8370
17

Arabidopsis

96
15228553
sp|QSGXW1|RGL2_ARATH






gibberellin-


DELLA protein RGL2






responsive


(RGA-like protein 2)






modulator


(Scarecrow-like protein 19)









[Arabidopsis thaliana]


65
160
PHE0006774_8489
15
NFB2_E76R_S83R
82
115840
sp|P25209|NFYB_MaizeNuclear









transcription factor Y









subunit B (NF-YB) (CAAT-









box DNA-binding protein









subunit B)


66
161
PHE0006778_8503
15
NFB2_149R_C73S_C89S
82
115840
sp|P25209|NFYB_MaizeNuclear









transcription factor Y









subunit B (NF-YB) (CAAT-









box DNA-binding protein









subunit B)


67
162
PHE0006780_8502
15
NFB2_C73S_C89S_L102R
82
115840
sp|P25209|NFYB_Maize









Nuclear transcription factor









Y subunit B (NF-YB)









(CAAT-box DNA-binding









protein subunit B)


68
163
PHE0006752_8521
16
wheat AP1
75
30721847
gb|AAP33790.1|MADS-box






(VRN1)


protein TaVRT-1









gb|AAW73225.1|VRN-B1









[Triticum aestivum]


69
164
PHE0006779_8565
15
corn
82
115840
sp|P25209|NFYB_MaizeNuclear






NFB2_C73R_C89S


transcription factor Y









subunit B (NF-YB) (CAAT-









box DNA-binding protein









subunit B)


70
165
PHE0006781_8573
15
corn
82
115840
sp|P25209|NFYB_MaizeNuclear






NFB2_149R_C73R_C89S_L102R


transcription factor Y









subunit B (NF-YB) (CAAT-









box DNA-binding protein









subunit B)


71
166
PHE0003664_8637
15
soy AP2/EREBP
48
15227980
gb|AAT44934.1|putative






transcription factor


AP2/EREBP transcription









factor [Arabidopsis thaliana]


72
167
PHE0006004_8667
15
soy NAM like
51
15224202
ref|NP_181828.1|ANAC042;






protein


transcription factor









gb|AAD22369.1|NAM (no









apical meristem)-like









protein [Arabidopsis










thaliana]



73
168
PHE0006022_8690
15
soy transcription
82
18643341
gb|AAL76272.1|transcription






factor EIL1


factor EIL1 [Vigna










radiata]



74
169
PHE0006290_8689
15
corn putative
70
50912285
ref|XP_467550.1|zinc-finger






CONSTANS-like


protein [Oryza sativa






B-box zinc finger


(japonica cultivar-group)]






protein


75
170
PHE0006423_8696
15
soy Myb61
56
92873337
gb|ABE81808.1|Homeodomain-









related [Medicago










truncatula]



76
171
PHE0002149_8748
15
corn DNA-binding
66
50941323
ref|XP_480189.1|putative






protein


LHY protein [Oryza sativa









(japonica cultivar-group)]


77
172
PHE0006023_8762
15

Arabidopsis bHLH

92
15241896
ref|NP_201067.1|DNA






family protein


binding/transcription factor









[Arabidopsis thaliana]


78
173
PHE0004987_8771
15
soy transfactor-like
63
77403669
dbj|BAE46413.1|MYB-CC






protein


type transfactor [Solanum










tuberosum]



79
174
PHE0006858_8859
7
corn MADS box
97
939781
gb|AAB00079.1|MADS box






protein


protein


80
175
PHE0006860_8863
7
corn kernel specific
100
939779
gb|AAB00078.1|MADS box






MADS


protein


81
176
PHE0006955_9129
20

Lycopersicon

67
24967140
gb|AAM33103.2|TAGL12







esculentum



transcription factor






TAGL12


[Lycopersicon esculentum]






transcription factor


82
177
PHE0006951_9137
20
AT5g52010/MSG15_9
97
15242250
ref|NP_200014.1|nucleic









acid binding/transcription









factor/zinc ion binding









[Arabidopsis thaliana]


83
178
PHE0006981_9158
15
GRAS family
59
92886232
gb|ABE88228.1|GRAS






transcription factor


family transcription factor









[Medicago truncatula]


84
179
PHE0006951_9173
15
AT5g52010/MSG15_9
97
15242250
ref|NP_200014.1|nucleic









acid binding/transcription









factor/zinc ion binding









[Arabidopsis thaliana]


85
180
PHE0004646_PMON94356.pep
17

Arabidopsis NAM

86
9758529
dbj|BAB08905.1|unnamed






family protein


protein product









[Arabidopsis thaliana]


86
181
PHE0004723_PMON94660.pep
17
soy auxin-induced
92
114733
sp|P13088|AUX22_SOYBN






protein


Auxin-induced protein









AUX22


87
182
PHE0004648_PMON95051.pep
4

Arabidopsis

93
20152540
emb|CAD29662.1|putative






putative auxin


auxin response factor 23






response factor 23


[Arabidopsis thaliana]


88
183
PHE0004357_PMON94163.pep
2
corn
47
50927517
ref|XP_473403.1|






OSJNBa0079A21.14


OSJNBa0079A21.14









[Oryza sativa









(japonica cultivar-group)]


89
184
PHE0004646_PMON94352.pep
2

Arabidopsis NAM

86
9758529
dbj|BAB08905.1|unnamed






family protein


protein product









[Arabidopsis thaliana]


90
185
PHE0004624_PMON94400.pep
2
soy auxin response
65
30027167
gb|AAP06759.1|auxin






factor-like protein


response factor-like protein









[Mangifera indica]


91
186
PHE0004463_PMON94432.pep
2
soy ethylene
48
15238727
ref|NP_197901.1|DNA






response factor


binding/transcription factor









[Arabidopsis thaliana]


92
187
PHE0004356_PMON93862.pep
1
corn LEC2/FUS3
66
56785317
dbj|BAD82277.1|regulatory









protein Viviparous-1-like









[Oryza sativa (japonica









cultivar-group)]


93
188
PHE0004332_PMON95104.pep
14
tomato Pti4
85
3342211
gb|AAC50047.1|Pti4









[Lycopersicon esculentum]


94
189
PHE0004644_PMON95096.pep
3
corn ICE1-like
50
77551194
gb|ABA93991.1|Helix-loop-









helix DNA-binding domain









containing protein [Oryza










sativa (japonica cultivar-










group)]


95
190
PHE0004723_PMON95121.pep
4
soy auxin-induced
92
114733
sp|P13088|AUX22_SOYBN






protein


Auxin-induced protein









AUX22










Selection Methods for Transgenic Plants with Enhanced Agronomic Trait


Within a population of transgenic plants regenerated from plant cells transformed with the recombinant DNA construct many plants that survive to fertile transgenic plants that produce seeds and progeny plants will not exhibit an enhanced agronomic trait. Selection from the population is necessary to identify one or more transgenic plant cells that can provide plants with the enhanced trait. Transgenic plants having enhanced agronomic traits are selected from populations of plants regenerated or derived from plant cells transformed as described herein by evaluating the plants in a variety of assays to detect an enhanced trait, e.g. enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil. These assays also may take many forms including, but not limited to, direct screening for the trait in a greenhouse or field trial or by screening for a surrogate trait. Such analyses can be directed to detecting changes in the chemical composition, biomass, physiological properties, morphology of the plant. Changes in chemical compositions such as nutritional composition of grain can be detected by analysis of the seed composition and content of protein, free amino acids, oil, free fatty acids, starch or tocopherols. Changes in biomass characteristics can be made on greenhouse or field grown plants and can include plant height, stem diameter, root and shoot dry weights; and, for corn plants, ear length and diameter. Changes in physiological properties can be identified by evaluating responses to stress conditions, for example assays using imposed stress conditions such as water deficit, nitrogen deficiency, cold growing conditions, pathogen or insect attack or light deficiency, or increased plant density. Changes in morphology can be measured by visual observation of tendency of a transformed plant with an enhanced agronomic trait to also appear to be a normal plant as compared to changes toward bushy, taller, thicker, narrower leaves, striped leaves, knotted trait, chlorosis, albino, anthocyanin production, or altered tassels, ears or roots. Other selection properties include days to pollen shed, clays to silking, leaf extension rate, chlorophyll content, leaf temperature, stand, seedling vigor, internode length, plant height, leaf number, leaf area, tillering, brace roots, stay green, stalk lodging, root lodging, plant health, barreness/prolificacy, green snap, and pest resistance. In addition, phenotypic characteristics of harvested grain may be evaluated, including number of kernels per row on the ear, number of rows of kernels on the ear, kernel abortion, kernel weight, kernel size, kernel density and physical grain quality. Although the plant cells and methods of this invention can be applied to any plant cell, plant, seed or pollen, e.g. any fruit, vegetable, grass, tree or ornamental plant, the various aspects of the invention are preferably applied to corn, soybean, cotton, canola, alfalfa, wheat and rice plants. In many cases the invention is applied to corn plants that are inherently resistant to disease from the Mal de Rio Cuarto virus or the Puccina sorghi fungus or both.


The following examples are included to demonstrate aspects of the invention, those of skill in the art should, in light of the present disclosure, appreciate that many changes can be made in the specific aspects which are disclosed and still obtain a like or similar results without departing from the spirit and scope of the invention.


Example 1
Plant Expression Constructs

This example illustrates the construction of plasmids for transferring recombinant DNA into plant cells which can be regenerated into transgenic plants of this invention.


A. Plant Expression Constructs for Corn Transformation


A base corn plant transformation vector pMON93039, as set forth in SEQ ID NO: 2202, illustrated in Table 2 and FIG. 2, was fabricated for use in preparing recombinant DNA for Agrobacterium-mediated transformation into corn tissue.












TABLE 2








Coordinates of


Function
Name
Annotation
SEQ ID NO: 2202







Agro T-DNA
B-AGRtu.right border
Agro right border sequence,
11364-11720


transfer

essential for transfer of T-




DNA.


Gene of
E-Os.Act1
Upstream promoter region
 19-775


interest

of the rice actin 1 gene


expression
E-CaMV.35S.2xA1-B3
Duplicated 35S A1-B3
 788-1120


cassette

domain without TATA box



P-Os.Act1
Promoter region of the rice
1125-1204




actin 1 gene



L-Ta.Lhcb1
5′ untranslated leader of
1210-1270




wheat major chlorophyll




a/b binding protein



I-Os.Act1
First intron and flanking
1287-1766




UTR exon sequences from




the rice actin 1 gene



T-St.Pis4
3′ non-translated region of
1838-2780




the potato proteinase




inhibitor II gene which




functions to direct




polyadenylation of the




mRNA


Plant
P-Os.Act1
Promoter from the rice
2830-3670


selectable

actin 1 gene


marker
L-Os.Act1
First exon of the rice actin 1
3671-3750


expression

gene


cassette
I-Os.Act1
First intron and flanking
3751-4228




UTR exon sequences from




the rice actin 1 gene



TS-At.ShkG-CTP2
Transit peptide region of
4238-4465





Arabidopsis EPSPS




CR-AGRtu.aroA-CP4.nat
Coding region for bacterial
4466-5833




strain CP4 native aroA




gene



T-AGRtu.nos
A 3′ non-translated region
5849-6101




of the nopaline synthase




gene of Agrobacterium





tumefaciens Ti plasmid





which functions to direct




polyadenylation of the




mRNA.


Agro T-DNA
B-AGRtu.left border
Agro left border sequence,
6168-6609


transfer

essential for transfer of T-




DNA.


Maintenance
OR-Ec.oriV-RK2
The vegetative origin of
6696-7092


in E. coli

replication from plasmid




RK2.



CR-Ec.rop
Coding region for repressor
8601-8792




of primer from the ColE1




plasmid. Expression of this




gene product interferes with




primer binding at the origin




of replication, keeping




plasmid copy number low.



OR-Ec.ori-ColE1
The minimal origin of
9220-9808




replication from the E. coli




plasmid ColE1.



