Your search keyword '"Brian Abernathy"' showing total 28 results

1. Graph-based pangenomics maximizes genotyping density and reveals structural impacts on fungal resistance in melon

Author

Justin N. Vaughn, Sandra E. Branham, Brian Abernathy, Amanda M. Hulse-Kemp, Adam R. Rivers, Amnon Levi, and William P. Wechter

Subjects

Science

Abstract

The power of pangenomic graphs to improve genetic mapping is still unclear. Here, the authors demonstrate its value in identification of genetic variants associated with disease resistance traits in melon using PanPipes, a pangenome construction and low-coverage genotype-by-sequencing pipeline.

Published

2022

2. Dynamics of a Novel Highly Repetitive CACTA Family in Common Bean (Phaseolus vulgaris)

Author

Dongying Gao, Dongyan Zhao, Brian Abernathy, Aiko Iwata-Otsubo, Alfredo Herrera-Estrella, Ning Jiang, and Scott A. Jackson

Subjects

DNA transposon, CACTA, genome evolution, common bean, Phaseolus, Genetics, QH426-470

Abstract

Transposons are ubiquitous genomic components that play pivotal roles in plant gene and genome evolution. We analyzed two genome sequences of common bean (Phaseolus vulgaris) and identified a new CACTA transposon family named pvCACTA1. The family is extremely abundant, as more than 12,000 pvCACTA1 elements were found. To our knowledge, this is the most abundant CACTA family reported thus far. The computational and fluorescence in situ hybridization (FISH) analyses indicated that the pvCACTA1 elements were concentrated in terminal regions of chromosomes and frequently generated AT-rich 3 bp target site duplications (TSD, WWW, W is A or T). Comparative analysis of the common bean genomes from two domesticated genetic pools revealed that new insertions or excisions of pvCACTA1 elements occurred after the divergence of the two common beans, and some of the polymorphic elements likely resulted in variation in gene sequences. pvCACTA1 elements were detected in related species but not outside the Phaseolus genus. We calculated the molecular evolutionary rate of pvCACTA1 transposons using orthologous elements that indicated that most transposition events likely occurred before the divergence of the two gene pools. These results reveal unique features and evolution of this new transposon family in the common bean genome.

Published

2016

3. Fluorescence In Situ Hybridization (FISH)-Based Karyotyping Reveals Rapid Evolution of Centromeric and Subtelomeric Repeats in Common Bean (Phaseolus vulgaris) and Relatives

Author

Aiko Iwata-Otsubo, Brittany Radke, Seth Findley, Brian Abernathy, C. Eduardo Vallejos, and Scott A. Jackson

Subjects

common bean, karyotyping, fluorescence in situ hybridization, satellite repeats, chromosome evolution, Genetics, QH426-470

Abstract

Fluorescence in situ hybridization (FISH)-based karyotyping is a powerful cytogenetics tool to study chromosome organization, behavior, and chromosome evolution. Here, we developed a FISH-based karyotyping system using a probe mixture comprised of centromeric and subtelomeric satellite repeats, 5S rDNA, and chromosome-specific BAC clones in common bean, which enables one to unambiguously distinguish all 11 chromosome pairs. Furthermore, we applied the karyotyping system to several wild relatives and landraces of common bean from two distinct gene pools, as well as other related Phaseolus species, to investigate repeat evolution in the genus Phaseolus. Comparison of karyotype maps within common bean indicates that chromosomal distribution of the centromeric and subtelomeric satellite repeats is stable, whereas the copy number of the repeats was variable, indicating rapid amplification/reduction of the repeats in specific genomic regions. In Phaseolus species that diverged approximately 2–4 million yr ago, copy numbers of centromeric repeats were largely reduced or diverged, and chromosomal distributions have changed, suggesting rapid evolution of centromeric repeats. We also detected variation in the distribution pattern of subtelomeric repeats in Phaseolus species. The FISH-based karyotyping system revealed that satellite repeats are actively and rapidly evolving, forming genomic features unique to individual common bean accessions and Phaseolus species.

Published

2016

4. TAR30, a homolog of the canonical plant TTTAGGG telomeric repeat, is enriched in the proximal chromosome regions of peanut (Arachis hypogaea L.)

Author

Dongying Gao, Eliza F. M. B. Nascimento, Soraya C. M. Leal-Bertioli, Brian Abernathy, Scott A. Jackson, Ana C. G. Araujo, and David J. Bertioli

Subjects

Arachis, Genetics, Hybridization, Genetic, Telomere, Genome, Plant, In Situ Hybridization, Fluorescence

Abstract

Telomeres are the physical ends of eukaryotic linear chromosomes that play critical roles in cell division, chromosome maintenance, and genome stability. In many plants, telomeres are comprised of TTTAGGG tandem repeat that is widely found in plants. We refer to this repeat as canonical plant telomeric repeat (CPTR). Peanut (Arachis hypogaea L.) is a spontaneously formed allotetraploid and an important food and oil crop worldwide. In this study, we analyzed the peanut genome sequences and identified a new type of tandem repeat with 10-bp basic motif TTTT(C/T)TAGGG named TAndem Repeat (TAR) 30. TAR30 showed significant sequence identity to TTTAGGG repeat in 112 plant genomes suggesting that TAR30 is a homolog of CPTR. It also is nearly identical to the telomeric tandem repeat in Cestrum elegans. Fluorescence in situ hybridization (FISH) analysis revealed interstitial locations of TAR30 in peanut chromosomes but we did not detect visible signals in the terminal ends of chromosomes as expected for telomeric repeats. Interestingly, different TAR30 hybridization patterns were found between the newly induced allotetraploid ValSten and its diploid wild progenitors. The canonical telomeric repeat TTTAGGG is also present in the peanut genomes and some of these repeats are closely adjacent to TAR30 from both cultivated peanut and its wild relatives. Overall, our work identifies a new homolog of CPTR and reveals the unique distributions of TAR30 in cultivated peanuts and wild species. Our results provide new insights into the evolution of tandem repeats during peanut polyploidization and domestication.

Published

2022

5. Legacy genetics of Arachis cardenasii in the peanut crop shows the profound benefits of international seed exchange

Author

Carolina Chavarro, Neil Halpin, Steven B. Cannon, H. T. Stalker, Dongying Gao, Shona Wood, Marcos Doniseti Michelotto, Walid Korani, Peggy Ozias-Akins, Soraya C. M. Leal-Bertioli, Andrew Farmer, João Francisco dos Santos, Scott A. Jackson, David J. Bertioli, Vania C. R. Azevedo, G. C. Wright, Daniel Fonceka, Carolina Ballén-Taborda, Brian E. Scheffler, Josh Clevenger, Brian Abernathy, Jane Grimwood, Ye Chu, Ignácio José de Godoy, Jacqueline D. Campbell, Ramey C Youngblood, Márcio C. Moretzsohn, and Justin N. Vaughn

Subjects

Germplasm, Crops, Agricultural, Genetic Markers, disease resistance, Asia, Arachis, DNA, Plant, Oceania, Biology, Accession, Species Specificity, Convention on Biological Diversity, Genetics, Genetic diversity, Multidisciplinary, Food security, business.industry, Agricultural Sciences, fungi, food and beverages, Chromosome Mapping, Genetic Variation, food security, Biological Sciences, biology.organism_classification, Plant Breeding, Agriculture, wild species, Africa, Seeds, Biological dispersal, Hybridization, Genetic, peanut, sense organs, business, Arachis cardenasii, Genome, Plant

Abstract

Significance A great challenge for humanity is feeding its growing population while minimizing ecosystem damage and climate change. Here, we uncover the global benefits arising from the introduction of one wild species accession to peanut-breeding programs decades ago. This work emphasizes the importance of biodiversity to crop improvement: peanut cultivars with genetics from this wild accession provided improved food security and reduced use of fungicide sprays. However, this study also highlights the perilous consequences of changes in legal frameworks and attitudes concerning biodiversity. These changes have greatly reduced the botanical collections, seed exchanges, and international collaborations which are essential for the continued diversification of crop genetics and, consequently, the long-term resilience of crops against evolving pests and pathogens and changing climate., The narrow genetics of most crops is a fundamental vulnerability to food security. This makes wild crop relatives a strategic resource of genetic diversity that can be used for crop improvement and adaptation to new agricultural challenges. Here, we uncover the contribution of one wild species accession, Arachis cardenasii GKP 10017, to the peanut crop (Arachis hypogaea) that was initiated by complex hybridizations in the 1960s and propagated by international seed exchange. However, until this study, the global scale of the dispersal of genetic contributions from this wild accession had been obscured by the multiple germplasm transfers, breeding cycles, and unrecorded genetic mixing between lineages that had occurred over the years. By genetic analysis and pedigree research, we identified A. cardenasii–enhanced, disease-resistant cultivars in Africa, Asia, Oceania, and the Americas. These cultivars provide widespread improved food security and environmental and economic benefits. This study emphasizes the importance of wild species and collaborative networks of international expertise for crop improvement. However, it also highlights the consequences of the implementation of a patchwork of restrictive national laws and sea changes in attitudes regarding germplasm that followed in the wake of the Convention on Biological Diversity. Today, the botanical collections and multiple seed exchanges which enable benefits such as those revealed by this study are drastically reduced. The research reported here underscores the vital importance of ready access to germplasm in ensuring long-term world food security.

