Your search keyword '"Talag, J."' showing total 36 results

1. Characterization of transposable elements in the genome of rice (Oryza sativa L.) using Representational Difference Analysis (RDA)

Author

Panaud, O., Vitte, C., Hivert, J., Muzlak, S., Talag, J., Brar, D., and Sarr, A.

Published

2002

2. Constructing a physical map of the rice genome

Author

Sanchez, A. C., primary, Fu, B., additional, Maghirang, R., additional, Aquino, C., additional, Mendoza, J., additional, Talag, J., additional, Yu, S., additional, Domingo, J. R., additional, McNally, K. L., additional, Bagali, P., additional, Khush, G. S., additional, and Li, Z. K., additional

Published

2008

3. The Amborella Genome and the Evolution of Flowering Plants

Author

Albert, Va, Barbazuk, Wb, Depamphilis, Cw, Der, Jp, Leebens Mack, J, Ma, H, Palmer, Jd, Rounsley, S, Sankoff, D, Schuster, Sc, Soltis, De, Soltis, Ps, Wessler, Sr, Wing, Ra, Ammiraju, Js, Chamala, S, Chanderbali, As, Determann, R, Ralph, P, Talag, J, Tomsho, L, Walts, B, Wanke, S, Chang, Th, Lan, T, Arikit, S, Axtell, Mj, Ayyampalayam, S, Burnette JM 3rd, DE PAOLI, Emanuele, Estill, Jc, Farrell, Np, Harkess, A, Jiao, Y, Liu, K, Mei, W, Meyers, Bc, Shahid, S, Wafula, E, Zhai, J, Zhang, X, Carretero Paulet, L, Lyons, E, Tang, H, Zheng, C, Altman, Ns, Chen, F, Chen, Jq, Chiang, V, De Paoli, E, Fogliani, B, Guo, C, Harholt, J, Job, C, Job, D, Kim, S, Kong, H, Li, G, Li, L, Liu, J, Park, J, Qi, X, Rajjou, L, Burtet Sarramegna, V, Sederoff, R, Sun, Yh, Ulvskov, P, Villegente, M, Xue, Jy, Yeh, Tf, Yu, X, Acosta, Jj, Bruenn, Ra, de Kochko, A, Herrera Estrella LR, Ibarra Laclette, E, Kirst, M, Pissis, Sp, Poncet, V, Tomsho, L., Department of Biological Sciences, University at Buffalo [SUNY] (SUNY Buffalo), State University of New York (SUNY)-State University of New York (SUNY), Department of Biology, University of Florida [Gainesville], University of Florida Genetics Institute, Huck Institutes of the Life Sciences [University Park], Intercollege Plant Biology Graduate Program, Pennsylvania State University (Penn State), Penn State System-Penn State System, Center for Comparative Genomics and Bioinformatics, Penn State Univ, Ctr Comparat Genom & Bioinformat, University Pk, PA 16802 USA, Université Paris Diderot - Paris 7 (UPD7), Department of Plant Biology [Athens], University of Georgia [USA], Penn State Univ, Huck Inst Life Sci, University Pk, PA 16802 USA, Penn State Univ, Dept Biol, University Pk, PA 16802 USA, Fudan Univ, Sch Life Sci, State Key Lab Genet Engn, Shanghai 200433, Peoples R China, Fudan Univ, Inst Genet, Inst Plant Biol, Ctr Evolutionary Biol,Inst Biomed Sci, Shanghai 200433, Peoples R China, Indiana Univ, Dept Biol, Bloomington, IN 47405 USA, Univ Arizona, Inst Collaborat Res BIO5, Tucson, AZ 85721 USA, Dow AgroSci, Indianapolis, IN 46268 USA, Univ Arizona, Sch Biol Sci, Tucson, AZ 85721 USA, Department of Mathematics and Statistics, University of Ottawa [Ottawa] (uOttawa), Singapore Ctr Environm Life Sci Engn, Singapore, Singapore, Penn State Univ, Dept Biochem & Mol Biol, University Pk, PA 16802 USA, Florida Museum of Natural History, Department of Botany and Plant Sciences [Riverside], University of California [Riverside] (UCR), University of California-University of California, Univ Arizona, Arizona Genom Inst, Tucson, AZ 85721 USA, Atlanta Bot Garden, Atlanta, GA 30309 USA, Univ Florida, Dept Biol, Gainesville, FL 32611 USA, Tech Univ Dresden, Inst Bot, D-01062 Dresden, Germany, SUNY Buffalo, Dept Biol Sci, Buffalo, NY 14260 USA, Chongqing Univ Sci & Technol, Dept Biol, Chongqing 4000042, Peoples R China, Univ Delaware, Delaware Biotechnol Inst, Newark, DE 19711 USA, Univ Georgia, Dept Plant Biol, Athens, GA 30602 USA, Univ Udine, Dipartimento Sci Agr & Ambientali, I-33100 Udine, Italy, Penn State Univ, Intercoll Plant Biol Grad Program, University Pk, PA 16802 USA, Univ Arizona, iPlant Collaborat, Tucson, AZ 85721 USA, J Craig Venter Inst, Rockville, MD 20850 USA, Univ Ottawa, Dept Math & Stat, Ottawa, ON K1N 6N5, Canada, Penn State Univ, Dept Stat, University Pk, PA 16802 USA, Univ Tennessee, Dept Plant Sci, Knoxville, TN 37996 USA, Nanjing Univ, Sch Life Sci, Nanjing 210093, Jiangsu, Peoples R China, N Carolina State Univ, Dept Forestry & Environm Resources, Raleigh, NC 27695 USA, Institut Agronomique Néo-Calédonien (IAC), Univ New Caledonia, Lab Insulaire Vivant & Environm, Noumea 98851, New Caledonia, Chinese Acad Sci, Inst Bot, State Key Lab Systemat & Evolutionary Bot, Beijing 100093, Peoples R China, Univ Copenhagen, Dept Plant & Environm Sci, DK-1871 Frederiksberg C, Denmark, Univ Claude Bernard Lyon, Inst Natl Sci Appl Bayer CropSci Joint Lab UMR524, CNRS, Bayer CropSci, F-69263 Lyon 9, France, Sungshin Womens Univ, Basic Sci Res Inst, Seoul 142732, South Korea, Sungshin Womens Univ, Sch Biol Sci & Chem, Seoul 142732, South Korea, Zhejiang Univ, Coll Life Sci, Lab Systemat & Evolutionary Bot & Biodivers, Hangzhou 310058, Zhejiang, Peoples R China, Zhejiang Univ, Coll Life Sci, Key Lab Conservat Biol Endangered Wildlife, Minist Educ, Hangzhou 310058, Zhejiang, Peoples R China, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Natl Chung Hsing Univ, Dept Forestry, Taichung 40227, Taiwan, Natl Taiwan Univ, Sch Forestry & Resource Conservat, Taipei 10617, Taiwan, Univ Florida, Sch Forest Resources & Conservat, Gainesville, FL 32611 USA, Univ Calif Berkeley, Dept Plant & Microbial Biol, Berkeley, CA 94720 USA, Diversité, adaptation, développement des plantes (UMR DIADE), 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), Lab Nacl Genom Biodiversidad, Irapuato 36821, Mexico, Univ Florida, Genet Inst, Gainesville, FL 32610 USA, Univ Florida, Florida Museum Nat Hist, Gainesville, FL 32611 USA, Heidelberg Inst Theoret Studies, Sci Comp Grp, D-69118 Heidelberg, Germany, NSF Plant Genome Research Program [0922742], NSF, University of Florida [Gainesville] (UF), University of Florida Genetics Institute (UFGI), Center for Comparative Genomics and Bioinformatics (CCBB), Department of Biology [PennState], State Key Laboratory of Genetic Engineering, Fudan University [Shanghai], Institute of Plant Biology [Shanghai], Department of Biology [Bloomington], Indiana University [Bloomington], Indiana University System-Indiana University System, BIO5 - Institute for Collaborative