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1. The Evolution of an Invasive Plant, Sorghum halepense L. (Johnsongrass).

Author

Paterson, Andrew, Kong, WenQian, Johnston, Robyn, Nabukalu, Pheonah, Wu, Guohong, Poehlman, William, Goff, Valorie, Isaacs, Krista, Lee, Tae-Ho, Guo, Hui, Zhang, Dong, Sezen, Uzay, Kennedy, Megan, Bauer, Diane, Feltus, Frank, Weltzien, Eva, Rattunde, Henry, Barney, Jacob, Barry, Kerrie, Cox, T, and Scanlon, Michael

Subjects
crop, evolutionary novelty, invasion biology, perennial, polyploidy, rhizome, weed
Abstract

From noble beginnings as a prospective forage, polyploid Sorghum halepense (Johnsongrass) is both an invasive species and one of the worlds worst agricultural weeds. Formed by S. bicolor x S. propinquum hybridization, we show S. halepense to have S. bicolor-enriched allele composition and striking mutations in 5,957 genes that differentiate it from representatives of its progenitor species and an outgroup. The spread of S. halepense may have been facilitated by introgression from closely-related cultivated sorghum near genetic loci affecting rhizome development, seed size, and levels of lutein, a photochemical protectant and abscisic acid precursor. Rhizomes, subterranean stems that store carbohydrates and spawn clonal propagules, have growth correlated with reproductive rather than other vegetative tissues, and increase survival of both temperate cold seasons and tropical dry seasons. Rhizomes of S. halepense are more extensive than those of its rhizomatous progenitor S. propinquum, with gene expression including many alleles from its non-rhizomatous S. bicolor progenitor. The first surviving polyploid in its lineage in ∼96 million years, its post-Columbian spread across six continents carried rich genetic diversity that in the United States has facilitated transition from agricultural to non-agricultural niches. Projected to spread another 200-600 km northward in the coming century, despite its drawbacks S. halepense may offer novel alleles and traits of value to improvement of sorghum.

Published
2020

3. Comparative Physical Mapping Links Conservation of Microsynteny to Chromosome Structure and Recombination in Grasses

Author

Bowers, John E., Arias, Miguel A., Asher, Rochelle, Avise, Jennifer A., Ball, Robert T., Brewer, Gene A., Buss, Ryan W., Chen, Amy H., Edwards, Thomas M., Estill, James C., Exum, Heather E., Goff, Valorie H., Herrick, Kristen L., Karunakaran, Santhosh, Lafayette, Gmerice K., Lemke, Cornelia, Marler, Barry S., Masters, Shelley L., McMillan, Joana M., Nelson, Lisa K., Newsome, Graham A., Nwakanma, Chike C., Odeh, Rosana N., Phelps, Cynthia A., Rarick, Elizabeth A., Rogers, Carl J., Ryan, Sean P., Slaughter, Keimun A., Soderlund, Carol A., Tang, Haibao, Wing, Rod A., Paterson, Andrew H., and Phillips, Ronald L.

Published
2005

12. Comparative evolution of vegetative branching in sorghum

Author

Kong, WenQian, primary, Nabukalu, Pheonah, additional, Cox, T. Stan, additional, Goff, Valorie, additional, Robertson, Jon S., additional, Pierce, Gary, additional, Lemke, Cornelia, additional, Compton, Rosana, additional, Reeves, Jaxk, additional, and Paterson, Andrew H., additional

Published
2021
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13. The Evolution of an Invasive Plant, Sorghum halepense L. ('Johnsongrass')

Author

Paterson, Andrew H., Kong, Wenqian, Johnston, Robyn M., Nabukalu, Pheonah, Wu, Guohong, Poehlman, William L., Goff, Valorie H., Isaacs, Krista, Lee, Tae-Ho, Guo, Hui, Zhang, Dong, Sezen, U. Uzay, Kennedy, Megan, Bauer, Diane, Feltus, Frank A., Weltzien, Eva, Rattunde, Henry Frederick, Barney, Jacob, Barry, Kerrie, Cox, T. Stan, and Scanlon, Michael J.