P-Ec.aadA-SPC/STR
Promoter for Tn7
10339-10380




adenylyltransferase (AAD




(3″))



CR-Ec.aadA-SPC/STR
Coding region for Tn7
10381-11169




adenylyltransferase (AAD




(3″)) conferring




spectinomycin and




streptomycin resistance.



T-Ec.aadA-SPC/STR
3′ UTR from the Tn7
11170-11227




adenylyltransferase (AAD




(3″)) gene of E. coli.









Another embodiment of corn plant transformation base vector is pMON92705, as set forth in SEQ ID NO: 2203, illustrated in Table 3 and FIG. 3, which was fabricated for use in preparing recombinant DNA for Agrobacterium-mediated transformation into corn tissue.


Other base vectors similar to those described above were also constructed as listed in Table 4. See Table 4 for a summary of base vector plasmids and base vector ID's which are referenced in Table 1. Also see Table 5 for a summary of regulatory elements used in the gene expression cassette for these base vectors and SEQ ID NOs for elements.












TABLE 3








Coordinates of


Function
Name
Annotation
SEQ ID NO: 2203







Agro T-DNA
B-AGRtu. right border
Agro right border sequence,
5206-5562


transfer

essential for transfer of T-




DNA.


Gene of
P-Os.Act1
Promoter from rice actin 1
5580-6423


interest

gene


expression
L-Os.Act1
5′ UTR of rice Act7 (or 1)
6424-6503


cassette

gene



I-Os.Act1
Intron from the rice actin7
6504-6980




gene



T-St.Pis4
3′ non-translated region of the
7055-7997




potato proteinase inhibitor II




gene which functions to direct




polyadenylation of the mRNA


Plant
P-Os.Act1
Promoter from the rice actin 1
8047-8887


selectable

gene


marker
L-Os.Act1
First exon of the rice actin 1
8888-8967


expression

gene


cassette
I-Os.Act1
First intron and flanking UTR
8968-9445




exon sequences from the rice




actin 1 gene



TS-At.ShkG-CTP2
Transit peptide region of
9455-9682





Arabidopsis EPSPS




CR-AGRtu.aroA-CP4.nat
Coding region for bacterial
 9683-11050




strain CP4 native aroA gene



T-AGRtu.nos
A 3′ non-translated region of
11066-11318




the nopaline synthase gene of





Agrobacterium tumefaciens Ti





plasmid which functions to




direct polyadenylation of the




mRNA.


Agro T-DNA
B-AGRtu.left border
Agro left border sequence,
 10-451


transfer

essential for transfer of T-




DNA.


Maintenance
OR-Ec.oriV-RK2
The vegetative origin of
538-934


in E. coli

replication from plasmid RK2.



CR-Ec.rop
Coding region for repressor of
2443-2634




primer from the ColE1




plasmid. Expression of this




gene product interferes with




primer binding at the origin of




replication, keeping plasmid




copy number low.



OR-Ec.ori-ColE1
The minimal origin of
3062-3650




replication from the E. coli




plasmid ColE1.



P-Ec.aadA-SPC/STR
Promoter for Tn7
4181-4222




adenylyltransferase (AAD




(3″))



CR-Ec.aadA-SPC/STR
Coding region for Tn7
4223-5011




adenylyltransferase (AAD




(3″)) conferring




spectinomycin and




streptomycin resistance.



T-Ec.aadA-SPC/STR
3′ UTR from the Tn7
5012-5069




adenylyltransferase (AAD




(3″)) gene of E. coli.









Primers for PCR amplification of protein coding nucleotides of recombinant DNA are designed at or near the start and stop codons of the coding sequence, in order to eliminate most of the 5′ and 3′ untranslated regions. Each recombinant DNA coding for a protein identified in Table 1 is amplified by PCR prior to insertion into the insertion site within the gene of interest expression cassette of one of the base vectors as referenced in Table 1.










TABLE 4





Base Vector ID

















Base Vector for Corn


1
pMON74577


2
pMON82060


3
pMON82921


4
pMON92705


5
pMON92708


6
pMON92712


7
pMON92713


8
pMON92715


9
pMON92716


10
pMON92718


11
pMON92719


12
pMON92722


13
pMON92724


14
pMON92725


15
pMON93039


16
pMON93043



Base Vector for



Soybean And Canola


17
pMON82053


18
pMON92669


19
pMON92671


20
pMON99006






















TABLE 5







SEQ ID

SEQ ID

SEQ ID


Vector
Promoter
NO
Leader
NO
Intron
NO







pMON74577
P-Hv.Per1
2167
L-Hv.Per1
2182
I-Zm.DnaK
2197


pMON82053
P-CaMV.35S-enh
2168
NONE
/
NONE
/


pMON82060
P-Os.Act1
2169
L-Os.Act1
2183
I-Os.Act1
2198


pMON82921
P-Zm.Cik 1
2170
L-Zm.Cik 1
2184
I-Zm.Cik 1
2199


pMON92705
P-Os.Act1
2169
L-Os.Act1
2183
I-Os.Act1
2198


pMON92708
P-Zm.CA4H
2171
L-Zm.CA4H
2185
NONE
/


pMON92712
P-Os.Cut1
2172
L-Os.Cut1
2186
I-Zm.DnaK
2197


pMON92713
P-Zm.P39486
2173
L-Zm.39486
2187
I-Zm.DnaK
2197


pMON92715
P-Hv.Per1
2167
L-Hv.Per1
2182
I-Zm.DnaK
2197


pMON92716
P-Zm.FDA
2174
L-Zm.FDA
2188
I-Zm.DnaK
2197


pMON92718
P-Zm.Cik 1
2170
L-Zm.Cik1
2184
I-Zm.Cik1
2199


pMON92719
P-Zm.RAB17
2175
L-
2189
I-Zm.DnaK
2197





Zm.RAB17


pMON92722
P-CaMV.35S-enh
2168
L-
2190
I-Zm.DnaK
2197





CaMV.35S


pMON92724
P-Zm.-636aldolase-0:1:2 +
2176
L-Zm.PPDK
2191
I-Zm.DnaK
2197



P-Zm.PPDK


pMON93039
E-Os.Act1 + E-
2177
L-Ta.Lhcb1
2192
I-Os.Act1
2198



CaMV.35S.2xA1-B3 + P-



Os.Act1


pMON93043
P-Zm.EM
2178
L-Zm.EM
2193
I-Zm.DnaK
2197


pMON92669
P-At.Rca
2179
L-At.Rca
2194
NONE
/


pMON92671
P-At.SAMS3
2180
L-
2195
I-At.SAMS3
2200





At.SAMS3


pMON99006
P-CaMV.35S-enh
2168
NONE
/
NONE
/


pMON92725
P-Zm.HRGP
2181
L-Zm.HRGP
2196
I-Zm.DnaK
2197









B. Plasmids for Use in Transformation of Soybean and Canola are Also Prepared


Elements of an exemplary common expression vector plasmid pMONS2053 are shown in Table 6 below and FIG. 4.












TABLE 6








Coordinates of


Function
Name
Annotation
SEQ ID NO: 2204







Agro T-DNA
B-AGRtu.left
Agro left border sequence, essential for
6144-6585


transfer
border
transfer of T-DNA.


Plant selectable
P-At.Act7
Promoter from the Arabidopsis actin 7
6624-7861


marker

gene


expression


cassette



L-At.Act7
5′ UTR of Arabidopsis Act7 gene



I-At.Act7
Intron from the Arabidopsis actin7 gene



TS-At.ShkG-CTP2
Transit peptide region of Arabidopsis
7864-8091




EPSPS



CR-AGRtu.aroA-
Synthetic CP4 coding region with dicot
8092-9459



CP4.nno_At
preferred codon usage.



T-AGRtu.nos
A 3′ non-translated region of the
9466-9718




nopaline synthase gene of





Agrobacterium tumefaciens Ti plasmid





which functions to direct




polyadenylation of the mRNA.


Gene of interest
P-CaMV.35S-enh
Promoter for 35S RNA from CaMV
 1-613


expression

containing a duplication of the −90 to −350


cassette

region.



T-Gb.E6-3b
3′ untranslated region from the liber
 688-1002




protein E6 gene of sea-island cotton;


Agro T-DNA
B-AGRtu.right
Agro right border sequence, essential
1033-1389


transfer
border
for transfer of T-DNA.


Maintenance in
OR-Ec.oriV-RK2
The vegetative origin of replication
5661-6057



E. coli


from plasmid RK2.



CR-Ec.rop
Coding region for represser of primer
3961-4152




from the ColE1 plasmid. Expression of




this gene product interferes with primer




binding at the origin of replication,




keeping plasmid copy number low.



OR-Ec.ori-ColE1
The minimal origin of replication from
2945-3533




the E. coli plasmid ColE1.



P-Ec.aadA-
Promoter for Tn7 adenylyltransferase
2373-2414



SPC/STR
(AAD(3″))



CR-Ec.aadA-
Coding region for Tn7
1584-2372



SPC/STR
adenylyltransferase (AAD (3″))




conferring spectinomycin and




streptomycin resistance.



T-Ec.aadA-
3′ UTR from the Tn7
1526-1583



SPC/STR
adenylyltransferase (AAD (3″)) gene of





E. coli.










Primers for PCR amplification of protein coding nucleotides of recombinant DNA are designed at or near the start and stop codons of the coding sequence, in order to eliminate most of the 5′ and 3′ untranslated regions. Each recombinant DNA coding for a protein identified in Table 1 is amplified by PCR prior to insertion into the insertion site within the gene of interest expression cassette of one of the base vectors as referenced in Table 1.


C. Cotton Transformation Vector


Recombinant DNA constructs for use in transformation of cotton are also prepared. Elements of an exemplary common expression vector plasmid pMON99053 are shown in Table 7 below and FIG. 5. Primers for PCR amplification of protein coding nucleotides of recombinant DNA are designed at or near the start and stop codons of the coding sequence, in order to eliminate most of the 5′ and 3′ untranslated regions. Each recombinant DNA coding for a protein identified in Table 1 is amplified by PCR prior to insertion into the insertion site within the gene of interest expression cassette of the base vector in Table 7.












TABLE 7








Coordinates of


Function
Name
Annotation
SEQ ID NO: 2205








Agrobacterium

B-AGRtu.right border
Agro right border sequence,
 1-357


T-DNA transfer

essential for transfer of T-




DNA.


Gene of interest
Exp-CaMV.35S-enh + Ph.DnaK
Enhanced version of the 35S
 388-1091


expression

RNA promoter from CaMV


cassette

plus the petunia hsp70 5′




untranslated region



T-Ps.RbcS2-E9
The 3′ non-translated region of
1165-1797




the pea RbcS2 gene which




functions to direct




polyadenylation of the mRNA.


Plant selectable
Exp-CaMV.35S
Promoter and 5′ untranslated
1828-2151


marker

region from the 35S RNA of


expression

CaMV


cassette
CR-Ec.nptII-Tn5
Coding region for neomycin
2185-2979




phosphotransferase gene from




transposon Tn5 which confers




resistance to neomycin and




kanamycin.



T-AGRtu.nos
A 3′ non-translated region of
3011-3263




the nopaline synthase gene of





Agrobacterium tumefaciens Ti





plasmid which functions to




direct polyadenylation of the




mRNA.



Agrobacterium

B-AGRtu.left border
Agro left border sequence,
3309-3750


T-DNA transfer

essential for transfer of T-




DNA.


Maintenance in
OR-Ec.oriV-RK2
The vegetative origin of
3837-4233



E. coli


replication from plasmid RK2.



CR-Ec.rop
Coding region for repressor of
5742-5933




primer from the ColE1




plasmid. Expression of this




gene product interferes with




primer binding at the origin of




replication, keeping plasmid




copy number low.



OR-Ec.ori-ColEI
The minimal origin of
6361-6949




replication from the E. coli




plasmid ColE1.



P-Ec.aadA-SPC/STR
Promoter for Tn7
7480-7521




adenylyltransferase




(AAD(3″))



CR-Ec.aadA-SPC/STR
Coding region for Tn7
7522-8310




adenylyltransferase




(AAD(3″)) conferring




spectinomycin and




streptomycin resistance.