Bioresearch, University of Arizona, Dow AgroSciences LLC, School of Plant Sciences [Tucson], Department of Mathematics and Statistics [Ottawa], University of Ottawa [Ottawa], Singapore Centre for Environmental Life Sciences Engineering [Singapore] (SCELSE), Nanyang Technological University [Singapour], Department of Biochemistry and Molecular Biology [PennState], Arizona Genomics Institute [Tucson], Atlanta Botanical Garden, Department of Biology [Gainesville] (UF|Biology), Institut für Botanik [Dresden], Technische Universität Dresden = Dresden University of Technology (TU Dresden), Department of Biological Sciences [Buffalo], Department of Biology [Chongqing], Chongqing University of Science & Technology, Plant Genome Mapping Laboratory (PGML), Dipartimento di Scienze Agrarie e Ambientali (DiSA), Università degli Studi di Udine - University of Udine [Italie], iPlant Collaborative, J. Craig Venter Institute, Department of Statistics [PennState], Department of Plant Sciences [Knoxville], The University of Tennessee [Knoxville], School of Life Sciences [Nanjing] (SLiS), Nanjing University (NJU), Department of Forestry and Environmental Resources [Raleigh] (FER), North Carolina State University [Raleigh] (NC State), University of North Carolina System (UNC)-University of North Carolina System (UNC), Université de la Nouvelle-Calédonie (UNC), State Key Laboratory of Systematic and Evolutionary Botany, Institute of Botany [Beijing] (IB-CAS), Chinese Academy of Sciences [Beijing] (CAS)-Chinese Academy of Sciences [Beijing] (CAS), Department of Plant and Environmental Sciences [Frederiksberg], University of Copenhagen = Københavns Universitet (KU), Microbiologie, adaptation et pathogénie (MAP), Centre National de la Recherche Scientifique (CNRS)-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon, Génomique fonctionnelle des champignons pathogènes des plantes (FungiPath), Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Basic Science Research Institute [Seoul], Sungshin Women's University, School of Biological Sciences and Chemistry [Seoul], Laboratory of Systematic & Evolutionary Botany and Biodiversity, Zhejiang University, Key Laboratory of Conservation Biology for Endangered Wildlife of the Ministry of Education, Department of Forestry [Taichung], National Chung Hsing University (NCHU), School of Forestry and Resource Conservation [Taiwan], National Taïwan University (NTU), School of Forest Resources and Conservation [Gainesville] (UF|IFAS|FFGS), Institute of Food and Agricultural Sciences [Gainesville] (UF|IFAS), University of Florida [Gainesville] (UF)-University of Florida [Gainesville] (UF), Department of Plant and Microbial Biology [Berkeley], University of California [Berkeley], Laboratorio Nacional de Genómica para la Biodiversidad (LANGEBIO), Centro de Investigacion y de Estudios Avanzados del Instituto Politécnico Nacional (CINVESTAV), Florida Museum of Natural History [Gainesville], Heidelberg Institute for Theoretical Studies (HITS ), 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]), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), and Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL)