Published

2021

6. Evaluating two different models of peanut’s origin

Author

David J. Bertioli, Brian Abernathy, Steven B. Cannon, Josh Clevenger, and Guillermo Seijo

Subjects

Evolutionary biology, Genetics, MEDLINE, Karyotype, Fabaceae, Biology, Domestication

Published

2020

7. Genic C-Methylation in Soybean Is Associated with Gene Paralogs Relocated to Transposable Element-Rich Pericentromeres

Author

Lijuan Qiu, Moaine El Baidouri, Kyung Do Kim, Scott A. Jackson, Yinghui Li, and Brian Abernathy

Subjects

0301 basic medicine, Genetics, Transposable element, animal structures, fungi, food and beverages, Plant Science, Methylation, DNA Methylation, Biology, Evolution, Molecular, Polyploidy, 03 medical and health sciences, 030104 developmental biology, Polyploid, Gene Expression Regulation, Plant, DNA methylation, DNA Transposable Elements, Genetic redundancy, Soybeans, Domestication, Molecular Biology, Gene, Genome, Plant, Functional divergence

Abstract

Most plants are polyploid due to whole-genome duplications (WGD) and can thus have duplicated genes. Following a WGD, paralogs are often fractionated (lost) and few duplicate pairs remain. Little attention has been paid to the role of DNA methylation in the functional divergence of paralogous genes. Using high-resolution methylation maps of accessions of domesticated and wild soybean, we show that in soybean, a recent paleopolyploid with many paralogs, DNA methylation likely contributed to the elimination of genetic redundancy of polyploidy-derived gene paralogs. Transcriptionally silenced paralogs exhibit particular genomic features as they are often associated with proximal transposable elements (TEs) and are preferentially located in pericentromeres, likely due to gene movement during evolution. Additionally, we provide evidence that gene methylation associated with proximal TEs is implicated in the divergence of expression profiles between orthologous genes of wild and domesticated soybean, and within populations.

Published

2018

8. A Comparative Epigenomic Analysis of Polyploidy-Derived Genes in Soybean and Common Bean

Author

Brian Abernathy, Michael D. Gonzales, Scott A. Jackson, Kyung Do Kim, Marc Libault, Carolina Chavarro, Jane Grimwood, Moaine El Baidouri, and Aiko Iwata-Otsubo

Subjects

Epigenomics, Physiology, Research Articles - Focus Issue, Bisulfite sequencing, Plant Science, Biology, Genes, Plant, Synteny, Genome, Chromosomes, Plant, Epigenesis, Genetic, Polyploidy, Species Specificity, Gene duplication, Genetics, Epigenetics, Gene, Phylogeny, Plant Proteins, Phaseolus, Chromosome Mapping, food and beverages, DNA Methylation, Gene Ontology, Paleopolyploidy, DNA methylation, DNA Transposable Elements, Soybeans, Genome, Plant

Abstract

Soybean (Glycine max) and common bean (Phaseolus vulgaris) share a paleopolyploidy (whole-genome duplication [WGD]) event, approximately 56.5 million years ago, followed by a genus Glycine-specific polyploidy, approximately 10 million years ago. Cytosine methylation is an epigenetic mark that plays an important role in the regulation of genes and transposable elements (TEs); however, the role of DNA methylation in the fate/evolution of genes following polyploidy and speciation has not been fully explored. Whole-genome bisulfite sequencing was used to produce nucleotide resolution methylomes for soybean and common bean. We found that, in soybean, CG body-methylated genes were abundant in WGD genes, which were, on average, more highly expressed than single-copy genes and had slower evolutionary rates than unmethylated genes, suggesting that WGD genes evolve more slowly than single-copy genes. CG body-methylated genes were also enriched in shared single-copy genes (single copy in both species) that may be responsible for the broad and high expression patterns of this class of genes. In addition, diverged methylation patterns in non-CG contexts between paralogs were due mostly to TEs in or near genes, suggesting a role for TEs and non-CG methylation in regulating gene expression post polyploidy. Reference methylomes for both soybean and common bean were constructed, providing resources for investigating epigenetic variation in legume crops. Also, the analysis of methylation patterns of duplicated and single-copy genes has provided insights into the functional consequences of polyploidy and epigenetic regulation in plant genomes.

Published

2015

9. Segmental allopolyploidy in action: Increasing diversity through polyploid hybridization and homoeologous recombination

Author

Brian Abernathy, João Francisco dos Santos, Márcio C. Moretzsohn, Soraya C. M. Leal-Bertioli, David J. Bertioli, Jeff J. Doyle, Scott A. Jackson, Ignácio José de Godoy, Patricia M. Guimarães, SORAYA CRISTINA DE M LEAL BERTIOLI, Cenargen, IGNÁCIO J. GODOY, CAMPINAS AGRONOMICAL INSTITUTE, JOÃO F. SANTOS, JOÃO F. SANTOS, JEFF J. DOYLE, CORNELL UNIVERSITY, USA, PATRICIA MESSEMBERG GUIMARAES, Cenargen, BRIAN L. ABERNATHY, UNIVERSITY OF GEORGIA, USA, SCOTT A. JACKSON, UNIVERSITY OF GEORGIA, USA, MARCIO DE CARVALHO MORETZSOHN, Cenargen, and DAVID J. BERTIOLI, UNIVERSITY OF GEORGIA, USA.

Subjects

0106 biological sciences, 0301 basic medicine, Pre-breeding, Lineage (genetic), Arachis, Introgression, Plant Science, Biology, 01 natural sciences, Genome, Polyploidy, 03 medical and health sciences, Polyploid, Lineage recombination, Genetics, Gene conversion, Allele, Homologous Recombination, Ecology, Evolution, Behavior and Systematics, Alleles, Genetic diversity, Tetr, Peanuts, food and beverages, Genetic Variation, Fabaceae, 030104 developmental biology, Population bottleneck, Segmental allotetraploid, Hybridization, Genetic, 010606 plant biology & botany

Abstract

PREMISE OF THE STUDY The genetic bottleneck of polyploid formation can be mitigated by multiple origins, gene flow, and recombination among different lineages. In crop plants with limited origins, efforts to increase genetic diversity have limitations. Here we used lineage recombination to increase genetic diversity in peanut, an allotetraploid likely of single origin, by crossing with a novel allopolyploid genotype and selecting improved lines. METHODS Single backcross progeny from cultivated peanut × wild species-derived allotetraploid cross were studied over successive generations. Using genetic assumptions that encompass segmental allotetraploidy, we used single nucleotide polymorphisms and whole-genome sequence data to infer genome structures. KEY RESULTS Selected lines, despite a high proportion of wild alleles, are agronomically adapted, productive, and with improved disease resistances. Wild alleles mostly substituted homologous segments of the peanut genome. Regions of dispersed wild alleles, characteristic of gene conversion, also occurred. However, wild chromosome segments sometimes replaced cultivated peanut's homeologous subgenome; A. ipaensis B sometimes replaced A. hypogaea A subgenome (~0.6%), and A. duranensis replaced A. hypogaea B subgenome segments (~2%). Furthermore, some subgenome regions historically lost in cultivated peanut were "recovered" by wild chromosome segments (effectively reversing the "polyploid ratchet"). These processes resulted in lines with new genome structure variations. CONCLUSIONS Genetic diversity was introduced by wild allele introgression, and by introducing new genome structure variations. These results highlight the special possibilities of segmental allotetraploidy and of using lineage recombination to increase genetic diversity in peanut, likely mirroring what occurs in natural segmental allopolyploids with multiple origins.

Published

2018

10. Tetrasomic Recombination Is Surprisingly Frequent in Allotetraploid Arachis

Author

Brian Abernathy, David J. Bertioli, Kenta Shirasawa, Scott A. Jackson, Peggy Ozias-Akins, Carolina Chavarro, Soraya C. M. Leal-Bertioli, Márcio C. Moretzsohn, and Josh Clevenger

Subjects

Arachis, Genetic Linkage, Quantitative Trait Loci, Plant genetics, groundnut, tetrasomic genetics, Investigations, Quantitative trait locus, Genome, Chromosomes, Plant, segmental genetics, Genome Integrity and Transmission, Inbred strain, Genetic linkage, Genetic model, Genetics, Recombination, Genetic, Models, Genetic, biology, food and beverages, biology.organism_classification, Tetrasomy, peanut, induced allotetraploid, Recombination

Abstract

Arachis hypogaea L. (cultivated peanut) is an allotetraploid (2n = 4x = 40) with an AABB genome type. Based on cytogenetic studies it has been assumed that peanut and wild-derived induced AABB allotetraploids have classic allotetraploid genetic behavior with diploid-like disomic recombination only between homologous chromosomes, at the exclusion of recombination between homeologous chromosomes. Using this assumption, numerous linkage map and quantitative trait loci studies have been carried out. Here, with a systematic analysis of genotyping and gene expression data, we show that this assumption is not entirely valid. In fact, autotetraploid-like tetrasomic recombination is surprisingly frequent in recombinant inbred lines generated from a cross of cultivated peanut and an induced allotetraploid derived from peanut’s most probable ancestral species. We suggest that a better, more predictive genetic model for peanut is that of a “segmental allotetraploid” with partly disomic, partly tetrasomic genetic behavior. This intermediate genetic behavior has probably had a previously overseen, but significant, impact on the genome and genetics of cultivated peanut.