T-Ec.aadA-SPC/STR
3′ UTR from the Tn7
8311-8368




adenylyltransferase




(AAD(3″)) gene of E. coli.









Example 2
Corn Transformation

This example illustrates the production and identification of transgenic corn cells in seed of transgenic corn plants having an enhanced agronomic trait, i.e. enhanced nitrogen use efficiency, increased yield, enhanced water use efficiency, enhanced tolerance to cold and/or improved seed compositions as compared to control plants. Transgenic corn cells are prepared with recombinant DNA construct expressing each of the protein encoding DNAs listed in Table 1 by Agrobacterium-mediated transformation using the corn transformation vectors as disclosed in Example 1. Corn transformation is effected using methods disclosed in U.S. Patent Application Publication 2004/0344075 A1 where corn embryos are inoculated and co-cultured with the Agrobacterium tumefaciens strain ABI and the corn transformation vector. To regenerate transgenic corn plants the transgenic callus resulting from transformation is placed on media to initiate shoot development in plantlets which are transferred to potting soil for initial growth in a growth chamber followed by a mist bench before transplanting to pots where plants are grown to maturity. The plants are self fertilized and seed is harvested for screening as seed, seedlings or progeny R2 plants or hybrids, e.g., for yield trials in the screens indicated above.


Many transgenic events which survive to fertile transgenic plants that produce seeds and progeny plants do not exhibit an enhanced agronomic trait. The transgenic plants and seeds having the transgenic cells of this invention which have recombinant DNA imparting the enhanced agronomic traits are identified by screening for nitrogen use efficiency, yield, water use efficiency, cold tolerance and improved seed composition as reported in Example 7.


Example 3
Soybean Transformation

This example illustrates the production and identification of transgenic soybean cells in seed of transgenic soybean plants having an enhanced agronomic trait, i.e. enhanced nitrogen use efficiency, increased yield, enhanced water use efficiency, enhanced tolerance to cold and/or improved seed compositions as compared to control plants. Transgenic soybean cells are prepared with recombinant DNA expressing each of the protein encoding DNAs listed in Table 1 by Agrobacterium-mediated transformation using the soybean transformation vectors disclosed in Example 1. Soybean transformation is effected using methods disclosed in U.S. Pat. No. 6,384,301 where soybean meristem explants are wounded then inoculated and co-cultured with the soybean transformation vector, then transferred to selection media for 6-8 weeks to allow selection and growth of transgenic shoots.


Transgenic shoots producing roots are transferred to the greenhouse and potted in soil. Many transgenic events which survive to fertile transgenic plants that produce seeds and progeny plants do not exhibit an enhanced agronomic trait. The transgenic plants and seeds having the transgenic cells of this invention which have recombinant DNA imparting the enhanced agronomic traits are identified by screening for nitrogen use efficiency, yield, water use efficiency, cold tolerance and improved seed composition as reported in Example 7.


Example 4
Cotton Transgenic Plants with Enhanced Agronomic Traits

Cotton transformation is performed as generally described in WO0036911 and in U.S. Pat. No. 5,846,797. Transgenic cotton plants containing each of the recombinant DNA construct having a sequence of SEQ ID NO: 1 through SEQ ID NO: 95 are obtained by transforming with recombinant DNA from each of the genes identified in Table 1. Progeny transgenic plants are selected from a population of transgenic cotton events under specified growing conditions and are compared with control cotton plants. Control cotton plants are substantially the same cotton genotype but without the recombinant DNA, for example, either a parental cotton plant of the same genotype that was not transformed with the identical recombinant DNA or a negative isoline of the transformed plant. Additionally, a commercial cotton cultivar adapted to the geographical region and cultivation conditions, i.e. cotton variety ST474, cotton variety FM 958, and cotton variety Siokra L-23, are used to compare the relative performance of the transgenic cotton plants containing the recombinant DNA. The specified culture conditions are growing a first set of transgenic and control plants under “wet” conditions, i.e. irrigated in the range of 85 to 100 percent of evapotranspiration to provide leaf water potential of −14 to −18 bars, and growing a second set of transgenic and control plants under “dry” conditions; i.e: irrigated in the range of 40 to 60 percent of evapotranspiration to provide a leaf water potential of −21 to −25 bars. Pest control, such as weed and insect control is applied equally to both wet and dry treatments as needed. Data gathered during the trial includes weather records throughout the growing season including detailed records of rainfall; soil characterization information; any herbicide or insecticide applications; any gross agronomic differences observed such as leaf morphology, branching habit, leaf color, time to flowering, and fruiting pattern; plant height at various points during the trial; stand density; node and fruit number including node above white flower and node above crack boll measurements; and visual wilt scoring. Cotton boll samples are taken and analyzed for lint fraction and fiber quality. The cotton is harvested at the normal harvest timeframe for the trial area. Enhanced water use efficiency is indicated by increased yield, improved relative water content, enhanced leaf water potential; increased biomass, enhanced leaf extension rates, and improved fiber parameters.


The transgenic cotton plants of this invention are identified from among the transgenic cotton plants by agronomic trait screening as having increased yield and enhanced water use efficiency.


Example 5
Canola Transformation

This example illustrates plant transformation useful in producing the transgenic canola plants of this invention and the production and identification of transgenic seed for transgenic canola having enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil.


Tissues from in vitro grown canola seedlings are prepared and inoculated with overnight-grown Agrobacterium cells containing the recombinant DNA construct containing the DNA segment for the gene of interest cassette and a plant selectable marker cassette. Following co-cultivation with Agrobacterium, the infected tissues are allowed to grow on selection to promote growth of transgenic shoots, followed by growth of roots from the transgenic shoots. The selected planners are then transferred to the greenhouse and potted in soil. Molecular characterization are performed to confirm the presence of the gene of interest, and its expression in transgenic plants and progenies. Progeny transgenic plants are selected from a population of transgenic canola events under specified growing conditions and are compared with control canola plants: Control canola plants are substantially the same canola genotype but without the recombinant DNA, for example, either a parental canola plant of the same genotype that is not transformed with the identical recombinant DNA or a negative isoline of the transformed plant


Transgenic canola plant cells are transformed with recombinant DNA construct from each of the genes identified in Table 1. Transgenic progeny plants and seed of the transformed plant cells are screened for enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil as reported in Example 7.


Example 6
Homolog Identification

This example illustrates the identification of homologs of proteins encoded by the DNA identified in Table 1 which is used to provide transgenic seed and plants having enhanced agronomic traits. From the sequence of the homologs, homologous DNA sequence can be identified for preparing additional transgenic seeds and plants of this invention with enhanced agronomic traits.


An “All Protein Database” was constructed of known protein sequences using a proprietary sequence database and the National Center for Biotechnology Information (NCBI) non-redundant amino acid database (nr.aa). For each organism from which a polynucleotide sequence provided herein was obtained, an “Organism Protein Database” was constructed of known protein sequences of the organism; it is a subset of the All Protein Database based on the NCBI taxonomy ID for the organism.


The All Protein Database was queried using amino acid sequences provided herein as SEQ ID NO: 96 through SEQ ID NO: 193 using NCBI “blastp” program with E-value cutoff of 1 e-8. Up to 1000 top hits were kept, and separated by organism names. For each organism other than that of the query sequence, a list was kept for hits from the query organism itself with a more significant E-value than the best hit of the organism. The list contains likely duplicated genes of the polynucleotides provided herein, and is referred to as the Core List. Another list was kept for all the hits from each organism, sorted by E-value, and referred to as the Hit List.


The Organism Protein Database was queried using polypeptide sequences provided herein as SEQ ID NO: 96 through SEQ ID NO: 193 using NCBI “blastp” program with E-value cutoff of 1e-4. Up to 1000 top hits were kept. A BLAST searchable database was constructed based on these hits, and is referred to as “SubDB”, SubDB was queried with each sequence in the Hit List using NCBI “blastp” program with E-value cutoff of 1e-8. The hit with the best E-value was compared with the Core List from the corresponding organism. The hit is deemed a likely ortholog if it belongs to the Core List, otherwise it is deemed not a likely ortholog and there is no further search of sequences in the Hit List for the same organism. Homologs from a large number of distinct organisms were identified and are reported by amino acid sequences of SEQ ID NO: 194 through SEQ ID NO: 2166. The relationship of proteins of SEQ ID NO: 96 through 193 and homologs of SEQ ID NO: 194 through 2166 is identified in Table 8. The source organism for each homolog is found in the Sequence Listing.