Subjects
Genetics & Heredity, 0604 Genetics, 1801 Law, TOPHAT, GENETICS, rhizome, food and beverages, 1103 Clinical Sciences, evolutionary novelty, SUGGESTS, READ ALIGNMENT, GENOME, SORGHUM-BICOLOR, crop, RECONSTRUCTION, PLANTS, invasion biology, Life Sciences & Biomedicine, polyploidy, weed, perennial
Abstract

From noble beginnings as a prospective forage, polyploid Sorghum halepense (‘Johnsongrass’) is both an invasive species and one of the world’s worst agricultural weeds. Formed by S. bicolor x S. propinquum hybridization, we show S. halepense to have S. bicolor-enriched allele composition and striking mutations in 5,957 genes that differentiate it from representatives of its progenitor species and an outgroup. The spread of S. halepense may have been facilitated by introgression from closely-related cultivated sorghum near genetic loci affecting rhizome development, seed size, and levels of lutein, a photochemical protectant and abscisic acid precursor. Rhizomes, subterranean stems that store carbohydrates and spawn clonal propagules, have growth correlated with reproductive rather than other vegetative tissues, and increase survival of both temperate cold seasons and tropical dry seasons. Rhizomes of S. halepense are more extensive than those of its rhizomatous progenitor S. propinquum, with gene expression including many alleles from its non-rhizomatous S. bicolor progenitor. The first surviving polyploid in its lineage in ∼96 million years, its post-Columbian spread across six continents carried rich genetic diversity that in the United States has facilitated transition from agricultural to non-agricultural niches. Projected to spread another 200–600 km northward in the coming century, despite its drawbacks S. halepense may offer novel alleles and traits of value to improvement of sorghum. Published version

Published
2020

15. The Evolution of an Invasive Plant, Sorghum halepense L. (‘Johnsongrass’)

Author

Paterson, Andrew H., primary, Kong, WenQian, additional, Johnston, Robyn M., additional, Nabukalu, Pheonah, additional, Wu, Guohong, additional, Poehlman, William L., additional, Goff, Valorie H., additional, Isaacs, Krista, additional, Lee, Tae-Ho, additional, Guo, Hui, additional, Zhang, Dong, additional, Sezen, Uzay U., additional, Kennedy, Megan, additional, Bauer, Diane, additional, Feltus, Frank A., additional, Weltzien, Eva, additional, Rattunde, Henry Frederick, additional, Barney, Jacob N., additional, Barry, Kerrie, additional, Cox, T. Stan, additional, and Scanlon, Michael J., additional

Published
2020
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17. Genotyping by Sequencing of 393 Sorghum bicolor BTx623 × IS3620C Recombinant Inbred Lines Improves Sensitivity and Resolution of QTL Detection

Author

Kong, WenQian, primary, Kim, Changsoo, additional, Zhang, Dong, additional, Guo, Hui, additional, Tan, Xu, additional, Jin, Huizhe, additional, Zhou, Chengbo, additional, Shuang, Lan-shuan, additional, Goff, Valorie, additional, Sezen, Uzay, additional, Pierce, Gary, additional, Compton, Rosana, additional, Lemke, Cornelia, additional, Robertson, Jon, additional, Rainville, Lisa, additional, Auckland, Susan, additional, and Paterson, Andrew H, additional

Published
2018
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18. Genotyping by sequencing of 393Sorghum bicolorBTx623 × IS3620C recombinant inbred lines improves sensitivity and resolution of QTL detection