Published

2015

11. Horizontal Transfer of Non-LTR Retrotransposons from Arthropods to Flowering Plants

Author

Brian Abernathy, Karolina Heyduk, Scott A. Jackson, Han Xia, Chunming Xu, Ye Chu, Dongying Gao, Peggy Ozias-Akins, and Jim Leebens-Mack

Subjects

0106 biological sciences, 0301 basic medicine, Transposable element, Genome evolution, non-LTR retrotransposon, Arachis, Gene Transfer, Horizontal, Retroelements, Retrotransposon, Biology, genome evolution, arthropods, 01 natural sciences, 03 medical and health sciences, Sequence Homology, Nucleic Acid, Genetics, Animals, Clade, horizontal transfer, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Phylogeny, Discoveries, flowering plants, Phylogenetic tree, Base Sequence, Phylum, fungi, food and beverages, Multicellular organism, 030104 developmental biology, Evolutionary biology, Horizontal gene transfer, Genome, Plant, 010606 plant biology & botany

Abstract

Even though lateral movements of transposons across families and even phyla within multicellular eukaryotic kingdoms have been found, little is known about transposon transfer between the kingdoms Animalia and Plantae. We discovered a novel non-LTR retrotransposon, AdLINE3, in a wild peanut species. Sequence comparisons and phylogenetic analyses indicated that AdLINE3 is a member of the RTE clade, originally identified in a nematode and rarely reported in plants. We identified RTE elements in 82 plants, spanning angiosperms to algae, including recently active elements in some flowering plants. RTE elements in flowering plants were likely derived from a single family we refer to as An-RTE. Interestingly, An-RTEs show significant DNA sequence identity with non-LTR retroelements from 42 animals belonging to four phyla. Moreover, the sequence identity of RTEs between two arthropods and two plants was higher than that of homologous genes. Phylogenetic and evolutionary analyses of RTEs from both animals and plants suggest that the An-RTE family was likely transferred horizontally into angiosperms from an ancient aphid(s) or ancestral arthropod(s). Notably, some An-RTEs were recruited as coding sequences of functional genes participating in metabolic or other biochemical processes in plants. This is the first potential example of horizontal transfer of transposons between animals and flowering plants. Our findings help to understand exchanges of genetic material between the kingdom Animalia and Plantae and suggest arthropods likely impacted on plant genome evolution.

Published

2017

12. Improved drought tolerance in wheat plants overexpressing a synthetic bacterial cold shock protein gene SeCspA

Author

Ming Chen, Brian Abernathy, Yong-Bin Zhou, Xiao Chen, Xing-Guo Ye, Yan-Xia Wang, Jin-Kao Guo, Zhao-Shi Xu, Jin-Dong Fu, Tai-Fei Yu, and You-Zhi Ma

Subjects

0106 biological sciences, 0301 basic medicine, Transgene, Acclimatization, Drought tolerance, Arabidopsis, Germination, 01 natural sciences, Article, 03 medical and health sciences, chemistry.chemical_compound, Stress, Physiological, Proline, Triticum, Plant Proteins, Multidisciplinary, biology, Escherichia coli Proteins, fungi, Temperature, food and beverages, biology.organism_classification, Malondialdehyde, Plants, Genetically Modified, Genetically modified organism, Droughts, Horticulture, 030104 developmental biology, Phenotype, chemistry, Agronomy, Cold Shock Proteins and Peptides, 010606 plant biology & botany

Abstract

Cold shock proteins (CSPs) enhance acclimatization of bacteria to adverse environmental circumstances. The Escherichia coli CSP genes CspA and CspB were modified to plant-preferred codon sequences and named as SeCspA and SeCspB. Overexpression of exogenous SeCspA and SeCspB in transgenic Arabidopsis lines increased germination rates, survival rates, and increased primary root length compared to control plants under drought and salt stress. Investigation of several stress-related parameters in SeCspA and SeCspB transgenic wheat lines indicated that these lines possessed stress tolerance characteristics, including lower malondialdehyde (MDA) content, lower water loss rates, lower relative Na+ content, and higher chlorophyll content and proline content than the control wheat plants under drought and salt stresses. RNA-seq and qRT-PCR expression analysis showed that overexpression of SeCsp could enhance the expression of stress-responsive genes. The field experiments showed that the SeCspA transgenic wheat lines had great increases in the 1000-grain weight and grain yield compared to the control genotype under drought stress conditions. Significant differences in the stress indices revealed that the SeCspA transgenic wheat lines possessed significant and stable improvements in drought tolerance over the control plants. No such improvement was observed for the SeCspB transgenic lines under field conditions. Our results indicated that SeCspA conferred drought tolerance and improved physiological traits in wheat plants.

Published

2017

13. Genome-wide SNP Genotyping Resolves Signatures of Selection and Tetrasomic Recombination in Peanut

Author

Josh, Clevenger, Ye, Chu, Carolina, Chavarro, Gaurav, Agarwal, David J, Bertioli, Soraya C M, Leal-Bertioli, Manish K, Pandey, Justin, Vaughn, Brian, Abernathy, Noelle A, Barkley, Ran, Hovav, Mark, Burow, Spurthi N, Nayak, Annapurna, Chitikineni, Thomas G, Isleib, C Corley, Holbrook, Scott A, Jackson, Rajeev K, Varshney, and Peggy, Ozias-Akins

Subjects

Genetic Markers, Recombination, Genetic, Arachis, Genotype, Genotyping Techniques, groundnut, food and beverages, Genetic Variation, Polymorphism, Single Nucleotide, Haplotypes, single nucleotide polymorphism, Arachis hypogaea, Tetrasomy, Selection, Genetic, Research Article

Abstract

Peanut (Arachis hypogaea; 2n = 4x = 40) is a nutritious food and a good source of vitamins, minerals, and healthy fats. Expansion of genetic and genomic resources for genetic enhancement of cultivated peanut has gained momentum from the sequenced genomes of the diploid ancestors of cultivated peanut. To facilitate high-throughput genotyping of Arachis species, 20 genotypes were re-sequenced and genome-wide single nucleotide polymorphisms (SNPs) were selected to develop a large-scale SNP genotyping array. For flexibility in genotyping applications, SNPs polymorphic between tetraploid and diploid species were included for use in cultivated and interspecific populations. A set of 384 accessions was used to test the array resulting in 54 564 markers that produced high-quality polymorphic clusters between diploid species, 47 116 polymorphic markers between cultivated and interspecific hybrids, and 15 897 polymorphic markers within A. hypogaea germplasm. An additional 1193 markers were identified that illuminated genomic regions exhibiting tetrasomic recombination. Furthermore, a set of elite cultivars that make up the pedigree of US runner germplasm were genotyped and used to identify genomic regions that have undergone positive selection. These observations provide key insights on the inclusion of new genetic diversity in cultivated peanut and will inform the development of high-resolution mapping populations. Due to its efficiency, scope, and flexibility, the newly developed SNP array will be very useful for further genetic and breeding applications in Arachis., Genome-wide single nucleotide polymorphisms (SNPs), identified among diploid and tetraploid Arachis species and used to construct an Affymetrix 60K SNP array, provided insight into diversity across US runner-type peanut cultivars and the US mini - core collection. The frequency of fixed marker polymorphisms and identification of preferentially selected haplotypes will inform future peanut breeding to enhance diversity.

Published

2016

14. Dynamic Oryza Genomes: Repetitive DNA Sequences as Genome Modeling Agents

Author

Rod A. Wing, Phillip SanMiguel, Brian Abernathy, Hyeran Kim, Braham Dhillon, Doreen Ware, Lincoln Stein, Scott A. Jackson, and Navdeep Gill

Subjects

0106 biological sciences, Comparative genomics, Genetics, 0303 health sciences, Genome evolution, food and beverages, Soil Science, Retrotransposon, Plant Science, Genome project, Biology, 01 natural sciences, Genome, 03 medical and health sciences, Evolutionary biology, Cot analysis, Agronomy and Crop Science, Genome size, 030304 developmental biology, 010606 plant biology & botany, Reference genome

Abstract

Repetitive sequences, primarily transposable elements form an indispensable part of eukaryotic genomes. However, little is known about how these sequences originate, evolve and function in context of a genome. In an attempt to address this question, we performed a comparative analysis of repetitive DNA sequences in the genus Oryza, representing ~15 million years of evolution. Both Class I and Class II transposable elements, through their expansion, loss and movement in the genome, were found to influence genome size variation in this genus. We identified 38 LTRretrotransposon families that are present in 1,500 or more copies throughout Oryza, and many are preferentially amplified in specific lineages. The data presented here, besides furthering our understanding of genome organization in the genus Oryza, will aid in the assembly, annotation and analysis of genomic data, as part of the future genome sequencing projects of O. sativa wild relatives.

Published

2010

15. The genome sequences of Arachis duranensis and Arachis ipaensis, the diploid ancestors of cultivated peanut

Author

Lutz Froenicke, David J. Bertioli, Andrew Farmer, Ethalinda K. S. Cannon, Sudhansu Dash, Josh Clevenger, Brian E. Scheffler, Baozhu Guo, Xu Xun, Mark D. Burow, Noelle A. Barkley, Brian Abernathy, Steven B. Cannon, Xinyou Zhang, Boshou Liao, Kenta Shirasawa, Peggy Ozias-Akins, Bruna Vidigal, Chad E. Niederhuth, Pooja E. Umale, Dongying Gao, Xin Liu, Alexander Kozik, H. Thomas Stalker, Rajeev K. Varshney, Scott A. Jackson, Kyung Do Kim, Soraya C. M. Leal-Bertioli, Ye Chu, Richard W Michelmore, Longhui Ren, Ana Claudia Guerra Araujo, Robert J. Schmitz, Xingjun Wang, Márcio C. Moretzsohn, Wei Huang, Guodong Huang, Sachiko Isobe, and Patricia M. Guimarães

Subjects

0106 biological sciences, 0301 basic medicine, Arachis, Genetic Linkage, Population, Genomics, 01 natural sciences, Genome, Synteny, Chromosomes, Plant, Arachis duranensis, Evolution, Molecular, 03 medical and health sciences, Arachis ipaensis, Botany, Genetics, education, education.field_of_study, Ploidies, biology, food and beverages, Molecular Sequence Annotation, Sequence Analysis, DNA, DNA Methylation, biology.organism_classification, Arachis hypogaea, 030104 developmental biology, DNA Transposable Elements, Ploidy, Genome, Plant, 010606 plant biology & botany

Abstract

Cultivated peanut (Arachis hypogaea) is an allotetraploid with closely related subgenomes of a total size of ∼2.7 Gb. This makes the assembly of chromosomal pseudomolecules very challenging. As a foundation to understanding the genome of cultivated peanut, we report the genome sequences of its diploid ancestors (Arachis duranensis and Arachis ipaensis). We show that these genomes are similar to cultivated peanut's A and B subgenomes and use them to identify candidate disease resistance genes, to guide tetraploid transcript assemblies and to detect genetic exchange between cultivated peanut's subgenomes. On the basis of remarkably high DNA identity of the A. ipaensis genome and the B subgenome of cultivated peanut and biogeographic evidence, we conclude that A. ipaensis may be a direct descendant of the same population that contributed the B subgenome to cultivated peanut.