TABLE 8





PEP SEQ ID NO: homolog SEQ ID Nos




























 96:
1993
479
2151
697
1028
1041
1751
979
522
1247





 97:
747
592
1014
1740
1904
1641
1354
1207
2134
1569
1635
407



602
635
397
2029
975


 98:
1246
1099
1100
2152
1152
1301
1474
1482
1994
1196
737
736



324
1078
1076
615
339
322
335
775
608
611
613
1745



1744
1742
1697
486
2049
1971
454
1472
789
1829
1058
1941



368
574
1555
1416
1228
1020
456
205
1081
2047
1746
489



821
1409
2081
534
330
1884
2138
1748
1621
1361
1505
1199



1985
1756
371
693
1702
1287
1766
1571
1573
550
552
1726



1891
1727
1633
634
253
457
288
290
398
405
401
1516



1356
2038
551
417
1553
2055
863
1284
1282
1917
1102
735



768
531
720
616
466
772
1708


 99:
1041
1906
491
927
1788
1116
404
1636
1231
1676
1684
139



136
135
133
1132
1026


100:
1041
1906
491
927
1788
1116
404
1636
1231
1676
1684
139



136
135
133
1132
1026


101:
894
956
458
1085
809
1448
102
1855
797
1620
714
505



1339
927
715
979
1805
639
384
578


102:
956
1085
458
809
1145
1448
505
927
715
570
459
1018



1104
477
810
455
654
101
578
1704


103:
1041
1906
491
927
1788
1116
404
1636
1231
1676
1684
139



136
135
133
1132
1026


104:
781
1325
2061
1348
1350
1346
467
256
903
915
1759
1882



1432
1433
734
669
1639
575
1203
544
525
1547
970
1403



1665
1366
652
1566
920
1984
470
319
1288
1290
1375
1296



1395
1328
1330
1311
292
661
2131
2146
2085
542
916
1519



1367
1364
1313
1314
1324
1355
1352
1293
1294
1378
1401
1399



1310
2068
2082
1160
1773


105:
1497
1872
730
361
732
2066
1954
690
201
1359
473
1879



745
1129
411
415
1715
2144
1074
1476
1417


106:
806
869
1412
264
265
248
246
1096
286
312
238
1864



1860
1243
1261
744
428
930
496
629
851
852
2148
497



516
933
1814
1478
1463
573
377
641
867
665
221
1455



991
653
601
1524
1418
526
883
2110
1185
1368
1630
1441



2004
1771
919
1098
1138
424
1731
1379
413
1186
778
833



1172
2034
1607
1791
147
144
143
887
504
988
228
936



499
1931
403
382
609
680
733
982
1725
1713
1711
1710



414
1044


107:
1369
1400
831
344
218
588
1863
1489
2031
1450
375
1709



798
1837
1681
543
1500
1005
1159
1900


108:
1936
853
1935
2105
350
594
893
2101
1268
1233
866
1422


109:
1151
1167
1166
1178
1358
630
500
538
535
1413
1564
1721



198
1898
723
1411
1019
1316
1331
1318
1999
2007
1822
519



709
329
840
1511
1502
766
671
1951
1436
501
610
612



539
1414
648
1263
997


110:
769
1861
1156
1828
1093
568
677
1659
252
250
370
276



197
1133
275
262
261
259
257
241
239
236
889
1012



1209


111:
781
1325
2061
1348
1350
1346
1332
196
903
915
1759
1882



1639
2006
667
2035
652
1566
1169
830
1220
2051
920
470



1105
1103
1290
1288
1375
1370
1296
1395
1328
1330
1311
509



579
1488
628
292
1875
952
1504
1803
779
1430
285
1857



1598
1718
796
1101
1739
423
542
916
1519
945
1313
1364



1367
1324
1314
1352
1355
1293
1294
1378
1401
1399
1310
2082



2068
1597
1160
1773
1599
1586
1582
1976
1580
1722
1545


112:
823
1253
1750
247
1859
1753
2147
1752
1544
688
1631
1347



1769
875
510
503
1663
374
722
752
942
2128
512
987



1298
1066


113:
1396
1221
433
326
406
2093
1273
1670
1655
1672
2031
1147



338
1712
553
619
986
1479
792
1837
1681
543
741


114:
1144
1143
1813
386
995
502
708
707
1886
206
1007
1279



1809
1389
1657
1644
882
1075
1069
911
1867
1023
223
1934



1541
356
1960
2062
914
1051
2057
672
476
394
438
1637



605
1079
1513
1795
1862
2028
1970
1983
646
304
971
1577



1539
755
1624
1895
2098
913


115:
800
2016
213
1056
254
799
1217
600
334
848
1134
444



185
1950
2046
1468
1888
1124
1923
953
985
1587
1000
999



1001
716
1877
828
1887
1937
621


116:
800
2016
213
1056
799
1217
848
600
334
1134
444
1139



185
1950
904
985
1587
1000
999
372
1162
1887
1937
1768



1091


117:
203
711
1833
1765
1956
1295
410
1050
822
1496
1781
762



1095
981
1006
1097
1827
1611
1632
559
527
1512
445
1473


118:
853
1935
2105
393
1499
993
1595
1514
478
299
1873
1148



893
1552
803
2090
1646
1533
1615
1260
866


119:
1517
1030
1583
359
655
1521
327
1276
815
1323
245
318



962
2078
549
888
296
2084
513
422
378
1398
1501
1785



679
2037
864
1986
390
463
1525
1576
306
1674
1245
380



1142
367
1821
1437
767
923
1878
2043
1381
1678
465
1550



1618
902
137


120:
150
121
1491
1380


121:
120
150
1491
1380


122:
659
1724
1835
507
1242
836
738
895
1572
1625
1218
879



1990
365
1299
1425
597
790
1338
1945
1691
1737
2129
1690



924
791
855
123
2154
1852
837
1981
2112


123:
659
1724
1835
507
1242
836
738
895
1572
1625
1218
879



1990
365
1299
1425
597
790
1338
1945
1691
1737
2129
1690



924
791
855
122
211
2154
1852
837
1981
2112


124:
1177
1754
521
1254
2067
471
2012
1673
834
1280
1464
400



807
622
1027
1939
1556
426
565
1360
1452
493
1569
1200



1892
321
2071
427
1831
1557
1701
1890
1889
785
1334
1149



1255
1438
1554
1838


125:
1475
1302
388
2165
2070
2073
2065
865
1077
484
589
487



604
1067
1068
760
994
585
495
890
1885
876
1285
2033



222
1762
1015
801
839
842
1871
844
435
857
859
650



1237
1238
861
1111
2111
432
694
1929
314
1170
1942
1908



1560
1216
1964
537
311
825
841
1530
1002
1909
443
1682



664
572
2083
1070
1153


126:
894
956
2013
430
1041
1448
713
1021
591
325
786
928



1034
1522
1506
1743
1905
522


127:
1503
1108
1543
1315
1881
1922
1239
2030
266
873


128:
1528
387
206
1007
271
607
1692
1991
1848
1345
963
1651



1213
249
1903
402
186
153
773
1901
1874
412
1190
480



1297
1003
1122
898
1540
660
564
1616
1051
555
683
1987



273
244
672
438
1384
1520
698
793
2052
1173
756
336



1269
1094
2145
1234
1807
943
1949
776
704
1486
1961
1776



482
625
1775
483
1526


129:
1528
387
206
1007
271
607
1692
1991
1848
1345
963
1651



1213
249
1903
402
186
153
773
1901
1874
412
1190
480



1297
1003
1122
898
1540
660
564
1616
1051
555
683
1987



273
244
672
438
1384
1520
698
793
2052
1173
756
336



1269
1094
2145
1234
1807
943
1949
776
704
1486
1961
1776



482
625
1775
483
1526


130:
1528
387
206
1007
271
607
1692
1991
1848
1345
963
1651



1213
249
1903
402
186
153
773
1901
1874
412
1190
480



1297
1003
1122
898
1540
660
564
1616
1051
555
683
1987



273
244
672
438
1384
1520
698
793
2052
1173
756
336



1269
1094
2145
1234
1807
943
1949
776
704
1486
1961
1776



482
625
1775
483
1526


131:
1528
387
206
1007
271
607
1692
1991
1848
1345
963
1651



1213
249
1903
402
186
153
773
1901
1874
412
1190
480



1297
1003
1122
898
1540
660
564
1616
1051
555
683
1987



273
244
672
438
1384
1520
698
793
2052
1173
756
336



1269
1094
2145
1234
1807
943
1949
776
704
1486
1961
1776



482
625
1775
483
1526


132:
1528
387
206
1007
271
607
1692
1991
1848
1345
963
1651



1213
249
1903
402
186
153
773
1901
1874
412
1190
480



1297
1003
1122
898
1540
660
564
1616
1051
555
683
1987



273
244
672
438
1384
1520
698
793
2052
1173
756
336



1269
1094
2145
1234
1807
943
1949
776
704
1486
1961
1776



482
625
1775
483
1526


133:
956
1906
927
979
1788
1116
404
1636
1231
1026
103
100



99
1834


134:
1157
758
451
548
1281
832
1136
1816
1804
710
858
289



618
1049
1933
532
1567
1256
878
620
1031
2118


135:
956
1906
927
979
1788
1116
404
1636
1231
1026
103
100



99
1834


136:
956
1906
927
979
1788
1116
404
1636
1231
1026
103
100



99
1834


137:
1517
1030
1583
359
655
1521
327
1276
815
1323
245
318



962
2078
549
888
296
2084
513
422
378
1398
1501
1785



679
2037
864
1986
390
463
1525
1576
306
1674
1245
380



1142
367
1821
1437
767
923
1878
2043
1381
1678
465
1550



1618
902
119


138:
1144
708
202
364
1321
219
216
1541
356
603
488
587



581
2126
394
438
1272
1666
225
651
1604
1602
989
1060



1594
243
1082
1054
1970
1865


139:
956
1906
927
979
1788
1116
404
1636
1231
1026
103
100



99
1834


140:
416
1799
662
298
1278
1126
1694
1176
1187
1819
2119
1397



468
1664
1493
932
1393
1498
2088
1811
1259
1184
369
1008



1009
1966
395
1036
1037
1039
1033
1995
1992
1040
1071
1065



1155
1141
352
354
1926
1826
1661
1053
301
1642
233
1627



2048
1593
1613
1483
1667
1010
437
1125
1080
1092
529
331



347
1982
1165
1568
1542
1451


141:
1320
2158
541
295
1150
984
284
743
1714
1728
2008
1136



1823
847
1508
2115
2130
1121
1977
1802
481
1466
1244
1140



717
1996
1979
461


142:
806
1210
871
1412
248
265
264
246
2075
286
312
238



1243
744
428
629
1131
2148
1110
1426
497
933
1814
1927



1924
641
1918
1578
926
958
1847
1197
2096
939
1368
1630



1441
886
490
1731
1729
782
557
1227
1419
1179
2045
1792



1774
1186
1219
1423
977
1607
1791
1763
1761
1789
1777
682



644
268
226
623
829
1793
1836
1265
1790
263
258
260



731
566
1376
1720
447
1579
850
1953
676
849
1308
1869



2092
567
967
2009
499
936
1931
403
382
609
680
733



982
1725
1713
1711
1710
1693
1214


143:
806
1191
1194
869
868
1412
1303
264
265
248
246
1096



286
312
315
238
1864
1860
1243
1261
744
428
930
496



629
851
852
1127
1128
2148
497
516
933
1017
1814
1478



1463
1212
573
377
641
653
601
867
991
1455
665
1524



221
1418
526
883
2110
1185
1630
1368
1441
2004
1771
919



1098
316
881
1138
424
816
1731
1792
1774
1186
464
778



1916
1955
1219
827
826
724
1423
725
727
833
1172
2034



977
1607
1791
228
106
1608
1044
1154
936
499
1931
403



382
609
680
733
982
1725
1713
1711
1710
414
887


144:
806
1191
1194
869
868
1412
1303
264
265
248
246
1096



286
312
315
238
1864
1860
1243
1261
744
428
930
496



629
851
852
1127
1128
2148
497
516
933
1017
1814
1478



1463
1212
573
377
641
653
601
867
991
1455
665
1524



221
1418
526
883
2110
1185
1630
1368
1441
2004
1771
919



1098
316
881
1138
424
816
1731
1792
1774
1186
464
778



1916
1955
1219
827
826
724
1423
725
727
833
1172
2034



977
1607
1791
228
106
1608
1044
1154
936
499
1931
403



382
609
680
733
982
1725
1713
1711
1710
414
887


145:
1570
294
1640
2053
1248
1703
1252
547
1201
1362
1386
2132



712
1327
453
363
1841
379
212
921
2060
1340
446
998



891
961
627
1928
910
805
1064
1899
1469
2108
1716
237



1972
1038
949
1732
1289
1808
1824
2010
695
560
1029
1946



1089
657
1088
158
1730
328


146:
769
281
279
282
267
1861
2102
978
1106
569
421
1638



360
2143
370
2032
1283
276
272
270
261
241
275
262



257
236
259
239
889
1012


147:
806
1191
1194
869
868
1412
1303
264
265
248
246
1096



286
312
315
238
1864
1860
1243
1261
744
428
930
496



629
851
852
1127
1128
2148
497
516
933
1017
1814
1478



1463
1212
573
377
641
653
601
867
991
1455
665
1524



221
1418
526
883
2110
1185
1630
1368
1441
2004
1771
919



1098
316
881
1138
424
816
1731
1792
1774
1186
464
778



1916
1955
1219
827
826
724
1423
725
727
833
1172
2034



977
1607
1791
228
106
1608
1044
1154
936
499
1931
403



382
609
680
733
982
1725
1713
1711
1710
414
887


148:
210
1183
1548
1291
1471
2140
436
1120
1119
1115
1118
2141



687
1656
1534
1286
905
1251
1372
313
1603
1300
638
1181



1198
220


149:
1277
524
955
658
1609
317
1180
1536
355
353
357
2005



399
229
645
425
1561
1958
1894
1312
1940
1783
1250
1390



1391
1507
917
227
640
996
2106
1446
518
1649
606
794



520
1610
1492
1208
1223
1800
1851
1706
1914
2039
941
1870



1698
434
2040
293
1778
1733
1322
1059
449
376
1846
2103



1025
1107


150:
120
121
1491
1380


151:
696
333
1013
1336
1257
1606
804
392
506
835
1193
593



1114
637
974
556
1734
906
701
1371
1086
1683
2095
1612



862
1896
362
419
1974
813
765


152:
1369
1400
831
344
218
588
1863
1489
2031
1450
375
1709



798
1837
1681
543
1500
1005
1159
1900


153:
1144
1143