Author

Kong, WenQian, primary, Kim, Changsoo, additional, Zhang, Dong, additional, Guo, Hui, additional, Tan, Xu, additional, Jin, Huizhe, additional, Zhou, Chengbo, additional, Shuang, Lan-shuan, additional, Goff, Valorie, additional, Sezen, Uzay, additional, Pierce, Gary, additional, Compton, Rosana, additional, Lemke, Cornelia, additional, Robertson, Jon, additional, Rainville, Lisa, additional, Auckland, Susan, additional, and Paterson, Andrew H., additional

Published
2018
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19. Multi-Phase US Spread and Habitat Switching of a Post-Columbian Invasive, Sorghum halepense

Author

School of Plant and Environmental Sciences, Sezen, U. Uzay, Barney, Jacob, Atwater, Daniel Z., Pederson, Gary A., Pederson, Jeffrey F., Chandler, J. Mike, Cox, T. Stan, Cox, Sheila, Dotray, Peter, Kopec, David, Smith, Steven E., Schroeder, Jill, Wright, Steven D., Jiao, Yuannian, Kong, Wenqian, Goff, Valorie H., Auckland, Susan, Rainville, Lisa K., Pierce, Gary J., Lemke, Cornelia, Compton, Rosana, Phillips, Christine, Kerr, Alexandra, Mettler, Matthew, Paterson, Andrew H., School of Plant and Environmental Sciences, Sezen, U. Uzay, Barney, Jacob, Atwater, Daniel Z., Pederson, Gary A., Pederson, Jeffrey F., Chandler, J. Mike, Cox, T. Stan, Cox, Sheila, Dotray, Peter, Kopec, David, Smith, Steven E., Schroeder, Jill, Wright, Steven D., Jiao, Yuannian, Kong, Wenqian, Goff, Valorie H., Auckland, Susan, Rainville, Lisa K., Pierce, Gary J., Lemke, Cornelia, Compton, Rosana, Phillips, Christine, Kerr, Alexandra, Mettler, Matthew, and Paterson, Andrew H.

Abstract

Johnsongrass (Sorghum halepense) is a striking example of a post-Columbian founder event. This natural experiment within ecological time-scales provides a unique opportunity for understanding patterns of continent-wide genetic diversity following range expansion. Microsatellite markers were used for population genetic analyses including leaf-optimized Neighbor-Joining tree, pairwise FST, mismatch analysis, principle coordinate analysis, Tajima’s D, Fu’s F and Bayesian clusterings of population structure. Evidence indicates two geographically distant introductions of divergent genotypes, which spread across much of the US in <200 years. Based on geophylogeny, gene flow patterns can be inferred to have involved five phases. Centers of genetic diversity have shifted from two introduction sites separated by ~2000 miles toward the middle of the range, consistent with admixture between genotypes from the respective introductions. Genotyping provides evidence for a ‘habitat switch’ from agricultural to non-agricultural systems and may contribute to both Johnsongrass ubiquity and aggressiveness. Despite lower and more structured diversity at the invasion front, Johnsongrass continues to advance northward into cooler and drier habitats. Association genetic approaches may permit identification of alleles contributing to the habitat switch or other traits important to weed/invasive management and/or crop improvement.

Published
2016

20. Multi-Phase US Spread and Habitat Switching of a Post-Columbian Invasive, Sorghum halepense

Author

Sezen, U. Uzay, primary, Barney, Jacob N., additional, Atwater, Daniel Z., additional, Pederson, Gary A., additional, Pederson, Jeffrey F., additional, Chandler, J. Mike, additional, Cox, T. Stan, additional, Cox, Sheila, additional, Dotray, Peter, additional, Kopec, David, additional, Smith, Steven E., additional, Schroeder, Jill, additional, Wright, Steven D., additional, Jiao, Yuannian, additional, Kong, Wenqian, additional, Goff, Valorie, additional, Auckland, Susan, additional, Rainville, Lisa K., additional, Pierce, Gary J., additional, Lemke, Cornelia, additional, Compton, Rosana, additional, Phillips, Christine, additional, Kerr, Alexandra, additional, Mettler, Matthew, additional, and Paterson, Andrew H., additional