Published

2015

16. A new approach for annotation of transposable elements using small RNA mapping

Author

Brian Abernathy, Olivier Panaud, Blake C. Meyers, Kyung Do Kim, Moaine El Baidouri, Siwaret Arikit, Scott A. Jackson, Florian Maumus, Laboratoire Génome et développement des plantes (LGDP), Université de Perpignan Via Domitia (UPVD)-Centre National de la Recherche Scientifique (CNRS), University of Georgia [USA], Univ Delaware, Delaware Biotechnol Inst, Newark, DE 19711 USA, Université Paris Diderot - Paris 7 (UPD7), Unité de Recherche Génomique Info (URGI), Institut National de la Recherche Agronomique (INRA), and Plant Genome Mapping Laboratory (PGML)

Subjects

0106 biological sciences, Small RNA, [SDV]Life Sciences [q-bio], Arabidopsis, [SDV.BID.SPT]Life Sciences [q-bio]/Biodiversity/Systematics, Phylogenetics and taxonomy, 01 natural sciences, Genome, new method for de novo TE Annotation, RNA, Small Interfering, transposable element, DNA, TASR, Genetics, 0303 health sciences, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], [SDV.BID.EVO]Life Sciences [q-bio]/Biodiversity/Populations and Evolution [q-bio.PE], Chromosome Mapping, food and beverages, [SDV.BBM.MN]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular Networks [q-bio.MN], [SDV.BIBS]Life Sciences [q-bio]/Quantitative Methods [q-bio.QM], [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biomolecules [q-bio.BM], [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biomolecules [q-bio.BM], Molecular Sequence Annotation, Methods Online, Genome, Plant, Transposable element, Computational biology, [SDV.BC]Life Sciences [q-bio]/Cellular Biology, Biology, DNA sequencing, [SDV.GEN.GPL]Life Sciences [q-bio]/Genetics/Plants genetics, 03 medical and health sciences, Annotation, [SDV.BBM.GTP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Genomics [q-bio.GN], [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biochemistry [q-bio.BM], 030304 developmental biology, [SDV.GEN]Life Sciences [q-bio]/Genetics, Oryza, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Interspersed Repetitive Sequences, Gene Annotation, [SDV.BV.AP]Life Sciences [q-bio]/Vegetal Biology/Plant breeding, Soybeans, 010606 plant biology & botany

Abstract

International audience; Transposable elements (TEs) are mobile genomic DNA sequences found in most organisms. They so densely populate the genomes of many eukaryotic species that they are often the major constituents. With the rapid generation of many plant genome sequencing projects over the past few decades, there is an urgent need for improved TE annotation as a prerequisite for genome-wide studies. Analogous to the use of RNA-seq for gene annotation, we propose a new method for de novo TE annotation that uses as a guide 24 nt-siRNAs that are a part of TE silencing pathways. We use this new approach, called TASR (for Transposon Annotation using Small RNAs), for de novo annotation of TEs in Arabidopsis, rice and soybean and demonstrate that this strategy can be successfully applied for de novo TE annotation in plants.Executable PERL is available for download from: http://tasr-pipeline.sourceforge.net/.

Published

2015

17. Distribution and analysis of SSR in mung bean (Vigna radiata L.) genome based on an SSR-enriched library

Author

Suhua Wang, Suk-Ha Lee, Brian Abernathy, Scott A. Jackson, Honglin Chen, Moaine Elbaidouri, Xu Zhen Cheng, and Li Xia Wang

Subjects

Genetics, education.field_of_study, biology, Population, food and beverages, Plant Science, Quantitative trait locus, biology.organism_classification, Genome, Vigna, Genetic marker, Genotype, Microsatellite, education, Agronomy and Crop Science, Molecular Biology, Gene, Biotechnology

Abstract

Simple sequence repeats (SSR) are widely distributed in plant genomes, have been popular genetic markers and can be involved in gene function. We report an SSR analysis of mung bean (Vigna radiata L.), based on an SSR-enriched library. A total of 308,509 SSRs (56.9 % simple and 43.1 % compound) were discovered from 167,628 sequences. Both di- and tri-nucleotide were the most prevalent repeat types (each accounts for 48.6 %). The most frequent motifs were AAC/GTT, accounting for 45.14 % of all, followed by AC/GT at 41.80 %. After filtering the SSRs, 70,104 flanking sequences were used as BLAST queries and corresponded to 574 non-redundant gene ontology terms against the protein database from Arabidopsis thaliana. The three main categories were biological processes (23.8 %), cellular components (44.4 %) and molecular functions (31.8 %). A total of 6,100 non-repeated primer pairs were designed and validated by PCR analysis. The results showed that 60 % of primers were effective in mung bean and 35.2, 34.0 and 25.9 % could be transferred to rice bean, adzuki bean and cowpea, respectively. 9.1 % of the 6,100 displayed polymorphism between a wild and cultivated mung bean genotype, and 367 were mapped onto chromosomes using a RIL population derived from a wild × a cultivated cross. However, only 49 of 1,700 effective primer pairs showed polymorphism among 32 Chinese cultivated mung bean accessions. A total of 46,565 loci on mung bean chromosomes from the draft genome were hit by the 70,104 flanking sequences using BLASTn. The present study, especially the newly published 387 markers that have been validated and mapped, will significantly enhance genetic linkage map construction, QTL mapping and marker-assisted selection in mung bean and breeding in closely related crop species.

Published

2015

18. Landscape and evolutionary dynamics of terminal-repeat retrotransposons in miniature (TRIMs) in 48 whole plant genomes

Author

Yupeng Li, Dongying Gao, Scott A. Jackson, and Brian Abernathy

Subjects

0106 biological sciences, Genetics, 0303 health sciences, animal structures, viruses, fungi, food and beverages, Retrotransposon, Biology, Plant genomes, 01 natural sciences, Genome, Long terminal repeat, Transposition (music), 03 medical and health sciences, Evolutionary biology, Evolutionary dynamics, Gene evolution, Gene, 030304 developmental biology, 010606 plant biology & botany

Abstract

Terminal-repeat retrotransposons in miniature (TRIMs) are structurally similar to long terminal repeat (LTR) retrotransposons except that they are extremely small and difficult to identify. Thus far, only a few TRIMs have been characterized in the euphyllophytes and the evolutionary and biological impacts and transposition mechanism of TRIMs are poorly understood. In this study, we combined de novo and homology-based methods to annotate TRIMs in 48 plant genome sequences, spanning land plants to algae. We found 156 TRIM families, 146 previously undescribed. Notably, we identified the first TRIMs in a lycophyte and non-vascular plants. The majority of the TRIM families were highly conserved and shared within and between plant families. Even though TRIMs contribute only a small fraction of any plant genome, they are enriched in or near genes and may play important roles in gene evolution. TRIMs were frequently organized into tandem arrays we called TA-TRIMs, another unique feature distinguishing them from LTR retrotransposons. Importantly, we identified putative autonomous retrotransposons that may mobilize specific TRIM elements and detected very recent transpositions of a TRIM in O. sativa. Overall, this comprehensive analysis of TRIMs across the entire plant kingdom provides insight into the evolution and conservation of TRIMs and the functional roles they may play in gene evolution.