1813
386
995
502
1668
1007
1279
271
1651
1024



1541
356
1540
660
1689
1051
488
2121
555
683
1987
581



132
131
130
129
128
973
672
438
1272
1666
1384
1520



698
1173
1513
336
1269
756
943
1949
776
243
1241
1970



646
304
402


154:
1405
1794
1087
2097
1304
1035
681
969
1628
2163
2100
452



1055
636
899
1083
885
2077
1549
582
1700
1947
1932
1084


155:
781
1325
2061
1348
1350
1346
467
256
903
915
1432
1433



1685
1688
1699
1669
1806
159
111
1224
1722
1645
748
1545



1853
1707
345
1798
429
787
278
1639
901
2006
614
1236



544
525
1547
667
1566
1169
1220
830
2051
920
1984
2036



470
319
1105
1288
1290
1375
1296
1395
1328
1330
1311
579



292
1875
1718
796
542
916
1519
945
1313
1367
1364
1314



1324
1352
1355
1293
1294
1378
1401
1399
1310
2068
2082
1597



1160
1773
1586
1599
1976
1582
1580
1817
673


156:
586
1434
2042
280
1523
2079
1647
705
817
1820
1915
617



1830
1135
2125
2149
1858
492
1757
819
918
818
759
692


157:
1517
1030
1583
359
655
1705
740
439
2020
1973
908
1090



1796
1696
962
318
2084
2017
1057
1117
422
378
684
554



1501
474
679
1910
864
880
624
1584
1307
234
1204
306



546
1674
1782
1245
396
1189
1211
678
367
1779
1821
1437



870
1878
2043
2058
1686
445
1381
1678
558
465
1550
1618



892
1680


158:
1570
294
1640
2053
1248
1252
1703
547
1201
1362
1386
2132



712
1327
453
363
212
1841
379
2060
446
998
1340
961



627
910
805
1928
1899
1469
1052
2108
1716
237
1972
1038



949
1289
1808
1824
2010
695
560
1029
1946
1089
657
1088



1730
328


159:
781
1325
2061
1348
1350
1346
1332
196
903
915
1759
1882



1639
2006
667
2035
652
1566
1169
830
1220
2051
920
470



1105
1103
1290
1288
1375
1370
1296
1395
1328
1330
1311
509



579
1488
628
292
1875
952
1504
1803
779
1430
285
1857



1598
1718
796
1101
1739
423
542
916
1519
945
1313
1364



1367
1324
1314
1352
1355
1293
1294
1378
1401
1399
1310
2082



2068
1597
1160
1773
1599
1586
1582
1976
1580
1722
1545


160:
1570
294
1640
2053
1248
1252
1703
547
1201
1362
1386
2132



712
1327
453
363
1559
2091
1735
1596
1402
385
1842
1695



703
1484
1373
961
1658
563
2104
702
1736
1662
1899
1469



1052
1767
699
1801
237
1716
240
242
1972
1038
528
2021



1249
300
1824
2010
695
560
1029
1946
1089
657
1088
1854



164
162
161
165
420
1113
1738
685
1843
1415


161:
1570
294
1640
2053
1248
1252
1703
547
1201
1362
1386
2132



712
1327
453
363
1559
2091
1735
1596
1402
385
1842
1695



703
1484
1373
961
1658
563
2104
702
1736
1662
1899
1469



1052
1767
699
1801
237
1716
240
242
1972
1038
528
2021



1249
300
1824
2010
695
560
1029
1946
1089
657
1088
165



164
162
1854
160
420
1113
1738
685
1843
1415


162:
1570
294
1640
2053
1248
1252
1703
547
1201
1362
1386
2132



712
1327
453
363
1559
2091
1735
1596
1402
385
1842
1695



703
1484
1373
961
1658
563
2104
702
1736
1662
1899
1469



1052
1767
699
1801
237
1716
240
242
1972
1038
528
2021



1249
300
1824
2010
695
560
1029
1946
1089
657
1088
165



164
161
1854
160
420
1113
1738
685
1843
1415


163:
1605


164:
1570
294
1640
2053
1248
1252
1703
547
1201
1362
1386
2132



712
1327
453
363
1559
2091
1735
1596
1402
385
1842
1695



703
1484
1373
961
1658
563
2104
702
1736
1662
1899
1469



1052
1767
699
1801
237
1716
240
242
1972
1038
528
2021



1249
300
1824
2010
695
560
1029
1946
1089
657
1088
162



165
161
1854
160
420
1113
1738
685
1843
1415


165:
1570
294
1640
2053
1248
1252
1703
547
1201
1362
1386
2132



712
1327
453
363
1559
2091
1735
1596
1402
385
1842
1695



703
1484
1373
961
1658
563
2104
702
1736
1662
1899
1469



1052
1767
699
1801
237
1716
240
242
1972
1038
528
2021



1249
300
1824
2010
695
560
1029
1946
1089
657
1088
161



162
164
1854
160
420
1113
1738
685
1843
1415


166:
1144
708
202
364
1321
219
216
1541
356
603
488
587



581
2126
394
438
1272
1666
225
651
1604
1602
989
1060



1594
243
1082
1054
1970
1865


167:
1177
1754
521
1254
2067
471
2012
1673
834
1280
1464
400



807
622
1027
1939
1556
426
565
1360
1452
493
1569
1200



1892
321
2071
427
1831
1557
1701
1890
1889
785
1334
1149



1255
1438
1554
1838


168:
1475
1302
388
2165
2070
2073
2065
865
1077
484
589
487



604
1067
1068
760
994
585
495
890
1885
876
1285
2033



222
1762
1015
801
839
842
1871
844
435
857
859
650



1237
1238
861
1111
2111
432
694
1929
314
1170
1942
1908



1560
1216
1964
537
311
825
841
1530
1002
1909
443
1682



664
572
2083
1070
1153


169:
1320
2158
541
295
1150
984
284
743
1714
1728
2008
1136



1823
847
1508
2115
2130
1121
1977
1802
481
1466
1244
1140



717
1996
1979
461


170:
806
1210
871
1412
248
265
264
246
2075
286
312
238



1243
744
428
629
1131
2148
1110
1426
497
933
1814
1927



1924
641
1918
1578
926
958
1847
1197
2096
939
1368
1630



1441
886
490
1731
1729
782
557
1227
1419
1179
2045
1792



1774
1186
1219
1423
977
1607
1791
1763
1761
1789
1777
682



644
268
226
623
829
1793
1836
1265
1790
263
258
260



731
566
1376
1720
447
1579
850
1953
676
849
1308
1869



2092
567
967
2009
499
936
1931
403
382
609
680
733



982
1725
1713
1711
1710
1693
1214


171:
416
1799
662
298
1278
1126
1694
1176
1187
1819
2119
1397



468
1664
1493
932
1393
1498
2088
1811
1259
1184
369
1008



1009
1966
395
1036
1037
1039
1033
1995
1992
1040
1071
1065



1155
1141
352
354
1926
1826
1661
1053
301
1642
233
1627



2048
1593
1613
1483
1667
1010
437
1125
1080
1092
529
331



347
1982
1165
1568
1542
1451


172:
894
956
2013
430
1041
1448
713
1021
591
325
786
928



1034
1522
1506
1743
1905
522


173:
203
711
1833
1765
1956
1295
410
1050
822
1496
1781
762



1095
981
1006
1097
1827
1611
1632
559
527
1512
445
1473


174:
2086
2089
2087
1061
1588
1980
757
1601
1581
2120
2107
1679



1818
1998
1997
1959
1309
1270
2056
2001
2002
2003
2018
1978



761
700
1271
2041
1975
283
291
2026
1206
1363
1495
1565



1048
1537
1016
2011
1989
1652
561
929
753
1531
1515
754



631
912
1687
1264
200
1952
2123
2135
656
960
381
966



2063
937
545
1222
1072
1392
590
2150
1856
1262
959
925



1589
940
1591
1614
811
343
1797
1205
571
1832
877
1510



1011
944
846
938
948
649
726
897
1292
1047
1944
1962



964
965
1592
968
1509
277
1893
909
1435
1648
1866
1357



1377
643
2074
2072
1623
1527
1957
1342
1344
763
1319
472



632
647
633
856
1353
1158
1410
1046
195
2166
2069
2064



907
2139
1677
2159
2160
2136
214
232
224
1845
2022
2023



1485
1487
383
440
1913
675
1600
946
274
1192
1229
175



323
1335


175:
2086
2089
1061
1588
1349
1351
1921
235
1980
757
1601
1581



2120
2107
1535
1538
1679
1818
1998
1997
1959
1309
1270
2056



1168
2001
2002
2003
2018
1978
700
1271
2041
1975
283
291



2026
2024
1206
1363
1495
1565
1048
1537
1016
2011
1989
1652



561
929
753
1634
1531
1515
754
1383
631
912
1687
1264



200
1952
2123
656
960
381
966
2063
1222
1072
1392
590



2150
1856
1262
959
925
1589
940
1591
1614
811
343
1797



1205
571
1832
877
1510
1011
944
846
938
948
649
726



897
1292
1047
1944
1962
964
1741
1592
965
968
1509
1590



1341
277
1893
909
1435
1648
1866
1377
1357
643
2074
2072



1623
1527
1957
1342
1344
763
1319
472
632
647
856
1353



1158
1046
2069
2064
907
2139
1677
2159
2160
214
224
232



1845
750
721
2022
2023
1485
1487
383
440
1913
441
1600



946
1335
1229
174
1192
274


176:
2086
1911
1456
1447
1449
751
1581
2120
1780
1431
208
1998



1997
1959
1306
2056
1168
2001
2003
2018
1978
700
1465
1444



1461
1429
1428
1967
1912
1271
2041
1215
1439
1457
1442
1016



1634
1585
596
631
215
217
200
1952
2123
656
950
960



207
209
381
2027
1671
749
1258
2063
1222
1195
1551
1902



462
194
1392
450
1424
1407
1408
1558
1109
959
925
1591



940
1385
1382
1614
494
2116
1815
877
1510
944
1460
771



783
770
1274
938
1387
1275
1988
580
1626
2153
964
1592



965
968
1787
418
1719
1230
460
1619
1232
1305
297
1494



2059
1377
1333
1948
517
643
691
2074
1844
1410
2166
1643



907
2139
954
2022
2023
1490
1406
1427
946
2137


177:
303
408
860
2124
373
1812
795
729
814
2015


178:
781
1325
2061
1350
1348
1346
467
903
915
1759
1882
1685



1688
808
2117
2094
544
1547
1770
1566
1174
920
1984
2036



470
319
1288
1290
1375
1395
1296
1330
1328
1311
342
1758



1723
292
1532
2044
990
1112
764
668
1063
1123
1969
542



916
945
1367
1364
1313
1314
1324
1355
1352
1293
1294
1378



1401
1399
1310
2082
2068
1597
1160
1773
1529
2025


179:
303
408
860
2124
373
1812
795
729
814
2015


180:
1754
508
469
1907
1965
595
1464
1458
400
514
1617
1810



1839
565
348
366
389
391
431
1825
1004


181:
1919
972
351
349
1188
2164
1749
305
287
1329
983
935



1876
780
1747
1883
1175
1454
1326
2161
1042
1920
1654
843



1717
2014
900
824
820
530
1653


182:
1225
666
2099
1453
1467
774
1337
1137
562
2080
1235
1574



1963
1518
598
670
1462
719
442
523
1443
947
2000
1445



2054
1675
931
706
584
1240
718
838
1764
2114
2109
1480



1772
1022
1171
332


183:
1528
1786
1660
387
502
1562
204
1007
992
1880
1073
788



686
1388
1267
1840
2019
2050
1938
1943
1546
872
1024
485



1934
1622
1629
1541
340
674
1477
742
511
922
231
1960



2062
1440
1689
1051
2122
1755
583
2156
2162
188
2127
1481



1563
1897
672
394
225
784
1526
448
1795
302
1862
2028
1983



646
304
310
739
1459


184:
1754
508
469
1907
1965
595
1464
1458
400
514
1617
1810



1839
565
348
366
389
391
431
1825
1004


185:
2016
213
1056
254
799
1217
600
848
334
1134
444
1343



1124
1923
904
812
953
985
1587
1000
999
716
1877
828



372
1162
854
934
599
884
1887
115
621
251
1091
1768



116
2155


186:
1144
1143
1813
386
995
502
1668
1007
1279
271
1651
1024



1541
356
1540
660
1689
1051
488
2121
555
683
1987
581



132
131
130
129
128
973
672
438
1272
1666
1384
1520



698
1173
1513
336
1269
756
943
1949
776
243
1241
1970



646
304
402


187:
269
1470
1317
255
976
320
957
1849
1365
1760
577
1968



1161
576
777
308


188:
502
1562
1007
992
1073
1880
788
686
1840
2019
1938
1267



1388
2050
1943
1546
872
663
1024
485
1629
1622
674
1477



340
511
742
922
231
1130
1202
1226
1440
1689
1051
2122



1755
583
1266
1563
672
1868
784
346
802
309
2076
358



1146
475
1575
199
536
1420
1421
1394
310
739
183
1062



1459
2133
2157
409
625
689
646
304
2162


189:
1163
896
1164
1850
337
341
1032
874
1182
230
307
540



626
1374
1045
728
746
2113
2142
533
951
980
1043
1784



845
1650
1925
498
515
1404
1930
642


190:
1919
972
351
349
1188
2164
1749
305
287
1329
983
935



1876
780
1747
1883
1175
1454
1326
2161
1042
1920
1654
843



1717
2014
900
824
820
530
1653









Example 7
Selection of Transgenic Plants with Enhanced Agronomic Trait(s)

This example illustrates identification of transgenic plant cells of the invention by screening derived plants and seeds for enhanced trait. Transgenic seed and plants in corn, soybean, cotton or canola with recombinant DNA constructs identified in Table 1 are prepared by plant cells transformed with DNA that is stably integrated into a chromosome of the plant cell. Progeny transgenic plants and seed of the transformed plant cells are screened for enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil as compared to control plants


A. Selection for Enhanced Nitrogen Use Efficiency (NUE)

Transgenic corn seeds provided by the present invention are planted in fields with three levels of nitrogen (N) fertilizer being applied, i.e. low level (0 N), medium level (80 lb/ac) and high level (180 lb/ac). A variety of physiological traits are monitored. Plants with enhanced NUE provide higher yield as compared to control plants.