Published
2016
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27. Genetic Analysis of Recombinant Inbred Lines forSorghum bicolor × Sorghum propinquum

Author

Kong, Wenqian, primary, Jin, Huizhe, additional, Franks, Cleve D, additional, Kim, Changsoo, additional, Bandopadhyay, Rajib, additional, Rana, Mukesh K, additional, Auckland, Susan A, additional, Goff, Valorie H, additional, Rainville, Lisa K, additional, Burow, Gloria B, additional, Woodfin, Charles, additional, Burke, John J, additional, and Paterson, Andrew H, additional

Published
2013
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28. Reconstructing changes in the genotype, phenotype, and climatic niche of an introduced species.

Author

Atwater, Daniel Z., Sezen, U. Uzay, Goff, Valorie, Kong, Wenqian, Paterson, Andrew H., and Barney, Jacob N.

Subjects
INTRODUCED species, ECOLOGICAL niche, INVASIVE plants, PLANT variation, PLANT diversity, CLIMATE change
Abstract

An introduced species must contend with enormous environmental variation in its introduced range. In this study, we use niche models and ordination analyses to reconstruct changes in genotype, phenotype, and climatic niche of Johnsongrass Sorghum halepense, which is regarded as one of the world's most threatening invasive plants. In the United States, Johnsongrass has rapidly evolved within- and among-population genetic diversity; our results show that genetic differentiation in expanding Johnsongrass populations has resulted in phenotypic variation that is consistent with habitat and climatic variation encountered during its expansion. Moreover, Johnsongrass expanded from agricultural to non-agricultural habitat, and now, despite occupying overlapping ranges, extant agricultural and non-agricultural populations are genetically and phenotypically distinct and manifest different plastic responses when encountering environmental variation. Non-agricultural accessions are broadly distributed in climatic and geographic space and their fitness traits demonstrate plastic responses to common garden conditions that are consistent with local specialization. In contrast, agricultural accessions demonstrate 'general purpose' plastic responses and have more restricted climatic niches and geographic distributions. They also grow much larger than non-agricultural accessions. If these differences are adaptive, our results suggest that adaptation to local habitat variation plays a crucial role in the ecology of this invader. Further, its success relates to its ability to succeed on dual fronts, by responding simultaneously to habitat and climate variability and by capitalizing on differential responses to these factors during its range expansion. [ABSTRACT FROM AUTHOR]

Published
2016
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29. GENETIC ANALYSIS OF RHIZOMATOUSNESS AND ITS RELATIONSHIP WITH VEGETATIVE BRANCHING OF RECOMBINANT INBRED LINES OF SORGHUM BICOLOR X S. PROPINQUUM.

Author

Kong, Wenqian, Kim, Changsoo, Goff, Valorie H., Zhang, Dong, and Paterson, Andrew H.

Subjects
SORGHUM research, GENETIC research, PLANT genetics, PLANT epigenetics, PLANT breeding, PLANT genomes
Abstract

* Premise of the study: Rhizomes, subterranean stems that grow horizontally, are a storage organ that is highly associated with overwintering and regrowth. This quantitative study aimed to discover genetic determinants of rhizomatousness, an important trait related to perenniality and invasiveness. * Methods: A population of 161 individuals of a recombinant inbred line (RIL) derived from morphologically distinct parents, Sorghum bicolor and Sorghum propinquum, which segregates for rhizomatousness, was phenotyped and genetically mapped. * Key results: Seven genomic regions influenced rhizomatousness in this population; four were "consensus" regions that correspond with previously detected quantitative trait loci (QTLs) in an F2 population of the same pedigree and with different levels of vegetative branching. Because rhizomatousness is a plastic trait that is greatly influenced by environment, overlap between regions discovered in the RIL and F2 populations validates the position and effect of QTLs. Correspondence with regions influencing vegetative branching indicates that some genes and biochemical pathways may influence both vegetative branching and rhizomatousness, while genes influencing only one trait may confer divergent aspects of development of these organs. * Conclusions: Identifying genes conferring rhizomatousness and understanding their functions may provide opportunities to regulate plant growth for diverse applications. Increasing rhizomatousness may promote the productivity and perenniality of many grasses, especially biomass-dedicated crops, while decreasing rhizomatousness may improve monocarpic grain production and offer means to control many noxious weeds. [ABSTRACT FROM AUTHOR]