Published

2014

19. TILLING by sequencing to identify induced mutations in stress resistance genes of peanut (Arachis hypogaea)

Author

Yajuan Zeng, Peggy Ozias-Akins, Brian Abernathy, and Yufang Guo

Subjects

TILLING, Silent mutation, Arachis, Genotype, Sequence analysis, Population, Lipoxygenase, Mutation, Missense, Biology, Plant Roots, Polymorphism, Single Nucleotide, Stress, Physiological, Genetics, Phospholipase D, Missense mutation, Mutation frequency, education, Gene, Gene Library, Plant Proteins, education.field_of_study, food and beverages, High-Throughput Nucleotide Sequencing, Genomics, Sequence Analysis, DNA, Reverse genetics, Genome, Plant, Biotechnology, Research Article

Abstract

Background Targeting Induced Local Lesions in Genomes (TILLING) is a powerful reverse genetics approach for functional genomics studies. We used high-throughput sequencing, combined with a two-dimensional pooling strategy, with either minimum read percentage with non-reference nucleotide or minimum variance multiplier as mutation prediction parameters, to detect genes related to abiotic and biotic stress resistances. In peanut, lipoxygenase genes were reported to be highly induced in mature seeds infected with Aspergillus spp., indicating their importance in plant-fungus interactions. Recent studies showed that phospholipase D (PLD) expression was elevated more quickly in drought sensitive lines than in drought tolerant lines of peanut. A newly discovered lipoxygenase (LOX) gene in peanut, along with two peanut PLD genes from previous publications were selected for TILLING. Additionally, two major allergen genes Ara h 1 and Ara h 2, and fatty acid desaturase AhFAD2, a gene which controls the ratio of oleic to linoleic acid in the seed, were also used in our study. The objectives of this research were to develop a suitable TILLING by sequencing method for this allotetraploid, and use this method to identify mutations induced in stress related genes. Results We screened a peanut root cDNA library and identified three candidate LOX genes. The gene AhLOX7 was selected for TILLING due to its high expression in seeds and roots. By screening 768 M2 lines from the TILLING population, four missense mutations were identified for AhLOX7, three missense mutations were identified for AhPLD, one missense and two silent mutations were identified for Ara h 1.01, three silent and five missense mutations were identified for Ara h 1.02, one missense mutation was identified for AhFAD2B, and one silent mutation was identified for Ara h 2.02. The overall mutation frequency was 1 SNP/1,066 kb. The SNP detection frequency for single copy genes was 1 SNP/344 kb and 1 SNP/3,028 kb for multiple copy genes. Conclusions Our TILLING by sequencing approach is efficient to identify mutations in single and multi-copy genes. The mutations identified in our study can be used to further study gene function and have potential usefulness in breeding programs. Electronic supplementary material The online version of this article (doi:10.1186/s12864-015-1348-0) contains supplementary material, which is available to authorized users.

Published

2014

20. Annotation and sequence diversity of transposable elements in common bean (Phaseolus vulgaris)

Author

Daniel Rohksar, Dongying Gao, Brian Abernathy, Jeremy Schmutz, and Scott A. Jackson

Subjects

0106 biological sciences, Transposable element, Genome evolution, transposon, Retrotransposon, Plant Science, lcsh:Plant culture, Biology, ENCODE, 01 natural sciences, Genome, 03 medical and health sciences, evolution, lcsh:SB1-1110, Original Research Article, 030304 developmental biology, Genomic organization, 2. Zero hunger, Whole genome sequencing, Genetics, common bean, 0303 health sciences, Expressed sequence tag, food and beverages, ORF2, transposon database, 010606 plant biology & botany

Abstract

Common bean (Phaseolus vulgaris) is an important legume crop grown and consumed worldwide. With the availability of the common bean genome sequence, the next challenge is to annotate the genome and characterize functional DNA elements. Transposable elements (TEs) are the most abundant component of plant genomes and can dramatically affect genome evolution and genetic variation. Thus, it is pivotal to identify TEs in the common bean genome. In this study, we performed a genome-wide transposon annotation in common bean using a combination of homology and sequence structure-based methods. We developed a 2.12-Mb transposon database which includes 791 representative transposon sequences and is available upon request or from www.phytozome.org. Of note, nearly all transposons in the database are previously unrecognized TEs. More than 5,000 transposon-related expressed sequence tags (ESTs) were detected which indicates that some transposons may be transcriptionally active. Two Ty1-copia retrotransposon families were found to encode the envelope-like protein which has rarely been identified in plant genomes. Also, we identified an extra open reading frame (ORF) termed ORF2 from 15 Ty3-gypsy families that was located between the ORF encoding the retrotransposase and the 3’LTR. The ORF2 was in opposite transcriptional orientation to retrotransposase. Sequence homology searches and phylogenetic analysis suggested that the ORF2 may have an ancient origin, but its function is not clear. This transposon data provides a useful resource for understanding the genome organization and evolution and may be used to identify active TEs for developing transposon-tagging system in common bean and other related genomes.

Published

2014

21. A reference genome for common bean and genome-wide analysis of dual domestications

Author

Jane Grimwood, Kerrie Barry, Gaofeng Jia, Paul Gepts, Brian Abernathy, Mirayda Torres-Torres, Mansi Chovatia, Ming Zhang, Manon M.S. Richard, Mark A. Brick, Phillip E. McClean, Samira Mafi Moghaddam, Mei Wang, Valérie Geffroy, Steven B. Cannon, Carolina Chavarro, David L. Hyten, Dongying Gao, Qijian Song, Daniel S. Rokhsar, G Albert Wu, Shengqiang Shu, Scott A. Jackson, Jerry Jenkins, Dave Kudrna, Matthew W. Blair, Phillip N. Miklas, Vincent Thareau, Rod A. Wing, Michael D. Gonzales, Carlos A. Urrea, Sujan Mamidi, Yeisoo Yu, Juan M. Osorno, Uffe Hellsten, James D. Kelly, Rian Lee, Jeremy Schmutz, David Goodstein, Josiane Rodrigues, Perry B. Cregan, Joint Genome institute, United States Department of Energy, Hudson Alpha Institute for Biotechnology, Department of Plant Sciences, North Dakota State University (NDSU), USDA-ARS : Agricultural Research Service, United States Department of Agriculture (USDA), Center for Applied Genetic Technologies, University of Georgia [USA], Génétique Quantitative et Evolution - Le Moulon (Génétique Végétale) (GQE-Le Moulon), Centre National de la Recherche Scientifique (CNRS)-AgroParisTech-Université Paris-Sud - Paris 11 (UP11)-Institut National de la Recherche Agronomique (INRA), Institut de Biologie des Plantes (IBP), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Tennessee State University, Department of Soil and Crop Sciences [Fort Collins], Colorado State University [Fort Collins] (CSU), University of California [Davis] (UC Davis), University of California-University of California, Michigan State University [East Lansing], Michigan State University System, University of Arizona, University of Nebraska, Partenaires INRAE, Office of Science of the US Department of Energy - US Department of Agriculture National Institute for Food and Agriculture [DE-AC02-05CH11231, 2006-35300-17266], National Science Foundation [DBI 0822258], US Department of Agriculture Cooperative State Research, Education and Extension Service [2009-01860, 2009-01929], Schmutz, Jeremy, and McClean, Phillip E.

Subjects

0106 biological sciences, [SDV]Life Sciences [q-bio], Medical and Health Sciences, 01 natural sciences, Genome, 2. Zero hunger, Genetics, Phaseolus, 0303 health sciences, Chromosome Mapping, food and beverages, Single Nucleotide, Biological Sciences, Reference Standards, Seeds, Gene pool, Sequence Analysis, Genome, Plant, Crops, Agricultural, Plant genetics, Sequence analysis, Molecular Sequence Data, Quantitative Trait Loci, Crops, Quantitative trait locus, Biology, Genes, Plant, Polymorphism, Single Nucleotide, Article, Chromosomes, Chromosomes, Plant, 03 medical and health sciences, domestication, Humans, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Polymorphism, soja, Domestication, Gene, 030304 developmental biology, Agricultural, Ploidies, génome, Human Genome, Central America, phaseolus vulgaris, Plant, DNA, Sequence Analysis, DNA, haricot commun, South America, biology.organism_classification, Plant Leaves, Genes, Developmental Biology, 010606 plant biology & botany, Reference genome

Abstract

Scott Jackson, Jeremy Schmutz, Phillip McClean and colleagues report the genome sequence of the common bean (Phaseolus vulgaris) and resequenced wild individuals and landraces from Mesoamerican and Andean gene pools, showing that common bean underwent two independent domestications. Supplementary information The online version of this article (doi:10.1038/ng.3008) contains supplementary material, which is available to authorized users., Common bean (Phaseolus vulgaris L.) is the most important grain legume for human consumption and has a role in sustainable agriculture owing to its ability to fix atmospheric nitrogen. We assembled 473 Mb of the 587-Mb genome and genetically anchored 98% of this sequence in 11 chromosome-scale pseudomolecules. We compared the genome for the common bean against the soybean genome to find changes in soybean resulting from polyploidy. Using resequencing of 60 wild individuals and 100 landraces from the genetically differentiated Mesoamerican and Andean gene pools, we confirmed 2 independent domestications from genetic pools that diverged before human colonization. Less than 10% of the 74 Mb of sequence putatively involved in domestication was shared by the two domestication events. We identified a set of genes linked with increased leaf and seed size and combined these results with quantitative trait locus data from Mesoamerican cultivars. Genes affected by domestication may be useful for genomics-enabled crop improvement. Supplementary information The online version of this article (doi:10.1038/ng.3008) contains supplementary material, which is available to authorized users.