Subjects

0106 biological sciences, Most recent common ancestor, Genetics, Transposable element, 0303 health sciences, education.field_of_study, Multidisciplinary, Lineage (evolution), [SDV]Life Sciences [q-bio], Population, fungi, food and beverages, Biology, 01 natural sciences, Genome, 03 medical and health sciences, Gene duplication, Gene family, education, Gene, 030304 developmental biology, 010606 plant biology & botany

Abstract

Shaping Plant Evolution Amborella trichopoda is understood to be the most basal extant flowering plant and its genome is anticipated to provide insights into the evolution of plant life on Earth (see the Perspective by Adams ). To validate and assemble the sequence, Chamala et al. (p. 1516 ) combined fluorescent in situ hybridization (FISH), genomic mapping, and next-generation sequencing. The Amborella Genome Project (p. 10.1126/science.1241089 ) was able to infer that a whole-genome duplication event preceded the evolution of this ancestral angiosperm, and Rice et al. (p. 1468 ) found that numerous genes in the mitochondrion were acquired by horizontal gene transfer from other plants, including almost four entire mitochondrial genomes from mosses and algae.

Published

2013

4. Dynamic Evolution of Oryza Genomes Revealed by Comparative Genomic Analysis of a Genus-wide Vertical Dataset

Author

Ammiraju, S. S., Lu, F., Sanyal, A., Yu, Y., Song, X., Jiang, N., Pontaroli, A. C., Rambo, T., Currie, J., Kollura, K., Talag, J., Fan, C., Goicoechea, J. L., Zuccolo, Andrea, Bennetzen, J. L., Chen, M., Jackson, S., and Wing, R. A.

Published

2008

5. Evolutionary dynamics of an ancient retrotransposon family provides insights into evolution of genome size in the genus Oryza

Author

Jetty, S., Zuccolo, Andrea, Yu, Y., Song, X., Piegu, B., Chevalier, F., Walling, J., Ma, J., Talag, J., Brar, D., Sanmiguel, P., Jiang, N., Jackson, S., Panaud, O., Wing, R., Ecology and Evolutionary Biology [Tucson] (EEB), University of Arizona, Laboratoire Génome et développement des plantes (LGDP), Université de Perpignan Via Domitia (UPVD)-Centre National de la Recherche Scientifique (CNRS), Department of Agronomy, Purdue University [West Lafayette], and Genomics Core Facility

Subjects

[SDV]Life Sciences [q-bio], ComputingMilieux_MISCELLANEOUS

Abstract

International audience

Published

2007

6. Constructing a physical map of the rice genome.

Author

Sanchez, A. C., Fu, B., Maghirang, R., Aquino, C., Mendoza, J., Talag, J., Yu, S., Domingo, J. R., McNally, K. L., Bagali, P., Khush, G. S., and Li, Z. K.

Subjects

ARTIFICIAL chromosomes, PLANT genomes, RICE genetics, RICE breeding, RICE varieties

Published

2008

7. The genomic landscape of molecular responses to natural drought stress in Panicum hallii

Author

Lovell J., Jenkins J., Lowry D., Mamidi S., Sreedasyam A., Weng X., Barry K., Bonnette J., Campitelli B., Daum C., Gordon S., Gould B., Khasanova A., Lipzen A., MacQueen A., Palacio-Mejía J., Plott C., Shakirov E., Shu S., Yoshinaga Y., Zane M., Kudrna D., Talag J., Rokhsar D., Grimwood J., Schmutz J., Juenger T., Lovell J., Jenkins J., Lowry D., Mamidi S., Sreedasyam A., Weng X., Barry K., Bonnette J., Campitelli B., Daum C., Gordon S., Gould B., Khasanova A., Lipzen A., MacQueen A., Palacio-Mejía J., Plott C., Shakirov E., Shu S., Yoshinaga Y., Zane M., Kudrna D., Talag J., Rokhsar D., Grimwood J., Schmutz J., and Juenger T.

Abstract

© 2018, The Author(s). Environmental stress is a major driver of ecological community dynamics and agricultural productivity. This is especially true for soil water availability, because drought is the greatest abiotic inhibitor of worldwide crop yields. Here, we test the genetic basis of drought responses in the genetic model for C4 perennial grasses, Panicum hallii, through population genomics, field-scale gene-expression (eQTL) analysis, and comparison of two complete genomes. While gene expression networks are dominated by local cis-regulatory elements, we observe three genomic hotspots of unlinked trans-regulatory loci. These regulatory hubs are four times more drought responsive than the genome-wide average. Additionally, cis- and trans-regulatory networks are more likely to have opposing effects than expected under neutral evolution, supporting a strong influence of compensatory evolution and stabilizing selection. These results implicate trans-regulatory evolution as a driver of drought responses and demonstrate the potential for crop improvement in drought-prone regions through modification of gene regulatory networks.