Published
2015
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30. Genetic analysis of inflorescence and plant height components in sorghum (Panicoidae) and comparative genetics with rice (Oryzoidae).

Author

Dong Zhang, Wenqian Kong, Robertson, Jon, Goff, Valorie H., Epps, Ethan, Kerr, Alexandra, Mills, Gabriel, Cromwell, Jay, Lugin, Yelena, Phillips, Christine, and Paterson, Andrew H.

Subjects
INFLORESCENCES, SORGHUM research, FLOWERING time, PLANTS, DOMESTICATION of plants
Abstract

Background: Domestication has played an important role in shaping characteristics of the inflorescence and plant height in cultivated cereals. Taking advantage of meta-analysis of QTLs, phylogenetic analyses in 502 diverse sorghum accessions, GWAS in a sorghum association panel (n = 354) and comparative data, we provide insight into the genetic basis of the domestication traits in sorghum and rice. Results: We performed genome-wide association studies (GWAS) on 6 traits related to inflorescence morphology and 6 traits related to plant height in sorghum, comparing the genomic regions implicated in these traits by GWAS and QTL mapping, respectively. In a search for signatures of selection, we identify genomic regions that may contribute to sorghum domestication regarding plant height, flowering time and pericarp color. Comparative studies across taxa show functionally conserved 'hotspots' in sorghum and rice for awn presence and pericarp color that do not appear to reflect corresponding single genes but may indicate co-regulated clusters of genes. We also reveal homoeologous regions retaining similar functions for plant height and flowering time since genome duplication an estimated 70 million years ago or more in a common ancestor of cereals. In most such homoeologous QTL pairs, only one QTL interval exhibits strong selection signals in modern sorghum. Conclusions: Intersections among QTL, GWAS and comparative data advance knowledge of genetic determinants of inflorescence and plant height components in sorghum, and add new dimensions to comparisons between sorghum and rice. [ABSTRACT FROM AUTHOR]

Published
2015
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31. Seed shattering in a wild sorghum is conferred by a locus unrelated to domestication.

Author

Haibao Tang, Cuevas, Hugo E., Das, Sayan, Sezen, Uzay U., Chengbo Zhou, Hui Guo, Goff, Valorie H., Zhengxiang Ge, Clemente, Thomas E., and Paterson, Andrew H.

Subjects
DOMESTICATION of plants, SUGAR crops, FORAGE plants, SORGHUM, LOCUS (Genetics), TRANSCRIPTION factors
Abstract

Suppression of seed shattering was a key step during crop domestication that we have previously suggested to be convergent among independent cereal lineages. Positional, association, expression, and mutant complementation data all implicate a WRKY transcription factor, SpWRKY, in conferring shattering to a wild sorghum relative. Sorghum propinquum. We hypothesize that SpWRKY functions in a manner analogous to Medicago and Ara-bidopsis homologs that regulate cell wall biosynthesis genes, with low expression toward the end of floral development derepressing downstream cell wall biosynthesis genes to allow deposition of lignin that initiates the abscission zone in the seed-pedicel junction. The recent discovery of a YABBY locus that confers shattering within Sorghum bicolor and other cereals validated our prior hypothesis that some parallel domestication may have been convergent. Ironically, however, the shattering allele of SpWRKY appears to be recently evolved in S. propinquum and illustrates a case in which the genetic control of a trait in a wild relative fails to extrapolate even to closely related crops. Remarkably, the SpWRKY and YABBY loci lie only 300 kb apart and may have appeared to be a single genetic locus in some sorghum populations. [ABSTRACT FROM AUTHOR]

Published
2013
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32. Genotyping by Sequencing of 393 Sorghum bicolor BTx623 × IS3620C Recombinant Inbred Lines Improves Sensitivity and Resolution of QTL Detection.