B. Selection for Increased Yield

Effective selection of enhanced yielding transgenic plants uses hybrid progeny of the transgenic plants for corn, cotton, and canola, or inbred progeny of transgenic plants for soybean, canola and cotton over multiple locations with plants grown under optimal production management practices, and maximum pest control. A useful target for improved yield is a 5% to 10% increase as compared to yield produced by plants grown from seed for a control plant. Selection methods may be applied in multiple and diverse geographic locations, for example up to 16 or more locations, over one or more planting seasons, for example at least two planting seasons, to statistically distinguish yield improvement from natural environmental effects.


C. Selection for Enhanced Water Use Efficiency (WUE)

The selection process imposes a water withholding period to induce drought stress followed by watering. For example, for corn, a useful selection process imposes 3 drought/re-water cycles on plants over a total period of 15 days after an initial stress free growth period of 11 days. Each cycle consists of 5 days, with no water being applied for the first four days and a water quenching on the 5th day of the cycle. The primary phenotypes analyzed by the selection method are the changes in plant growth rate as determined by height and biomass during a vegetative drought treatment.


D. Selection for Growth Under Cold Stress

(1) Cold germination assay—Trays of transgenic and control seeds are placed in a growth chamber at 9.7° C. for 24 days (no light). Seeds having higher germination rates as compared to the control are identified.


(2) Cold field efficacy trial—A cold field efficacy trial is used to identify recombinant DNA constructs that confer enhanced cold vigor at germination and early seedling growth under early spring planting field conditions in conventional-till and simulated no-till environments. Seeds are planted into the ground around two weeks before local farmers begin to plant corn so that a significant cold stress is exerted onto the crop, named as cold treatment. Seeds also are planted under local optimal planting conditions such that the crop has little or no exposure to cold condition, named as normal treatment. At each location, seeds are planted under both cold and normal conditions with 3 repetitions per treatment. Two temperature monitors are set up at each location to monitor both air and soil temperature daily.


Seed emergence is defined as the point when the growing shoot breaks the soil surface. The number of emerged seedlings in each plot is counted everyday from the day the earliest plot begins to emerge until no significant changes in emergence occur. In addition, for each planting date, the latest date when emergence is 0 in all plots is also recorded. Seedling vigor is also rated at V3-V4 stage before the average of corn plant height reaches 10 inches, with 1=excellent early growth, 5=Average growth and 9=poor growth. Days to 50% emergence, maximum percent emergence and seedling vigor are used to determine plants with enhanced cold tolerance.


E. Screens for Transgenic Plant Seeds with Increased Protein and/or Oil Levels


This example sets forth a high-throughput selection for identifying plant seeds with improvement in seed composition using the Infratec 1200 series Grain Analyzer, which is a near-infrared transmittance spectrometer used to determine the composition of a bulk seed sample (Table 9). Near infrared analysis is a non-destructive, high-throughput method that can analyze multiple traits in a single sample scan. An NIR calibration for the analytes of interest is used to predict the values of an unknown sample. The NIR spectrum is obtained for the sample and compared to the calibration using a complex chemometric software package that provides predicted values as well as information on how well the sample fits in the calibration.


Infratec Model 1221, 1225, or 1227 with transport module by Foss North America is used with cuvette, item #1000-4033, Foss North America or for small samples with small cell cuvette, Foss standard cuvette modified by Leon Girard Co. Corn and soy check samples of varying composition maintained in check cell cuvettes are supplied by Leon Girard Co. NIT collection software is provided by Maximum Consulting Inc Software. Calculations are performed automatically by the software. Seed samples are received in packets or containers with barcode labels from the customer. The seed is poured into the cuvettes and analyzed as received.










TABLE 9







Typical sample(s):
Whole grain corn and soybean seeds


Analytical time to run method:
Less than 0.75 min per sample


Total elapsed time per run:
1.5 minute per sample


Typical and minimum sample
Corn typical: 50 cc; minimum 30 cc


size:
Soybean typical: 50 cc; minimum 5 cc


Typical analytical range:
Determined in part by the specific



calibration.



Corn - moisture 5-15%, oil 5-20%,



protein 5-30%, starch 50-75%, and



density 1.0-1.3%.



Soybean - moisture 5-15%, oil 15-



25%, and protein 35-50%.









Example 8
Consensus Sequence

This example illustrates the identification of consensus amino acid sequence for the proteins and homologs encoded by DNA that is used to prepare the transgenic seed and plants of this invention having enhanced agronomic traits.


ClustalW program was selected for multiple sequence alignments of the amino acid sequence of SEQ ID NO: 127 and its 10 homologs. Three major factors affecting the sequence alignments dramatically are (1) protein weight matrices; (2) gap open penalty; (3) gap extension penalty. Protein weight matrices available for ClustalW program include Blosum, Pam and Gonnet series. Those parameters with gap open penalty and gap extension penalty were extensively tested. On the basis of the test results, Blosum weight matrix, gap open penalty of 10 and gap extension penalty of 1 were chosen for multiple sequence alignment. FIG. 1 shows the sequences of SEQ ID NO: 127, its homologs and the consensus sequence (SEQ ID NO: 2201) at the end. The symbols for consensus sequence are (1) uppercase letters for 100% identity in all positions of multiple sequence alignment output; (2) lowercase letters for >=70% identity; symbol; (3) “X” indicated <70% identity; (4) dashes “-” meaning that gaps were in >=70% sequences.


The consensus amino acid sequence can be used to identify DNA corresponding to the full scope of this invention that is useful in providing transgenic plants, for example corn and soybean plants with enhanced agronomic traits, for example improved nitrogen use efficiency, improved yield, improved water use efficiency and/or improved growth under cold stress, due to the expression in the plants of DNA encoding a protein with amino acid sequence identical to the consensus amino acid sequence.


Example 9
Identification of Amino Acid Domain by Pfam Analysis

This example illustrates the identification of protein domain and domain module by Pfam analysis.


The amino acid sequence of the expressed proteins that are shown to be associated with an enhanced trait were analyzed for Pfam protein family against the current Pfam collection of multiple sequence alignments and Hidden Markov models using the HMMER software in the appended computer listing. The Pfam protein domains and modules for the proteins for the proteins of SEQ ID NO: 96 through 193 are shown in Tables 11 and 10 respectively. The Hidden Markov model databases for the identified pfam domains are also in the appended computer listing allowing identification of other homologous proteins and their cognate encoding DNA to enable the full breadth of the invention for a person of ordinary skill in the art. Certain proteins are identified by a single Pfam domain and others by multiple Pfam domains. For instance, the protein with amino acids of SEQ ID NO: 98 is characterized by three Pfam domains, i.e. KNOX1, KNOX2 and ELK.