8. ZW sex chromosome structure in Amborella trichopoda.

Author

Carey SB, Aközbek L, Lovell JT, Jenkins J, Healey AL, Shu S, Grabowski P, Yocca A, Stewart A, Jones T, Barry K, Rajasekar S, Talag J, Scutt C, Lowry PP 2nd, Munzinger J, Knox EB, Soltis DE, Soltis PS, Grimwood J, Schmutz J, Leebens-Mack J, and Harkess A

Abstract

Sex chromosomes have evolved hundreds of times across the flowering plant tree of life; their recent origins in some members of this clade can shed light on the early consequences of suppressed recombination, a crucial step in sex chromosome evolution. Amborella trichopoda, the sole species of a lineage that is sister to all other extant flowering plants, is dioecious with a young ZW sex determination system. Here we present a haplotype-resolved genome assembly, including highly contiguous assemblies of the Z and W chromosomes. We identify a ~3-megabase sex-determination region (SDR) captured in two strata that includes a ~300-kilobase inversion that is enriched with repetitive sequences and contains a homologue of the Arabidopsis METHYLTHIOADENOSINE NUCLEOSIDASE (MTN1-2) genes, which are known to be involved in fertility. However, the remainder of the SDR does not show patterns typically found in non-recombining SDRs, such as repeat accumulation and gene loss. These findings are consistent with the hypothesis that dioecy is derived in Amborella and the sex chromosome pair has not significantly degenerated., Competing Interests: Competing interests: The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

9. Relics of interspecific hybridization retained in the genome of a drought-adapted peanut cultivar.

Author

Grabowski PP, Dang P, Jenkins JJ, Sreedasyam A, Webber J, Lamb M, Zhang Q, Sanz-Saez A, Feng Y, Bunting V, Talag J, Clevenger J, Ozias-Akins P, Holbrook CC, Chu Y, Grimwood J, Schmutz J, Chen C, and Lovell JT

Subjects

Molecular Sequence Annotation, Genotype, Alleles, Adaptation, Physiological genetics, Arachis genetics, Genome, Plant, Droughts, Hybridization, Genetic

Abstract

Peanut (Arachis hypogaea L.) is a globally important oil and food crop frequently grown in arid, semi-arid, or dryland environments. Improving drought tolerance is a key goal for peanut crop improvement efforts. Here, we present the genome assembly and gene model annotation for "Line8," a peanut genotype bred from drought-tolerant cultivars. Our assembly and annotation are the most contiguous and complete peanut genome resources currently available. The high contiguity of the Line8 assembly allowed us to explore structural variation both between peanut genotypes and subgenomes. We detect several large inversions between Line8 and other peanut genome assemblies, and there is a trend for the inversions between more genetically diverged genotypes to have higher gene content. We also relate patterns of subgenome exchange to structural variation between Line8 homeologous chromosomes. Unexpectedly, we discover that Line8 harbors an introgression from A.cardenasii, a diploid peanut relative and important donor of disease resistance alleles to peanut breeding populations. The fully resolved sequences of both haplotypes in this introgression provide the first in situ characterization of A.cardenasii candidate alleles that can be leveraged for future targeted improvement efforts. The completeness of our genome will support peanut biotechnology and broader research into the evolution of hybridization and polyploidy., Competing Interests: Conflicts of interest The author(s) declare no conflicts of interest., (© The Author(s) 2024. Published by Oxford University Press on behalf of The Genetics Society of America.)