Author

WenQian Kong, Changsoo Kim, Dong Zhang, Hui Guo, Xu Tan, Huizhe Jin, Chengbo Zhou, Lan-shuan Shuang, Goff, Valorie, Sezen, Uzay, Pierce, Gary, Compton, Rosana, Lemke, Cornelia, Robertson, Jon, Rainville, Lisa, Auckland, Susan, and Paterson, Andrew H.

Subjects
*GENOTYPES, *SINGLE nucleotide polymorphisms, SORGHUM genetics
Abstract

We describe a genetic map with a total of 381 bins of 616 genotyping by sequencing (GBS)- based SNP markers in a F6-F8 recombinant inbred line (RIL) population of 393 individuals derived from crossing S. bicolor BTx623 to S. bicolor IS3620C, a guinea line substantially diverged from BTx623. Five segregation distorted regions were found with four showing enrichment for S. bicolor alleles, suggesting possible selection during formation of this RIL population. A quantitative trait locus (QTL) study with this number of individuals, tripled relative to prior studies of this cross, provided resources, validated previous findings, and demonstrated improved power to detect plant height and flowering time related QTL relative to other published studies. An unexpected low correlation between flowering time and plant height permitted us to separate QTL for each trait and provide evidence against pleiotropy. Ten non- random syntenic regions conferring QTL for the same trait suggest that those QTL may represent alleles at genes functioning in the same manner since the 96 million year ago genome duplication that created these syntenic relationships, while syntenic regions conferring QTL for different trait may suggest sub-functionalization after duplication. Collectively, this study provides resources for marker-assisted breeding, as well as a framework for fine mapping and subsequent cloning of major genes for important traits such as plant height and flowering time in sorghum. [ABSTRACT FROM AUTHOR]

Published
2018
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33. Comparative Genetics of Seed Size Traits in Divergent Cereal Lineages Represented by Sorghum (Panicoidae) and Rice (Oryzoidae).

Author

Dong Zhang, Jingping Li, Compton, Rosana O., Robertson, Jon, Goff, Valorie H., Epps, Ethan, Wenqian Kong, Changsoo Kim, and Paterson, Andrew H.

Subjects
*SORGHUM research, *SEED research, *GRAIN genetics
Abstract

Seed size is closely related to fitness of wild plants, and its modification has been a key recurring element in domestication of seed/grain crops. In sorghum, a genomic and morphological model for panicoid cereals, a rich history of research into the genetics of seed size is reflected by a total of 13 likelihood intervals determined by conventional QTL (linkage) mapping in 11 nonoverlapping regions of the genome. To complement QTL data and investigate whether the discovery of seed size QTL is approaching "saturation," we compared QTL data to GWAS for seed mass, seed length, and seed width studied in 354 accessions from a sorghum association panel (SAP) that have been genotyped at 265,487 SNPs. We identified nine independent GWAS-based "hotspots" for seed size associations. Targeted resequencing near four association peaks with the most notable linkage disequilibrium provides further support of the role(s) of these regions in the genetic control of sorghum seed size and identifies two candidate causal variants with nonsynonymous mutations. Of nine GWAS hotspots in sorghum, seven have significant correspondence with rice QTL intervals and known genes for components of seed size on orthologous chromosomes. Identifying intersections between positional and association genetic data are a potentially powerful means to mitigate constraints associated with each approach, and nonrandom correspondence of sorghum (panicoid) GWAS signals to rice (oryzoid) QTL adds a new dimension to the ability to leverage genetic data about this important trait across divergent plants. [ABSTRACT FROM AUTHOR]

Published
2015
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34. Genetic Analysis of Stem Diameter and Water Contents To Improve Sorghum Bioenergy Efficiency.