Published

2014

22. Identification and characterization of functional centromeres of the common bean

Author

Brian Abernathy, Scott A. Jackson, Andrea Pedrosa-Harand, Ahmet L. Tek, Yupeng Li, Vincent Thareau, Kiyotaka Nagaki, Aiko Iwata, Manon M.S. Richard, Minoru Murata, Ghislaine Magdelenat, Jeremy Schmutz, Valérie Geffroy, Artur Fonsêca, Nicolas W.G. Chen, University of Georgia [USA], Okayama University, Harran Univ, Partenaires INRAE, IBP, Université Paris-Sud - Paris 11 (UP11), Universidade Federal de Pernambuco, Hudson Alpha Institute for Biotechnology, Joint Genome Institute (JGI), Genoscope - Centre national de séquençage [Evry] (GENOSCOPE), Université Paris-Saclay-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Génétique Quantitative et Evolution - Le Moulon (Génétique Végétale) (GQE-Le Moulon), Centre National de la Recherche Scientifique (CNRS)-AgroParisTech-Université Paris-Sud - Paris 11 (UP11)-Institut National de la Recherche Agronomique (INRA), USDA-NIFA [2009-01860], Japan Society for the Promotion of Science (JSPS), INRA, IFR87, Turkish Higher Education Council, Harran University, Turkey, Fundacao de Amparo a Ciencia e Tecnologia do Estado de Pernambuco (FACEPE), Brazil, Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq), Brazil, and Institut National de la Recherche Agronomique (INRA)-Université Paris-Sud - Paris 11 (UP11)-AgroParisTech-Centre National de la Recherche Scientifique (CNRS)

Subjects

0106 biological sciences, TANDEM REPEATS, SATELLITE REPEAT, [SDV]Life Sciences [q-bio], Plant Science, 01 natural sciences, Genome, Histones, MULTIPLE SEQUENCE ALIGNMENT, REPETITIVE SEQUENCES, In Situ Hybridization, Fluorescence, Plant Proteins, Genetics, 0303 health sciences, biology, medicine.diagnostic_test, Fabaceae, EVOLUTIONARY DYNAMICS, satellite repeats, chromosome-specific homogenization, Phaseolus, higher-order repeat structure, DNA, Complementary, DNA, Plant, Satellite DNA, Centromere, Molecular Sequence Data, centromere evolution, Immunofluorescence, Phaseolus vulgaris, MOLECULAR DRIVE, Evolution, Molecular, 03 medical and health sciences, Histone H3, Species Specificity, medicine, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, RICE, centromere-specific histone H3, HISTONE H3, 030304 developmental biology, Base Sequence, Cell Biology, biology.organism_classification, DNA-SEQUENCES, ARABIDOPSIS-THALIANA, Chromatin immunoprecipitation, 010606 plant biology & botany, Fluorescence in situ hybridization, Microsatellite Repeats

Abstract

International audience; In higher eukaryotes, centromeres are typically composed of megabase-sized arrays of satellite repeats that evolve rapidly and homogenize within a species' genome. Despite the importance of centromeres, our knowledge is limited to a few model species. We conducted a comprehensive analysis of common bean (Phaseolus vulgaris) centromeric satellite DNA using genomic data, fluorescence in situ hybridization (FISH), immunofluorescence and chromatin immunoprecipitation (ChIP). Two unrelated centromere-specific satellite repeats, CentPv1 and CentPv2, and the common bean centromere-specific histone H3 (PvCENH3) were identified. FISH showed that CentPv1 and CentPv2 are predominantly located at subsets of eight and three centromeres, respectively. Immunofluorescence- and ChIP-based assays demonstrated the functional significance of CentPv1 and CentPv2 at centromeres. Genomic analysis revealed several interesting features of CentPv1 and CentPv2: (i) CentPv1 is organized into an higher-order repeat structure, named Nazca, of 528bp, whereas CentPv2 is composed of tandemly organized monomers; (ii) CentPv1 and CentPv2 have undergone chromosome-specific homogenization; and (iii) CentPv1 and CentPv2 are not likely to be commingled in the genome. These findings suggest that two distinct sets of centromere sequences have evolved independently within the common bean genome, and provide insight into centromere satellite evolution.

Published

2013

23. Integration of the Draft Sequence and Physical Map as a Framework for Genomic Research in Soybean (Glycine max (L.) Merr.) and Wild Soybean (Glycine soja Sieb. and Zucc.)

Author

Gary Stacey, Randy C. Shoemaker, Rod A. Wing, Brian Abernathy, Yeisoo Yu, Scott A. Jackson, David Grant, Xiaolei Wu, William Nelson, Jungmin Ha, and Henry T. Nguyen

Subjects

0106 biological sciences, Genome evolution, Investigations, genome evolution, FingerPrinted Contig, 01 natural sciences, Genome, genome structure, 03 medical and health sciences, Genetics, Molecular Biology, Genetics (clinical), 030304 developmental biology, Sequence (medicine), 2. Zero hunger, Whole genome sequencing, Comparative genomics, 0303 health sciences, Bacterial artificial chromosome, biology, Contig, food and beverages, biology.organism_classification, whole-genome sequencing, Glycine soja, 010606 plant biology & botany

Abstract

Soybean is a model for the legume research community because of its importance as a crop, densely populated genetic maps, and the availability of a genome sequence. Even though a whole-genome shotgun sequence and bacterial artificial chromosome (BAC) libraries are available, a high-resolution, chromosome-based physical map linked to the sequence assemblies is still needed for whole-genome alignments and to facilitate map-based gene cloning. Three independent G. max BAC libraries combined with genetic and gene-based markers were used to construct a minimum tiling path (MTP) of BAC clones. A total of 107,214 clones were assembled into 1355 FPC (FingerPrinted Contigs) contigs, incorporating 4628 markers and aligned to the G. max reference genome sequence using BAC end-sequence information. Four different MTPs were made for G. max that covered from 92.6% to 95.0% of the soybean draft genome sequence (gmax1.01). Because our purpose was to pick the most reliable and complete MTP, and not the MTP with the minimal number of clones, the FPC map and draft sequence were integrated and clones with unpaired BES were added to build a high-quality physical map with the fewest gaps possible (http://soybase.org). A physical map was also constructed for the undomesticated ancestor (G. soja) of soybean to explore genome variation between G. max and G. soja. 66,028 G. soja clones were assembled into 1053 FPC contigs covering approximately 547 Mbp of the G. max genome sequence. These physical maps for G. max and its undomesticated ancestor, G. soja, will serve as a framework for ordering sequence fragments, comparative genomics, cloning genes, and evolutionary analyses of legume genomes.

Published

2011

24. Genome sequence of the palaeopolyploid soybean

Author

Myron Peto, Jianlin Cheng, Dong Xu, Ananad Sethuraman, William Nelson, Xue-Cheng Zhang, Gregory D. May, David L. Hyten, Perry B. Cregan, Scott A. Jackson, Jane Grimwood, Erika Lindquist, Marc Libault, Zhixi Tian, Taishi Umezawa, Devinder Sandhu, Tetsuya Sakurai, Shengqiang Shu, Steven B. Cannon, Jianxin Ma, Henry T. Nguyen, Trupti Joshi, James E. Specht, Rod A. Wing, Jessica A. Schlueter, Madan K. Bhattacharyya, Daniel S. Rokhsar, Kazuo Shinozaki, Brian Abernathy, Liucun Zhu, Navdeep Gill, Babu Valliyodan, Montona Futrell-Griggs, Randy C. Shoemaker, Uffe Hellsten, David Goodstein, Jeremy Schmutz, Kerrie Barry, Jay J. Thelen, Jianchang Du, Gary Stacey, Yeisoo Yu, Qijian Song, Therese Mitros, and David Grant

Subjects

Genome evolution, Molecular Sequence Data, Quantitative Trait Loci, Arabidopsis, Genomics, Breeding, Genes, Plant, Genome, Plant Root Nodulation, Synteny, Chromosomes, Plant, Evolution, Molecular, Polyploidy, Genes, Duplicate, Gene density, Gene Duplication, palaeopolyploid soybean soil-borne microorganisms, Genome size, Phylogeny, Repetitive Sequences, Nucleic Acid, Genetics, Recombination, Genetic, Multidisciplinary, biology, fungi, food and beverages, Genome project, biology.organism_classification, Soybean Oil, Paleopolyploidy, Multigene Family, Soybeans, Glycine soja, Genome, Plant, Transcription Factors

Abstract

Soybean (Glycine max) is one of the most important crop plants for seed protein and oil content, and for its capacity to fix atmospheric nitrogen through symbioses with soil-borne microorganisms. We sequenced the 1.1-gigabase genome by a whole-genome shotgun approach and integrated it with physical and high-density genetic maps to create achromosome-scale draft sequence assembly. We predict 46,430 protein-coding genes, 70percent more than Arabidopsis and similar to the poplar genome which, like soybean, is an ancient polyploid (palaeopolyploid). About 78percent of the predicted genes occur in chromosome ends, which comprise less than one-half of the genome but account for nearly all of the genetic recombination. Genome duplications occurred at approximately 59 and 13 million years ago, resulting in a highly duplicated genome with nearly 75percent of the genes present in multiple copies. The two duplication events were followed by genediversification and loss, and numerous chromosome rearrangements. An accurate soybean genome sequence will facilitate the identification of the genetic basis of many soybean traits, and accelerate the creation of improved soybean varieties.

Published

2009

25. Erratum: Genome sequence of the palaeopolyploid soybean

Author

Shengqiang Shu, Taishi Umezawa, Scott A. Jackson, Steven B. Cannon, Trupti Joshi, Rod A. Wing, Qijian Song, David M. Grant, Uffe Hellsten, Daniel S. Rokhsar, William G. Nelson, Jeremy Schmutz, David L. Hyten, Anand Sethuraman, Babu Valliyodan, Dong Xu, James E. Specht, Yeisoo Yu, Perry B. Cregan, Erika Lindquist, Marc Libault, Montona Futrell-Griggs, David Goodstein, Devinder Sandhu, Gregory D. May, Navdeep Gill, Jessica A. Schlueter, Jane Grimwood, Madan K. Bhattacharyya, Kerrie Barry, Jay J. Thelen, Liucun Zhu, Myron Peto, Jianlin Cheng, Kazuo Shinozaki, Brian Abernathy, Henry T. Nguyen, Zhixi Tian, Tetsuya Sakurai, Randy C. Shoemaker, Jianchang Du, Xue-Cheng Zhang, Jianxin Ma, Therese Mitros, and Gary Stacey

Subjects

Genetics, Comparative genomics, Whole genome sequencing, Multidisciplinary, Chromosome 19, Mutation (genetic algorithm), food and beverages, Epistasis, Biology

Abstract

Nature 463, 178–183 (2010) During resubmission of this work, a paper was published1 that used a comparative genomics approach between soybean and maize to show that a single-base mutation in chromosome 19 accounts for the duplicate recessive epistasis needed to greatly reduce phytate production in soybean seed.