Published

2024

10. Hydrophobins from Aspergillus mediate fungal interactions with microplastics.

Author

Klauer RR, Silvestri R, White H, Hayes RD, Riley R, Lipzen A, Barry K, Grigoriev IV, Talag J, Bunting V, Stevenson Z, Solomon KV, and Blenner M

Abstract

Microplastics present myriad ecological and human health risks including serving as a vector for pathogens in human and animal food chains. However, the specific mechanisms by which pathogenic fungi colonize these microplastics have yet to be explored. In this work, we examine the opportunistic fungal pathogen, Aspergillus fumigatus, and other common soil and marine Aspergilli , which we found bind microplastics tightly. Up to 3.85+/- 1.48 g microplastic plastic/g fungi were bound and flocculated for polypropylene (PP), polyethylene (PE), and polyethylene terephthalate (PET) powders and particles ranging in size from 0.05 - 5 mm. Gene knockouts revealed hydrophobins as a key biomolecule driving microplastic-fungi binding. Moreover, purified hydrophobins were still able to flocculate microplastics independent of the fungus. Our work elucidates a role for hydrophobins in fungal colonization of microplastics and highlights a potential target for mitigating the harm of microplastics through engineered fungal-microplastic interactions., Competing Interests: Statement of Competing Interests: Work from this manuscript is claimed under pending provisional patent 63/564,151

Published

2024

11. Assembly, comparative analysis, and utilization of a single haplotype reference genome for soybean.

Author

Espina MJC, Lovell JT, Jenkins J, Shu S, Sreedasyam A, Jordan BD, Webber J, Boston L, Brůna T, Talag J, Goodstein D, Grimwood J, Stacey G, Cannon SB, Lorenz AJ, Schmutz J, and Stupar RM

Subjects

Chromosome Mapping, Molecular Sequence Annotation, Glycine max genetics, Genome, Plant genetics, Haplotypes, Chromosomes, Plant genetics

Abstract

Cultivar Williams 82 has served as the reference genome for the soybean research community since 2008, but is known to have areas of genomic heterogeneity among different sub-lines. This work provides an updated assembly (version Wm82.a6) derived from a specific sub-line known as Wm82-ISU-01 (seeds available under USDA accession PI 704477). The genome was assembled using Pacific BioSciences HiFi reads and integrated into chromosomes using HiC. The 20 soybean chromosomes assembled into a genome of 1.01Gb, consisting of 36 contigs. The genome annotation identified 48 387 gene models, named in accordance with previous assembly versions Wm82.a2 and Wm82.a4. Comparisons of Wm82.a6 with other near-gapless assemblies of Williams 82 reveal large regions of genomic heterogeneity, including regions of differential introgression from the cultivar Kingwa within approximately 30 Mb and 25 Mb segments on chromosomes 03 and 07, respectively. Additionally, our analysis revealed a previously unknown large (>20 Mb) heterogeneous region in the pericentromeric region of chromosome 12, where Wm82.a6 matches the 'Williams' haplotype while the other two near-gapless assemblies do not match the haplotype of either parent of Williams 82. In addition to the Wm82.a6 assembly, we also assembled the genome of 'Fiskeby III,' a rich resource for abiotic stress resistance genes. A genome comparison of Wm82.a6 with Fiskeby III revealed the nucleotide and structural polymorphisms between the two genomes within a QTL region for iron deficiency chlorosis resistance. The Wm82.a6 and Fiskeby III genomes described here will enhance comparative and functional genomics capacities and applications in the soybean community., (© 2024 The Author(s). The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

12. Biosynthesis of Haloterpenoids in Red Algae via Microbial-like Type I Terpene Synthases.

Author

Steele TS, Burkhardt I, Moore ML, de Rond T, Bone HK, Barry K, Bunting VM, Grimwood J, Handley LH, Rajasekar S, Talag J, Michael TP, and Moore BS

Subjects

Terpenes chemistry, Monoterpenes chemistry, Rhodophyta chemistry, Alkyl and Aryl Transferases