Author

Kong W, Jin H, Goff VH, Auckland SA, Rainville LK, and Paterson AH

Subjects
Chromosome Mapping, Genome-Wide Association Study, Phenotype, Quantitative Trait Loci, Water, Sorghum genetics
Abstract

Biofuel made from agricultural products has the potential in contribute to a stable supply of fuel for growing energy demands. Some salient plant traits, such as stem diameter and water content, and their relationship to other important biomass-related traits are so far poorly understood. Here, we performed QTL mapping for three stem diameter and two water content traits in a S. bicolor BTx623 x IS3620c recombinant inbred line population of 399 genotypes, and validated the genomic regions identified using genome-wide association studies (GWAS) in a diversity panel of 354 accessions. The discovery of both co-localized and non-overlapping loci affecting stem diameter traits suggests that stem widths at different heights share some common genetic control, but also have some distinct genetic influences. Co-localizations of stem diameter and water content traits with other biomass traits including plant height, flowering time and the 'dry' trait, suggest that their inheritance may be linked functionally (pleiotropy) or physically (linkage disequilibrium). Water content QTL in homeologous regions resulting from an ancient duplication event may have been retained and continue to have related functions for an estimated 96 million years. Integration of QTL and GWAS data advanced knowledge of the genetic basis of stem diameter and water content components in sorghum, which may lead to tools and strategies for either enhancing or suppressing these traits, supporting advances toward improved quality of plant-based biomass for biofuel production., (Copyright © 2020 Kong et al.)

Published
2020
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35. Genotyping by Sequencing of 393 Sorghum bicolor BTx623 × IS3620C Recombinant Inbred Lines Improves Sensitivity and Resolution of QTL Detection.

Author

Kong W, Kim C, Zhang D, Guo H, Tan X, Jin H, Zhou C, Shuang LS, Goff V, Sezen U, Pierce G, Compton R, Lemke C, Robertson J, Rainville L, Auckland S, and Paterson AH

Subjects
Flowers genetics, Genome, Plant, Genotyping Techniques standards, Inbreeding, Plant Breeding methods, Recombination, Genetic, Sensitivity and Specificity, Sorghum growth & development, Synteny, Genotyping Techniques methods, Quantitative Trait Loci, Sorghum genetics
Abstract

We describe a genetic map with a total of 381 bins of 616 genotyping by sequencing (GBS)-based SNP markers in a F 6 -F 8 recombinant inbred line (RIL) population of 393 individuals derived from crossing S. bicolor BTx623 to S. bicolor IS3620C, a guinea line substantially diverged from BTx623. Five segregation distorted regions were found with four showing enrichment for S. bicolor alleles, suggesting possible selection during formation of this RIL population. A quantitative trait locus (QTL) study with this number of individuals, tripled relative to prior studies of this cross, provided resources, validated previous findings, and demonstrated improved power to detect plant height and flowering time related QTL relative to other published studies. An unexpected low correlation between flowering time and plant height permitted us to separate QTL for each trait and provide evidence against pleiotropy. Ten non- random syntenic regions conferring QTL for the same trait suggest that those QTL may represent alleles at genes functioning in the same manner since the 96 million year ago genome duplication that created these syntenic relationships, while syntenic regions conferring QTL for different trait may suggest sub-functionalization after duplication. Collectively, this study provides resources for marker-assisted breeding, as well as a framework for fine mapping and subsequent cloning of major genes for important traits such as plant height and flowering time in sorghum., (Copyright © 2018 Kong et al.)

Published
2018
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36. Comparative Genetics of Seed Size Traits in Divergent Cereal Lineages Represented by Sorghum (Panicoidae) and Rice (Oryzoidae).