Published

2010

26. Integration of hybridization-based markers (overgos) into physical maps for comparative and evolutionary explorations in the genus Oryza and in Sorghum

Author

Fariborz Rakhshan, Montona Futrell-Griggs, Jetty S.S. Ammiraju, Brian Abernathy, Rick Westerman, Jason G. Walling, Barbara L. Hass-Jacobus, Jose Luis Goicoechea, Bonnie L. Hurwitz, Scott A. Jackson, Navdeep Gill, Dave Kudrna, Meizhong Luo, Rod A. Wing, Jer-Young Lin, Bin Zhou, Doreen Ware, Hyeran Kim, Patricia E. Klein, Joshua C. Stein, Phillip San Miguel, and Abhijit Sanyal

Subjects

Genetic Markers, Chromosomes, Artificial, Bacterial, lcsh:QH426-470, lcsh:Biotechnology, Genomics, Oryza, Genome, Chromosomes, Plant, Evolution, Molecular, Species Specificity, lcsh:TP248.13-248.65, Sequence Homology, Nucleic Acid, Genetics, Sorghum, Synteny, Gene Library, Bacterial artificial chromosome, Oryza sativa, biology, Contig, food and beverages, Chromosome Mapping, Nucleic Acid Hybridization, biology.organism_classification, DNA Fingerprinting, lcsh:Genetics, DNA Probes, Sequence Alignment, Genome, Plant, Biotechnology, Reference genome, Research Article

Abstract

Background With the completion of the genome sequence for rice (Oryza sativa L.), the focus of rice genomics research has shifted to the comparison of the rice genome with genomes of other species for gene cloning, breeding, and evolutionary studies. The genus Oryza includes 23 species that shared a common ancestor 8–10 million years ago making this an ideal model for investigations into the processes underlying domestication, as many of the Oryza species are still undergoing domestication. This study integrates high-throughput, hybridization-based markers with BAC end sequence and fingerprint data to construct physical maps of rice chromosome 1 orthologues in two wild Oryza species. Similar studies were undertaken in Sorghum bicolor, a species which diverged from cultivated rice 40–50 million years ago. Results Overgo markers, in conjunction with fingerprint and BAC end sequence data, were used to build sequence-ready BAC contigs for two wild Oryza species. The markers drove contig merges to construct physical maps syntenic to rice chromosome 1 in the wild species and provided evidence for at least one rearrangement on chromosome 1 of the O. sativa versus Oryza officinalis comparative map. When rice overgos were aligned to available S. bicolor sequence, 29% of the overgos aligned with three or fewer mismatches; of these, 41% gave positive hybridization signals. Overgo hybridization patterns supported colinearity of loci in regions of sorghum chromosome 3 and rice chromosome 1 and suggested that a possible genomic inversion occurred in this syntenic region in one of the two genomes after the divergence of S. bicolor and O. sativa. Conclusion The results of this study emphasize the importance of identifying conserved sequences in the reference sequence when designing overgo probes in order for those probes to hybridize successfully in distantly related species. As interspecific markers, overgos can be used successfully to construct physical maps in species which diverged less than 8 million years ago, and can be used in a more limited fashion to examine colinearity among species which diverged as much as 40 million years ago. Additionally, overgos are able to provide evidence of genomic rearrangements in comparative physical mapping studies.

Published

2006

27. The genome sequence of segmental allotetraploid peanut Arachis hypogaea

Author

Richard W Michelmore, Brian Abernathy, Melanie Pham, Jacqueline D. Campbell, Sergio Sebastián Samoluk, Ethalinda K. S. Cannon, Marie Mirouze, Ziqi Sun, Scott A. Jackson, Jane Grimwood, Zheng Zheng, Christopher Lui, C. Corley Holbrook, Longhui Ren, Manish K. Pandey, Ye Chu, Kenta Shirasawa, Guillermo Seijo, Sudhansu Dash, Carolina Chavarro, Connor Cameron, Xinyou Zhang, Gaurav Agarwal, Lutz Froenicke, Sophie Lanciano, Andrew Farmer, Soraya C. M. Leal-Bertioli, Nathan T. Weeks, David J. Bertioli, Walid Korani, Senjuti Sinharoy, Olga Dudchenko, Carolina Ballén-Taborda, Rajeev K. Varshney, Annapurna Chitikineni, Jerry Jenkins, Steven B. Cannon, Peggy Ozias-Akins, Erez Lieberman Aiden, Moaine El Baidouri, Márcio C. Moretzsohn, Jeremy Schmutz, Jin Hee Shin, Wei Huang, Dongying Gao, Josh Clevenger, Brian E. Scheffler, Baozhu Guo, Kyung Do Kim, Avinash Sreedasyam, DOE Joint Genome Institute [Walnut Creek], Baylor College of Medicine (BCM), Baylor University, University of Georgia [USA], Laboratoire Génome et développement des plantes (LGDP), Université de Perpignan Via Domitia (UPVD)-Centre National de la Recherche Scientifique (CNRS), Universität Bern [Bern] (UNIBE), Diversité, adaptation, développement des plantes (UMR DIADE), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Genome Center and Department of Plant Sciences, University of California (UC), Purdue University [West Lafayette], United States Department of Energy, Université de Berne, Institut de Recherche pour le Développement (IRD [France-Sud])-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad), University of California, DAVID J. BERTIOLI, UNIVERSITY OF GEORGIA, USA, JERRY JENKINS, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA, JOSH CLEVENGER, UNIVERSITY OF GEORGIA, USA, OLGA DUDCHENKO, BAYLOR COLLEGE OF MEDICINE, HOUSTON, USA, DONGYING GAO, UNIVERSITY OF GEORGIA, USA, GUILLERMO SEIJO, CONICETUNNE, ARGENTINA, SORAYA C. M. LEAL-BERTIOLI, UNIVERSITY OF GEORGIA, USA, LONGHUI REN, IOWA STATE UNIVERSITY, USA, ANDREW D. FARMER, NATIONAL CENTER FOR GENOME RESOURCES, USA, MANISH K. PANDEY, INTERNATIONAL CROPS RESEARCH INSTITUTE FOR THE SEMI-ARID TROPICS (ICRISAT), INDIA, SERGIO S. SAMOLUK, INSTITUTO DE BOTÁNICA DEL NORDESTE (CONICETUNNE), ARGENTINA, BRIAN ABERNATHY, UNIVERSITY OF GEORGIA, USA, GAURAV AGARWAL, UNIVERSITY OF GEORGIA, USA, CAROLINA BALLÉN-TABORDA, UNIVERSITY OF GEORGIA, USA, CONNOR CAMERON, NATIONAL CENTER FOR GENOME RESOURCES, USA, JACQUELINE CAMPBELL, IOWA STATE UNIVERSITY, USA, CAROLINA CHAVARRO, UNIVERSITY OF GEORGIA, USA, ANNAPURNA CHITIKINENI, INTERNATIONAL CROPS RESEARCH INSTITUTE FOR THE SEMI-ARID TROPICS (ICRISAT), INDIA, YE CHU, UNIVERSITY OF GEORGIA, USA, SUDHANSU DASH, NATIONAL CENTER FOR GENOME RESOURCES, USA, MOAINE EL BAIDOURI, UMR5096, FRANCE, BAOZHU GUO, CROP PROTECTION AND MANAGEMENT RESEARCH UNIT, USA, WEI HUANG, IOWA STATE UNIVERSITY, USA, KYUNG DO KIM, UNIVERSITY OF GEORGIA, USA, WALID KORANI, UNIVERSITY OF GEORGIA, USA, SOPHIE LANCIANO, UNIVERSITÉ DE PERPIGNAN, FRANCE, CHRISTOPHER G. LUI, BAYLOR COLLEGE OF MEDICINE, USA, MARIE MIROUZE, UNIVERSITÉ DE PERPIGNAN, FRANCE, MARCIO DE CARVALHO MORETZSOHN, Cenargen, MELANIE PHAM, BAYLOR COLLEGE OF MEDICINE, USA, JIN HEE SHIN, UNIVERSITY OF GEORGIA, USA, KENTA SHIRASAWA, KAZUSA DNA RESEARCH INSTITUTE, JAPAN, SENJUTI SINHAROY, NATIONAL INSTITUTE OF PLANT GENOME RESEARCH, INDIA, AVINASH SREEDASYAM, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA, NATHAN T. WEEKS, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, XINYOU ZHANG, HENAN ACADEMY OF AGRICULTURAL SCIENCES, CHINA, ZHENG ZHENG, HENAN ACADEMY OF AGRICULTURAL SCIENCES, CHINA, ZIQI SUN, HENAN ACADEMY OF AGRICULTURAL SCIENCES, CHINA, LUTZ FROENICKE, UNIVERSITY OF CALIFORNIA, DAVIS, USA, EREZ L. AIDEN, BAYLOR COLLEGE OF MEDICINE, USA, RICHARD MICHELMORE, UNIVERSITY OF CALIFORNIA, DAVIS, USA, RAJEEV K. VARSHNEY, INTERNATIONAL CROPS RESEARCH INSTITUTE FOR THE SEMI-ARID TROPICS (ICRISAT), INDIA, C. CORLEY HOLBROOK, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, ETHALINDA K. S. CANNON, IOWA STATE UNIVERSITY, USA, BRIAN E. SCHEFFLER, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, JANE GRIMWOOD, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA, PEGGY OZIAS-AKINS, UNIVERSITY OF GEORGIA, USA, STEVEN B. CANNON, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, SCOTT A. JACKSON, UNIVERSITY OF GEORGIA, USA, and JEREMY SCHMUTZ, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA.