Abstract

Red algae or seaweeds produce highly distinctive halogenated terpenoid compounds, including the pentabromochlorinated monoterpene halomon that was once heralded as a promising anticancer agent. The first dedicated step in the biosynthesis of these natural product molecules is expected to be catalyzed by terpene synthase (TS) enzymes. Recent work has demonstrated an emerging class of type I TSs in red algal terpene biosynthesis. However, only one such enzyme from a notoriously haloterpenoid-producing red alga ( Laurencia pacifica ) has been functionally characterized and the product structure is not related to halogenated terpenoids. Herein, we report 10 new type I TSs from the red algae Portieria hornemannii , Plocamium pacificum , L. pacifica , and Laurencia subopposita that produce a diversity of halogenated mono- and sesquiterpenes. We used a combination of genome sequencing, terpenoid metabolomics, in vitro biochemistry, and bioinformatics to establish red algal TSs in all four species, including those associated with the selective production of key halogenated terpene precursors myrcene, trans -β-ocimene, and germacrene D-4-ol. These results expand on a small but growing number of characterized red algal TSs and offer insight into the biosynthesis of iconic halogenated algal compounds that are not without precedence elsewhere in biology.

Published

2024

13. Haplotype-resolved genome assembly of Populus tremula × P. alba reveals aspen-specific megabase satellite DNA.

Author

Zhou R, Jenkins JW, Zeng Y, Shu S, Jang H, Harding SA, Williams M, Plott C, Barry KW, Koriabine M, Amirebrahimi M, Talag J, Rajasekar S, Grimwood J, Schmitz RJ, Dawe RK, Schmutz J, and Tsai CJ

Subjects

Haplotypes genetics, Ecosystem, Retroelements, Centromere genetics, DNA, Satellite genetics, Populus genetics

Abstract

Populus species play a foundational role in diverse ecosystems and are important renewable feedstocks for bioenergy and bioproducts. Hybrid aspen Populus tremula × P. alba INRA 717-1B4 is a widely used transformation model in tree functional genomics and biotechnology research. As an outcrossing interspecific hybrid, its genome is riddled with sequence polymorphisms which present a challenge for sequence-sensitive analyses. Here we report a telomere-to-telomere genome for this hybrid aspen with two chromosome-scale, haplotype-resolved assemblies. We performed a comprehensive analysis of the repetitive landscape and identified both tandem repeat array-based and array-less centromeres. Unexpectedly, the most abundant satellite repeats in both haplotypes lie outside of the centromeres, consist of a 147 bp monomer PtaM147, frequently span >1 megabases, and form heterochromatic knobs. PtaM147 repeats are detected exclusively in aspens (section Populus) but PtaM147-like sequences occur in LTR-retrotransposons of closely related species, suggesting their origin from the retrotransposons. The genomic resource generated for this transformation model genotype has greatly improved the design and analysis of genome editing experiments that are highly sensitive to sequence polymorphisms. The work should motivate future hypothesis-driven research to probe into the function of the abundant and aspen-specific PtaM147 satellite DNA., (© 2023 The Authors. The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2023

14. Newly identified sex chromosomes in the Sphagnum (peat moss) genome alter carbon sequestration and ecosystem dynamics.

Author

Healey AL, Piatkowski B, Lovell JT, Sreedasyam A, Carey SB, Mamidi S, Shu S, Plott C, Jenkins J, Lawrence T, Aguero B, Carrell AA, Nieto-Lugilde M, Talag J, Duffy A, Jawdy S, Carter KR, Boston LB, Jones T, Jaramillo-Chico J, Harkess A, Barry K, Keymanesh K, Bauer D, Grimwood J, Gunter L, Schmutz J, Weston DJ, and Shaw AJ

Subjects

Carbon Sequestration, Climate, Sex Chromosomes, Ecosystem, Sphagnopsida physiology