Author

Zhang D, Li J, Compton RO, Robertson J, Goff VH, Epps E, Kong W, Kim C, and Paterson AH

Subjects
Chromosome Mapping, Chromosomes, Plant, Edible Grain genetics, Genetic Association Studies, Genome-Wide Association Study, Genotype, Organ Size genetics, Phenotype, Quantitative Trait Loci genetics, Zea mays genetics, Ecotype, Oryza genetics, Quantitative Trait, Heritable, Seeds anatomy & histology, Seeds genetics, Sorghum genetics
Abstract

Seed size is closely related to fitness of wild plants, and its modification has been a key recurring element in domestication of seed/grain crops. In sorghum, a genomic and morphological model for panicoid cereals, a rich history of research into the genetics of seed size is reflected by a total of 13 likelihood intervals determined by conventional QTL (linkage) mapping in 11 nonoverlapping regions of the genome. To complement QTL data and investigate whether the discovery of seed size QTL is approaching "saturation," we compared QTL data to GWAS for seed mass, seed length, and seed width studied in 354 accessions from a sorghum association panel (SAP) that have been genotyped at 265,487 SNPs. We identified nine independent GWAS-based "hotspots" for seed size associations. Targeted resequencing near four association peaks with the most notable linkage disequilibrium provides further support of the role(s) of these regions in the genetic control of sorghum seed size and identifies two candidate causal variants with nonsynonymous mutations. Of nine GWAS hotspots in sorghum, seven have significant correspondence with rice QTL intervals and known genes for components of seed size on orthologous chromosomes. Identifying intersections between positional and association genetic data are a potentially powerful means to mitigate constraints associated with each approach, and nonrandom correspondence of sorghum (panicoid) GWAS signals to rice (oryzoid) QTL adds a new dimension to the ability to leverage genetic data about this important trait across divergent plants., (Copyright © 2015 Zhang et al.)

Published
2015
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37. Genetic analysis of recombinant inbred lines for Sorghum bicolor × Sorghum propinquum.

Author

Kong W, Jin H, Franks CD, Kim C, Bandopadhyay R, Rana MK, Auckland SA, Goff VH, Rainville LK, Burow GB, Woodfin C, Burke JJ, and Paterson AH

Subjects
Crosses, Genetic, Microsatellite Repeats genetics, Quantitative Trait Loci genetics, Recombination, Genetic genetics, Breeding methods, Chromosome Mapping, Genotype, Hybridization, Genetic, Sorghum genetics
Abstract

We describe a recombinant inbred line (RIL) population of 161 F5 genotypes for the widest euploid cross that can be made to cultivated sorghum (Sorghum bicolor) using conventional techniques, S. bicolor × Sorghum propinquum, that segregates for many traits related to plant architecture, growth and development, reproduction, and life history. The genetic map of the S. bicolor × S. propinquum RILs contains 141 loci on 10 linkage groups collectively spanning 773.1 cM. Although the genetic map has DNA marker density well-suited to quantitative trait loci mapping and samples most of the genome, our previous observations that sorghum pericentromeric heterochromatin is recalcitrant to recombination is highlighted by the finding that the vast majority of recombination in sorghum is concentrated in small regions of euchromatin that are distal to most chromosomes. The advancement of the RIL population in an environment to which the S. bicolor parent was well adapted (indeed bred for) but the S. propinquum parent was not largely eliminated an allele for short-day flowering that confounded many other traits, for example, permitting us to map new quantitative trait loci for flowering that previously eluded detection. Additional recombination that has accrued in the development of this RIL population also may have improved resolution of apices of heterozygote excess, accounting for their greater abundance in the F5 than the F2 generation. The S. bicolor × S. propinquum RIL population offers advantages over early-generation populations that will shed new light on genetic, environmental, and physiological/biochemical factors that regulate plant growth and development.

Published
2013
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