Subjects

Arachis, [SDV]Life Sciences [q-bio], Medical and Health Sciences, Genome, Domestication, 0302 clinical medicine, Gene Expression Regulation, Plant, ComputingMilieux_MISCELLANEOUS, Recombination, Genetic, 2. Zero hunger, Peanuts, 0303 health sciences, purl.org/becyt/ford/4.4 [https], food and beverages, Biodiversity, Biological Sciences, GENOME, Phenotype, Biotecnología Agrícola y Biotecnología Alimentaria, ARACHIS HYPOGAEA, Ploidy, SEGMENTAL ALLOTETRAPLOID, Genome, Plant, Crops, Agricultural, Plant genetics, DNA, Plant, Evolution, Biotecnología Agropecuaria, Argentina, Crops, Genomics, Biology, Chromosomes, Chromosomes, Plant, Evolution, Molecular, Polyploidy, 03 medical and health sciences, Genetic, Species Specificity, Polyploid, Genetics, Hybridization, 030304 developmental biology, Whole genome sequencing, Agricultural, Hypogaea, fungi, Molecular, Genetic Variation, Plant, DNA, DNA Methylation, biology.organism_classification, Base sequence, Recombination, Arachis hypogaea L, Arachis hypogaea, Tetraploidy, Gene Expression Regulation, CIENCIAS AGRÍCOLAS, Evolutionary biology, Hybridization, Genetic, purl.org/becyt/ford/4 [https], 030217 neurology & neurosurgery, Developmental Biology

Abstract

Like many other crops, the cultivated peanut (Arachis hypogaea L.) is of hybrid origin and has a polyploid genome that contains essentially complete sets of chromosomes from two ancestral species. Here we report the genome sequence of peanut and show that after its polyploid origin, the genome has evolved through mobile-element activity, deletions and by the flow of genetic information between corresponding ancestral chromosomes (that is, homeologous recombination). Uniformity of patterns of homeologous recombination at the ends of chromosomes favors a single origin for cultivated peanut and its wild counterpart A. monticola. However, through much of the genome, homeologous recombination has created diversity. Using new polyploid hybrids made from the ancestral species, we show how this can generate phenotypic changes such as spontaneous changes in the color of the flowers. We suggest that diversity generated by these genetic mechanisms helped to favor the domestication of the polyploid A. hypogaea over other diploid Arachis species cultivated by humans. Fil: Bertioli, David J.. University of Georgia; Estados Unidos Fil: Jenkins, Jerry. Hudsonalpha Institute For Biotechnology; Estados Unidos Fil: Clevenger, Josh. University of Georgia; Estados Unidos Fil: Dudchenko, Olga. The Center for Genome Architecture; Estados Unidos Fil: Gao, Dongying. University of Georgia; Estados Unidos Fil: Seijo, José Guillermo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Nordeste. Instituto de Botánica del Nordeste. Universidad Nacional del Nordeste. Facultad de Ciencias Agrarias. Instituto de Botánica del Nordeste; Argentina Fil: Leal Bertioli, Soraya C.M.. Universidad Nacional del Nordeste; Argentina Fil: Ren, Longhui. University of Georgia; Estados Unidos Fil: Farmer, Andrew D.. University of Georgia; Estados Unidos Fil: Pandey, Manish K.. Center of Excellence in Genomics & Systems Biology, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT); India Fil: Samoluk, Sergio Sebastián. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Nordeste. Instituto de Botánica del Nordeste. Universidad Nacional del Nordeste. Facultad de Ciencias Agrarias. Instituto de Botánica del Nordeste; Argentina Fil: Abernathy, Brian. University of Georgia; Estados Unidos Fil: Agarwal, Gaurav. University of Georgia; Estados Unidos Fil: Ballén Taborda, Carolina. University of Georgia; Estados Unidos Fil: Cameron, Connor. National Center for Genome Resources; Estados Unidos Fil: Campbell, Jacqueline. University of Iowa; Estados Unidos Fil: Chavarro, Carolina. University of Georgia; Estados Unidos Fil: Chitikineni, Annapurna. Center of Excellence in Genomics & Systems Biology, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT); India Fil: Chu, Ye. University of Georgia; Estados Unidos Fil: Dash, Sudhansu. National Center for Genome Resources; Estados Unidos Fil: El Baidouri, Moaine. Centre National de la Recherche Scientifique; Francia Fil: Guo, Baozhu. University of Georgia; Estados Unidos Fil: Huang, Wei. University of Iowa; Estados Unidos Fil: Kim, Kyung Do. University of Georgia; Estados Unidos. Corporate R&D, LG Chem; Corea del Sur Fil: Korani, Walid. University of Georgia; Estados Unidos Fil: Lanciano, Sophie. Centre National de la Recherche Scientifique; Francia Fil: Lui, Christopher G.. The Center for Genome Architecture; Estados Unidos Fil: Mirouze, Marie. Centre National de la Recherche Scientifique; Francia Fil: Moretzsohn, Márcio C.. Ministerio da Agricultura Pecuaria e Abastecimento de Brasil. Empresa Brasileira de Pesquisa Agropecuaria; Brasil Fil: Pham, Melanie. The Center for Genome Architecture; Estados Unidos Fil: Shin, Jin Hee. University of Georgia; Estados Unidos Fil: Shirasawa, Kenta Shirasawa. Department of Frontier Research and Development, Kazusa DNA Research Institute; Japón Fil: Sinharoy, Senjuti. National Institute of Plant Genome Research; India Fil: Sreedasyam, Avinash. Hudson Alpha Institute of Biotechnology; Estados Unidos Fil: Weeks, Nathan T.. United States Department of Agriculture; Estados Unidos Fil: Zhang, Xinyou. Henan Academy of Agricultural Sciences; China Fil: Zheng, Zheng. Henan Academy of Agricultural Sciences; China Fil: Sun, Ziqi. Henan Academy of Agricultural Sciences; China Fil: Froenicke, Lutz. University of California at Davis; Estados Unidos Fil: Aiden, Erez L.. The Center for Genome Architecture; Estados Unidos Fil: Michelmore, Richard. University of California at Davis; Estados Unidos Fil: Varshney, Rajeev K.. Center of Excellence in Genomics & Systems Biology, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT); India Fil: Holbrook, C. Corley. United States Department of Agriculture; Estados Unidos Fil: Cannon, Ethalinda K. S.. University of Iowa; Estados Unidos Fil: Scheffler, Brian E.. United States Department of Agriculture; Estados Unidos Fil: Grimwood, Jane. Hudson Alpha Institute of Biotechnology; Estados Unidos Fil: Ozias-Akins, Peggy. University of Georgia; Estados Unidos Fil: Cannon, Steven B.. United States Department of Agriculture; Estados Unidos Fil: Jackson, Scott A.. University of Georgia; Estados Unidos Fil: Schmutz, Jeremy. Hudson Alpha Institute of Biotechnology; Estados Unidos

28. Transcriptomic changes due to water deficit define a general soybean response and accession-specific pathways for drought avoidance

Author

Carolina Chavarro, Zenglu Li, Brian Abernathy, Scott A. Jackson, Justin N. Vaughn, Jin Hee Shin, Kyung Do Kim, and Hussein Abdel-Haleem

Subjects

Abiotic component, Genetics, education.field_of_study, Drought stress, Glycine max, Population, Quantitative trait loci (QTL), Canopy-wilting, Water, food and beverages, Plant Science, Quantitative trait locus, Biology, Genome, Phenotype, Droughts, Transcriptome, RNA-Sequencing, Genotype, Soybeans, education, Gene, Genotype x environment, Research Article

Abstract

Background Among abiotic stresses, drought is the most common reducer of crop yields. The slow-wilting soybean genotype PI 416937 is somewhat robust to water deficit and has been used previously to map the trait in a bi-parental population. Since drought stress response is a complex biological process, whole genome transcriptome analysis was performed to obtain a deeper understanding of the drought response in soybean. Results Contrasting data from PI 416937 and the cultivar ‘Benning’, we developed a classification system to identify genes that were either responding to water-deficit in both genotypes or that had a genotype x environment (GxE) response. In spite of very different wilting phenotypes, 90% of classifiable genes had either constant expression in both genotypes (33%) or very similar response profiles (E genes, 57%). By further classifying E genes based on expression profiles, we were able to discern the functional specificity of transcriptional responses at particular stages of water-deficit, noting both the well-known reduction in photosynthesis genes as well as the less understood up-regulation of the protein transport pathway. Two percent of classifiable genes had a well-defined GxE response, many of which are located within slow-wilting QTLs. We consider these strong candidates for possible causal genes underlying PI 416937’s unique drought avoidance strategy. Conclusions There is a general and functionally significant transcriptional response to water deficit that involves not only known pathways, such as down-regulation of photosynthesis, but also up-regulation of protein transport and chromatin remodeling. Genes that show a genotypic difference are more likely to show an environmental response than genes that are constant between genotypes. In this study, at least five genes that clearly exhibited a genotype x environment response fell within known QTL and are very good candidates for further research into slow-wilting. Electronic supplementary material The online version of this article (doi:10.1186/s12870-015-0422-8) contains supplementary material, which is available to authorized users.