TABLE 10







Pfam domain module annotation










PEP SEQ





ID NO
Gene ID
Pfam domain module
Position













154
PHE0001067_8154.pep
Homeobox
 97-158


106
PHE0002062_5913.pep
Myb_DNA-
14-61::67-112




binding::Myb_DNA-binding


140
PHE0002149_7487.pep
Myb_DNA-binding
24-69


171
PHE0002149_8748.pep
Myb_DNA-binding
24-69


107
PHE0002531_5926.pep
zf-Dof
 39-101


152
PHE0002531_7985.pep
zf-Dof
 39-101


151
PHE0003473_7927.pep
zf-C2H2::zf-C2H2
72-94::149-171


138
PHE0003664_7436.pep
AP2
21-84


166
PHE0003664_8637.pep
AP2
21-84


137
PHE0003673_7430.pep
Response_reg::Myb_DNA-
13-126::197-247




binding


188
PHE0004332_PMON95104.pep
AP2
104-168


187
PHE0004356_PMON93862.pep
B3
 23-128


183
PHE0004357_PMON94163.pep
AP2
135-199


153
PHE0004463_8059.pep
AP2
 6-69


186
PHE0004463_PMON94432.pep
AP2
 6-69


185
PHE0004624_PMON94400.pep
B3::Auxin_resp::AUX_IAA
141-246::268-350::640-805


96
PHE0004633_5508.pep
HLH
104-152


189
PHE0004644_PMON95096.pep
HLH
327-374


184
PHE0004646_PMON94352.pep
NAM
 17-139


180
PHE0004646_PMON94356.pep
NAM
 17-139


182
PHE0004648_PMON95051.pep
B3::B3
13-105::148-244


181
PHE0004723_PMON94660.pep
AUX_IAA
6


190
PHE0004723_PMON95121.pep
AUX_IAA
6


97
PHE0004738_5674.pep
NAM
96 


98
PHE0004814_5801.pep
KNOX1::KNOX2::ELK
38-82::92-147::203-244


133
PHE0004816_7303.pep
HLH
19-68


136
PHE0004816_7418.pep
HLH
19-68


135
PHE0004816_7421.pep
HLH
19-68


139
PHE0004816_7445.pep
HLH
19-68


99
PHE0004817_5809.pep
HLH
20-69


100
PHE0004817_5810.pep
HLH
20-69


103
PHE0004817_5901.pep
HLH
20-69


101
PHE0004821_5819.pep
HLH
105-154


102
PHE0004828_5826.pep
HLH
107-156


104
PHE0004861_5910.pep
GRAS
 26-325


105
PHE0004863_5912.pep
AT_hook::AT_HOOK::DUF296
121-133


119
PHE0004877_7030.pep
Response_reg::Myb_DNA-
13-126::197-247




binding


108
PHE0004914_5971.pep
Myb_DNA-
11-60::117-164




binding::Myb_DNA-binding


109
PHE0004924_5982.pep
TCP
 38-253


110
PHE0004925_5983.pep
SBP
 58-136


111
PHE0004938_5994.pep
GRAS
154-454


159
PHE0004938_8370.pep
GRAS
154-454


112
PHE0004957_6019.pep
zf-C2H2
68-90


113
PHE0004958_6020.pep
zf-Dof
104-166


114
PHE0004959_6021.pep
AP2
128-191


115
PHE0004974_6040.pep
B3::Auxin_resp
148-253


116
PHE0004975_6041.pep
B3::Auxin_resp
136-241::263-345


117
PHE0004987_6056.pep
Myb_DNA-binding
21-72


173
PHE0004987_8771.pep
Myb_DNA-binding
21-72


118
PHE0005005_7034.pep
Myb_DNA-binding
 96-143


124
PHE0006004_7082.pep
NAM
 18-147


167
PHE0006004_8667.pep
NAM
 18-147


125
PHE0006022_7105.pep
EIN3
 30-426


168
PHE0006022_8690.pep
EIN3
 30-426


126
PHE0006023_7240.pep
HLH
160-210


172
PHE0006023_8762.pep
HLH
160-210


120
PHE0006057_7048.pep
HLH
12-61


121
PHE0006057_7053.pep
HLH
12-61


150
PHE0006057_7929.pep
HLH
12-61


122
PHE0006070_7067.pep
bZIP_2
 96-153


123
PHE0006073_7072.pep
bZIP_2
 96-153


128
PHE0006237_7261.pep
AP2
 6-69


130
PHE0006237_7268.pep
AP2
 6-69


129
PHE0006237_7274.pep
AP2
 6-69


131
PHE0006237_7277.pep
AP2
 6-69


132
PHE0006237_7284.pep
AP2
 6-69


141
PHE0006290_7498.pep
zf-B_box::zf-B_box
1-47::48-90


169
PHE0006290_8689.pep
zf-B_box::zf-B_box
1-47::48-90::355-393


134
PHE0006291_7319.pep
zf-B_box::CCT
3-50::309-347


155
PHE0006350_8201.pep
GRAS
 98-403


143
PHE0006384_7737.pep
Myb_DNA-
14-61::67-112




binding::Myb_DNA-binding


144
PHE0006384_7789.pep
Myb_DNA-
14-61::67-112




binding::Myb_DNA-binding


147
PHE0006384_7839.pep
Myb_DNA-
14-61::67-112




binding::Myb_DNA-binding


142
PHE0006423_7664.pep
Myb_DNA-
14-61-67-112




binding::Myb_DNA-binding


170
PHE0006423_8696.pep
Myb_DNA-
14-61::67-112




binding::Myb_DNA-binding


148
PHE0006448_7859.pep
RWP-RK::PB1
553-604::741-823


149
PHE0006504_7876.pep
F-box::TUB
49-104::115-424


145
PHE0006507_7828.pep
CBFD_NFYB_HMF
 1-40


146
PHE0006509_7846.pep
SBP
 64-142


158
PHE0006527_8369.pep
CBFD_NFYB_HMF
26-91


157
PHE0006546_8310.pep
Response_reg::Myb_DNA-
28-141::225-275




binding


156
PHE0006605_8233.pep
GATA
223-258


163
PHE0006752_8521.pep
SRF-TF
 9-59


163
PHE0006752_8521.pep
K-box
 75-174


160
PHE0006774_8489.pep
CBFD_NFYB_HMF
 34-106


161
PHE0006778_8503.pep
CBFD_NFYB_HMF
 34-106


164
PHE0006779_8565.pep
CBFD_NFYB_HMF
 34-106


162
PHE0006780_8502.pep
CBFD_NFYB_HMF
 34-106


165
PHE0006781_8573.pep
CBFD_NFYB_HMF
 34-106


174
PHE0006858_8859.pep
SRF-TF::K-box
9-59::75-174


175
PHE0006860_8863.pep
SRF-TF::K-box
9-59::75-174


177
PHE0006951_9137.pep
zf-C2H2
152-175


179
PHE0006951_9173.pep
zf-C2H2
152-175


176
PHE0006955_9129.pep
SRF-TF::K-box
9-59::85-175


178
PHE0006981_9158.pep
GRAS
149-456
















TABLE 11







Pfam domain annotation













PEP








SEQ


ID


NO
GENE ID
Pfam domain name
Begin
Stop
Score
E-value
















154
PHE0001067_8154.pep
Homeobox
97
158
68
2.70E−17


106
PHE0002062_5913.pep
Myb_DNA-binding
14
61
44.5
3.20E−10


106
PHE0002062_5913.pep
Myb_DNA-binding
67
112
47.8
3.20E−11


140
PHE0002149_7487.pep
Myb_DNA-binding
24
69
54.4
3.40E−13


171
PHE0002149_8748.pep
Myb_DNA-binding
24
69
54.4
3.40E−13


107
PHE0002531_5926.pep
zf-Dof
39
101
133.7
4.60E−37


152
PHE0002531_7985.pep
zf-Dof
39
101
133.7
4.60E−37


151
PHE0003473_7927.pep
zf-C2H2
72
94
25.6
0.00016


151
PHE0003473_7927.pep
zf-C2H2
149
171
20.5
0.0055


138
PHE0003664_7436.pep
AP2
21
84
135.2
1.60E−37


166
PHE0003664_8637.pep
AP2
21
84
135.2
1.60E−37


137
PHE0003673_7430.pep
Response_reg
13
126
104.9
2.20E−28


137
PHE0003673_7430.pep
Myb_DNA-binding
197
247
46.4
8.90E−11


188
PHE0004332_PMON95104.pep
AP2
104
168
156.7
5.40E−44


187
PHE0004356_PMON93862.pep
B3
23
128
64.1
4.20E−16


183
PHE0004357_PMON94163.pep
AP2
135
199
150.2
5.10E−42


153
PHE0004463_8059.pep
AP2
6
69
116.5
7.10E−32


186
PHE0004463_PMON94432.pep
AP2
6
69
116.5
7.10E−32


185
PHE0004624_PMON94400.pep
B3
141
246
110.7
4.00E−30


185
PHE0004624_PMON94400.pep
Auxin_resp
268
350
198.6
1.30E−56


185
PHE0004624_PMON94400.pep
AUX_IAA
640
805
−72.2
0.00025


96
PHE0004633_5508.pep
HLH
104
152
39.4
1.10E−08


189
PHE0004644_PMON95096.pep
HLH
327
374
36.7
7.20E−08


184
PHE0004646_PMON94352.pep
NAM
17
139
58.4
2.20E−14


180
PHE0004646_PMON94356.pep
NAM
17
139
58.4
2.20E−14


182
PHE0004648_PMON95051.pep
B3
13
105
117
4.90E−32


182
PHE0004648_PMON95051.pep
B3
148
244
110.3
5.20E−30


181
PHE0004723_PMON94660.pep
AUX_IAA
6
173
339.7
4.50E−99


190
PHE0004723_PMON95121.pep
AUX_IAA
6
173
339.7
4.50E−99


97
PHE0004738_5674.pep
NAM
96
239
184.9
1.80E−52


98
PHE0004814_5801.pep
KNOX1
38
82
63.3
7.00E−16


98
PHE0004814_5801.pep
KNOX2
92
147
83.5
6.00E−22


98
PHE0004814_5801.pep
ELK
203
224
34.1
4.50E−07


133
PHE0004816_7303.pep
HLH
19
68
62.5
1.30E−15


136
PHE0004816_7418.pep
HLH
19
68
62.5
1.30E−15


135
PHE0004816_7421.pep
HLH
19
68
62.5
1.30E−15


139
PHE0004816_7445.pep
HLH
19
68
62.5
1.30E−15


99
PHE0004817_5809.pep
HLH
20
69
57.6
3.70E−14


100
PHE0004817_5810.pep
HLH
20
69
57.6
3.70E−14


103
PHE0004817_5901.pep
HLH
20
69
57.6
3.70E−14


101
PHE0004821_5819.pep
HLH
105
154
61.6
2.40E−15


102
PHE0004828_5826.pep
HLH
107
156
60
7.00E−15


104
PHE0004861_5910.pep
GRAS
26
325
369.5
4.70E−108


105
PHE0004863_5912.pep
AT_hook
121
133
17.5
0.02


105
PHE0004863_5912.pep
AT_hook
182
194
12.6
0.14


105
PHE0004863_5912.pep
DUF296
212
332
177.3
3.40E−50


119
PHE0004877_7030.pep
Response_reg
13
126
104.9
2.20E−28


119
PHE0004877_7030.pep
Myb_DNA-binding
197
247
46.4
8.90E−11


108
PHE0004914_5971.pep
Myb_DNA-binding
11
60
22.4
0.0014


108
PHE0004914_5971.pep
Myb_DNA-binding
117
164
49.3
1.20E−11


109
PHE0004924_5982.pep
TCP
38
253
139.2
1.00E−38


110
PHE0004925_5983.pep
SBP
58
136
173.4
5.30E−49


111
PHE0004938_5994.pep
GRAS
154
454
524.3
1.20E−154


159
PHE0004938_8370.pep
GRAS
154
454
524.3
1.20E−154


112
PHE0004957_6019.pep
zf-C2H2
68
90
21.6
0.0026


113
PHE0004958_6020.pep
zf-Dof
104
166
140.5
4.20E−39


114
PHE0004959_6021.pep
AP2
128
191
141.1
2.70E−39


115
PHE0004974_6040.pep
B3
148
253
114.1
3.60E−31


115
PHE0004974_6040.pep
Auxin_resp
275
357
156.9
4.80E−44


115
PHE0004974_6040.pep
AUX_IAA
623
809
−63.7
6.00E−05


116
PHE0004975_6041.pep
B3
136
241
113.4
6.10E−31


116
PHE0004975_6041.pep
Auxin_resp
263
345
170
5.40E−48


117
PHE0004987_6056.pep
Myb_DNA-binding
21
72
48.3
2.30E−11


173
PHE0004987_8771.pep
Myb_DNA-binding
21
72
48.3
2.30E−11


118
PHE0005005_7034.pep
Myb_DNA-binding
96
143
54
4.60E−13


124
PHE0006004_7082.pep
NAM
18
147
257.9
1.90E−74


167
PHE0006004_8667.pep
NAM
18
147
257.9
1.90E−74


125
PHE0006022_7105.pep
EIN3
30
426
983.5
7.20E−293


168
PHE0006022_8690.pep
EIN3
30
426
983.5
7.20E−293


126
PHE0006023_7240.pep
HLH
160
210
36.8
6.80E−08


172
PHE0006023_8762.pep
HLH
160
210
36.8
6.80E−08


120
PHE0006057_7048.pep
HLH
12
61
60.5
5.10E−15


121
PHE0006057_7053.pep
HLH
12
61
59.8
8.10E−15


150
PHE0006057_7929.pep
HLH
12
61
60.5
5.10E−15


122
PHE0006070_7067.pep
bZIP_2
96
153
65.7
1.30E−16


122
PHE0006070_7067.pep
bZIP_1
96
156
18.3
0.0014


123
PHE0006073_7072.pep
bZIP_1
96
156
18.3
0.0014


123
PHE0006073_7072.pep
bZIP_2
96
153
65.7
1.30E−16


128
PHE0006237_7261.pep
AP2
6
69
121.7
1.90E−33


130
PHE0006237_7268.pep
AP2
6
69
121.7
1.90E−33


129
PHE0006237_7274.pep
AP2
6
69
121.7
1.90E−33


131
PHE0006237_7277.pep
AP2
6
69
121.7
1.90E−33


132
PHE0006237_7284.pep
AP2
6
69
121.7
1.90E−33


141
PHE0006290_7498.pep
zf-B_box
1
47
44.6
3.00E−10


141
PHE0006290_7498.pep
zf-B_box
48
90
23.5
0.00039


141
PHE0006290_7498.pep
CCT
355
393
72.3
1.40E−18


169
PHE0006290_8689.pep
zf-B_box
1
47
44.6
3.00E−10


169
PHE0006290_8689.pep
zf-B_box
48
90
23.5
0.00039


169
PHE0006290_8689.pep
CCT
355
393
72.3
1.40E−18


134
PHE0006291_7319.pep
zf-B_box
3
50
56.9
6.10E−14


134
PHE0006291_7319.pep
CCT
309
347
69.6
9.10E−18


155
PHE0006350_8201.pep
GRAS
98
403
400
3.20E−117


143
PHE0006384_7737.pep
Myb_DNA-binding
14
61
43.1
8.70E−10


143
PHE0006384_7737.pep
Myb_DNA-binding
67
112
50
7.30E−12


144
PHE0006384_7789.pep
Myb_DNA-binding
14
61
43.1
8.70E−10


144
PHE0006384_7789.pep
Myb_DNA-binding
67
112
50
7.30E−12


147
PHE0006384_7839.pep
Myb_DNA-binding
14
61
43.1
8.70E−10


147
PHE0006384_7839.pep
Myb_DNA-binding
67
112
50
7.30E−12


142
PHE0006423_7664.pep
Myb_DNA-binding
14
61
51.6
2.50E−12


142
PHE0006423_7664.pep
Myb_DNA-binding
67
112
35.1
2.20E−07


170
PHE0006423_8696.pep
Myb_DNA-binding
14
61
51.6
2.50E−12


170
PHE0006423_8696.pep
Myb_DNA-binding
67
112
35.1
2.20E−07


148
PHE0006448_7859.pep
RWP-RK
553
604
110.7
3.80E−30


148
PHE0006448_7859.pep
PB1
741
823
92.6
1.10E−24


149
PHE0006504_7876.pep
F-box
49
104
29.5
1.10E−05


149
PHE0006504_7876.pep
Tub
115
424
691.2
7.00E−205


145
PHE0006507_7828.pep
CBFD_NFYB_HMF
1
40
31.5
2.80E−06


146
PHE0006509_7846.pep
SBP
64
142
188.1
1.90E−53


158
PHE0006527_8369.pep
CBFD_NFYB_HMF
26
91
130.9
3.20E−36


157
PHE0006546_8310.pep
Response_reg
28
141
92.2
1.40E−24


157
PHE0006546_8310.pep
Myb_DNA-binding
225
275
45.6
1.50E−10


156
PHE0006605_8233.pep
GATA
223
258
67.8
3.20E−17


163
PHE0006752_8521.pep
SRF-TF
9
59
117.1
4.70E−32


163
PHE0006752_8521.pep
K-box
75
174
163.9
3.80E−46


160
PHE0006774_8489.pep
CBFD_NFYB_HMF
34
106
112
1.60E−30


161
PHE0006778_8503.pep
CBFD_NFYB_HMF
34
106
106.2
8.90E−29


164
PHE0006779_8565.pep
CBFD_NFYB_HMF
34
106
106.5
7.30E−29


162
PHE0006780_8502.pep
CBFD_NFYB_HMF
34
106
102.1
1.50E−27


165
PHE0006781_8573.pep
CBFD_NFYB_HMF
34
106
95.6
1.30E−25


174
PHE0006858_8859.pep
SRF-TF
9
59
115.3
1.60E−31


174
PHE0006858_8859.pep
K-box
74
173
148.4
1.70E−41


175
PHE0006860_8863.pep
SRF-TF
9
59
121.5
2.20E−33


175
PHE0006860_8863.pep
K-box
74
172
152.7
8.70E−43


177
PHE0006951_9137.pep
zf-C2H2
152
175
20.1
0.0071


179
PHE0006951_9173.pep
zf-C2H2
152
175
20.1
0.0071


176
PHE0006955_9129.pep
SRF-TF
9
59
95.2
1.80E−25


176
PHE0006955_9129.pep
K-box
85
175
22.5
5.10E−06


178
PHE0006981_9158.pep
GRAS
149
456
481
1.30E−141
















TABLE 12







Description of Pfam domain











Accession
Gathering



Pfam domain name
number
cutoff
Domain description













AP2
PF00847.9
0
AP2 domain


AT_hook
PF02178.8
3.6
AT hook motif


AUX_IAA
PF02309.6
−83
AUX/IAA family


Auxin_resp
PF06507.3
25
Auxin response factor


B3
PF02362.12
26.5
B3 DNA binding domain


CBFD_NFYB_HMF
PF00808.12
18.4
Histone-like transcription factor (CBF/NF-Y)





and archaeal histone


CCT
PF06203.4
25
CCT motif


DUF296
PF03479.4
−11
Domain of unknown function (DUF296)


EIN3
PF04873.3
−137.6
Ethylene insensitive 3


ELK
PF03789.3
25
ELK domain


F-box
PF00646.21
13.6
F-box domain


GATA
PF00320.16
28.5
GATA zinc fincer


GRAS
PF03514.4
−78
GRAS family transcription factor


HLH
PF00010.15
8.2
Helix-loop-helix DNA-binding domain


Homeobox
PF00046.18
−4.1
Homeobox domain


K-box
PF01486.7
0
K-box region


KNOX1
PF03790.3
25
KNOX1 domain


KNOX2
PF03791.3
25
KNOX2 domain


Myb_DNA-binding
PF00249.19
2.8
Myb-like DNA-hinding domain


NAM
PF02365.5
−19
No apical meristem (NAM) protein


PB1
PF00564.13
12.3
PB1 domain


RWP-RK
PF02042.5
25
RWP-RK domain


Response_reg
PF00072.12
4
Response regulator receiver domain


SBP
PF03110.5
25
SBP domain


SRF-TF
PF00319.8
11
SRF-type transcription factor (DNA-binding





and dimerisation domain)


TCP
PF03634.3
−38
TCP family transcription factor


Tub
PF01167.7
−98
Tub family


bZIP_1
PF00170.10
16.5
bZIP transcription factor


bZIP_2
PF07716.4
15
Basic region leucine zipper


zf-B_box
PF00643.14
15.3
B-box zinc finger


zf-C2H2
PF00096.15
16.8
Zinc finger, C2H2 type


zf-Dof
PF02701.5
25
Dof domain, zinc finger









Example 10
Selection of Transgenic Plants with Enhanced Agronomic Trait(s)

This example illustrates the preparation and identification by selection of transgenic seeds and plants derived from transgenic plant cells of this invention where the plants and seed are identified by screening for an enhanced agronomic trait imparted by expression of a protein selected from the group including the homologous proteins identified in Example 6. Transgenic plant cells of corn, soybean, cotton, canola, wheat and rice are transformed with recombinant DNA for expressing each of the homologs identified in Example 6. Plants are regenerated from the transformed plant cells and used to produce progeny plants and seed that are screened for enhanced water use efficiency, enhanced cold tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil. Plants are identified exhibiting enhanced traits imparted by expression of the homologous proteins.

Claims
  • 1. A plant cell nucleus with stably integrated, recombinant DNA construct, wherein said recombinant DNA constrict comprises a promoter that is functional in a plant cell and that is operably linked to a DNA segment encoding a protein comprising an amino acid sequence of SEQ ID NO: 177; and wherein said recombinant DNA construct is stably integrated into a chromosome in said plant cell nucleus which is selected by screening a population or transgenic plants that have said recombinant DNA construct and an enhanced trait as compared to control plants that do not have said recombinant DNA construct in their nuclei; andwherein said enhanced trait is selected from group of enhanced traits consisting of enhanced water use efficiency, enhanced cold tolerance, enhanced heat tolerance, enhanced high salinity tolerance, enhanced shade tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil.
  • 2. A recombinant DNA construct comprising a promoter that is functional in a plant cell and that is operably linked to a DNA segment that encodes: a. at least one protein having an amino acid sequence comprising a Pfam domain module selected from the group consisting of Homeobox, Myb_DNA-binding::Myb_DNA-binding, Myb_DNA-binding, zf-Dof, zf-C2H2::zf-C2H2, AP2, Response_reg::Myb_DNA-binding, B3, B3::Auxin_resp::AUX_IAA, HLH, NAM, B3::B3, AUX_IAA, KNOX1::KNOX2::ELK, GRAS, AT_hook::AT_HOOK::DUF296, TCP, SBP; zf-C2H2, B3::Auxin_resp, EIN3, bZIP—2, zf-B_box::zf-B_box, zf-B_box::CCT, RWP-RK::PB1, F-box::TUB, CBFD_NFYB_HMF, GATA, SRF-TF, K-box, and SRF-TF::K-box;b. a protein comprising an amino acid sequence with at least 90% identity to a consensus amino acid sequence as set forth in SEQ ID NO: 2201;c. a protein having an amino acid sequence having at least 70% identity to an amino acid sequence selected from the group consisting of SEQ ID NOs 96 through SEQ ID NO: 193;ord. a protein having an amino acid sequence selected from the group consisting of SEQ ID NO: 96 through SEQ ID NO: 193;and wherein said recombinant DNA construct is stably integrated into a chromosome in a plant cell nucleus which is selected by screening a population of transgenic plants that have said recombinant DNA construct and an enhanced trait as compared to control plants that do not have said recombinant DNA construct in their nuclei; and wherein said enhanced trait is selected from group of enhanced traits consisting of enhanced water use efficiency, enhanced cold tolerance, enhanced heat tolerance, enhanced high salinity tolerance, enhanced shade tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil.
  • 3. A transgenic plant cell nucleus comprising a recombinant DNA construct of claim 2.
  • 4. A transgenic plant cell having a plant cell nucleus of claim 3.
  • 5. The transgenic plant cell of claim 4 wherein said transgenic plant cell is homozygous for said recombinant DNA construct.
  • 6. The transgenic plant cell of claim 4 further comprising DNA expressing a protein that provides tolerance from exposure to an herbicide applied at levels that are lethal to a wild type of said plant cell.
  • 7. The transgenic plant cell of claim 5 wherein said herbicide is a glyphosate, dicamba, or glufosinate compound.
  • 8. A transgenic plant comprising a plurality of plant cells of claim 4.
  • 9. The transgenic plant of claim 8 wherein said transgenic plant is homozygous for said recombinant DNA construct.
  • 10. A transgenic seed comprising a recombinant DNA construct of claim 2.
  • 11. The transgenic seed of claim 10 from a corn, soybean, cotton, canola, alfalfa, wheat or rice plant.
  • 12. A transgenic pollen grain comprising a recombinant DNA construct of claim 2.
  • 13. A method for manufacturing transgenic seeds that can be used to produce a crop of transgenic plants with an enhanced trait resulting from expression of a DNA segment in a plant cell nucleus comprising a recombinant DNA construct of claim 2, wherein said method comprises: (a) providing a population of plants produced from a parental plant having a recombinant DNA construct of claim 2;(b) screening, said population of plants for at least one of said enhanced trait and said recombinant DNA construct, wherein individual plants in said population can exhibit said trait at a level less than, essentially the same as or greater than the level that said trait is exhibited in control plants which do not contain said recombinant DNA construct, wherein said enhanced trait is selected from the group of enhanced traits consisting of enhanced water use efficiency, enhanced cold tolerance, enhanced heat tolerance, enhanced high salinity tolerance, enhanced shade tolerance, increased yield, enhanced nitrogen use efficiency, enhanced seed protein and enhanced seed oil;(c) selecting from said population one or more plants that exhibit said trait at a level greater than the level that said trait is exhibited in control plants; and(d) collecting seeds from selected plant selected from step c.
  • 14. The method of claim 13, wherein said method further comprises: (e) verifying that said recombinant DNA construct is stably integrated in said selected plants; and(f) analyzing tissue of said selected plant to determine the expression of a protein having the function of a protein having an amino acid sequence selected from the group consisting of one of SEQ ID NO: 96 through SEQ ID NO: 193.
  • 15. The method of claim 14 wherein said seed is corn, soybean, cotton, alfalfa, canola wheat or rice seed and said recombinant DNA construct is homozygous in said plant.
  • 16. A method of producing hybrid corn seed comprising: (a) acquiring hybrid corn seed from a herbicide tolerant corn plant which also has a stably-integrated, recombinant DNA construct of claim 2;(b) producing corn plants from said hybrid corn seed, wherein a fraction of the plants produced from said hybrid corn seed is homozygous for said recombinant DNA construct, a fraction of the plants produced from said hybrid corn seed is hemizygous for said recombinant DNA construct, and a fraction of the plants produced from said hybrid corn seed has none of said recombinant DNA construct;(c) selecting corn plants which are homozygous or hemizygous for said recombinant DNA construct by treating with an herbicide;(d) collecting seeds from herbicide-treated-surviving corn plants and planting said seed to produce further progeny corn plants;(e) repeating steps (c) and (d) at least once to produce an inbred corn line; and(f) crossing said inbred corn line with a second corn line to produce hybrid corn seed.
CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. Ser. No. 12/218,975, filed Jul. 18, 2008, which is a non-provisional application and claims benefit of priority to and of U.S. provisional application Ser. No. 60/961,192, filed Jul. 19, 2007 herein incorporated by reference in its entirety.

Provisional Applications (1)
Number Date Country
60961192 Jul 2007 US
Continuations (1)
Number Date Country
Parent 12218975 Jul 2008 US
Child 14544461 US