Abstract

Peatlands are crucial sinks for atmospheric carbon but are critically threatened due to warming climates. Sphagnum (peat moss) species are keystone members of peatland communities where they actively engineer hyperacidic conditions, which improves their competitive advantage and accelerates ecosystem-level carbon sequestration. To dissect the molecular and physiological sources of this unique biology, we generated chromosome-scale genomes of two Sphagnum species: S. divinum and S. angustifolium. Sphagnum genomes show no gene colinearity with any other reference genome to date, demonstrating that Sphagnum represents an unsampled lineage of land plant evolution. The genomes also revealed an average recombination rate an order of magnitude higher than vascular land plants and short putative U/V sex chromosomes. These newly described sex chromosomes interact with autosomal loci that significantly impact growth across diverse pH conditions. This discovery demonstrates that the ability of Sphagnum to sequester carbon in acidic peat bogs is mediated by interactions between sex, autosomes and environment., (© 2023. The Author(s).)

Published

2023

15. Genomic variation within the maize stiff-stalk heterotic germplasm pool.

Author

Bornowski N, Michel KJ, Hamilton JP, Ou S, Seetharam AS, Jenkins J, Grimwood J, Plott C, Shu S, Talag J, Kennedy M, Hundley H, Singan VR, Barry K, Daum C, Yoshinaga Y, Schmutz J, Hirsch CN, Hufford MB, de Leon N, Kaeppler SM, and Buell CR

Subjects

Genomics, Haplotypes, Hybrid Vigor, Plant Breeding, Zea mays genetics

Abstract

The stiff-stalk heterotic group in Maize (Zea mays L.) is an important source of inbreds used in U.S. commercial hybrid production. Founder inbreds B14, B37, B73, and, to a lesser extent, B84, are found in the pedigrees of a majority of commercial seed parent inbred lines. We created high-quality genome assemblies of B84 and four expired Plant Variety Protection (ex-PVP) lines LH145 representing B14, NKH8431 of mixed descent, PHB47 representing B37, and PHJ40, which is a Pioneer Hi-Bred International (PHI) early stiff-stalk type. Sequence was generated using long-read sequencing achieving highly contiguous assemblies of 2.13-2.18 Gbp with N50 scaffold lengths >200 Mbp. Inbred-specific gene annotations were generated using a core five-tissue gene expression atlas, whereas transposable element (TE) annotation was conducted using de novo and homology-directed methodologies. Compared with the reference inbred B73, synteny analyses revealed extensive collinearity across the five stiff-stalk genomes, although unique components of the maize pangenome were detected. Comparison of this set of stiff-stalk inbreds with the original Iowa Stiff Stalk Synthetic breeding population revealed that these inbreds represent only a proportion of variation in the original stiff-stalk pool and there are highly conserved haplotypes in released public and ex-Plant Variety Protection inbreds. Despite the reduction in variation from the original stiff-stalk population, substantial genetic and genomic variation was identified supporting the potential for continued breeding success in this pool. The assemblies described here represent stiff-stalk inbreds that have historical and commercial relevance and provide further insight into the emerging maize pangenome., (© 2021 The Authors. The Plant Genome published by Wiley Periodicals LLC on behalf of Crop Science Society of America.)

Published

2021

16. Two gap-free reference genomes and a global view of the centromere architecture in rice.

Author

Song JM, Xie WZ, Wang S, Guo YX, Koo DH, Kudrna D, Gong C, Huang Y, Feng JW, Zhang W, Zhou Y, Zuccolo A, Long E, Lee S, Talag J, Zhou R, Zhu XT, Yuan D, Udall J, Xie W, Wing RA, Zhang Q, Poland J, Zhang J, and Chen LL

Subjects

Molecular Sequence Annotation, Species Specificity, Whole Genome Sequencing, Centromere, Chromosomes, Plant, Genome, Plant, Oryza genetics

Abstract

Rice (Oryza sativa), a major staple throughout the world and a model system for plant genomics and breeding, was the first crop genome sequenced almost two decades ago. However, reference genomes for all higher organisms to date contain gaps and missing sequences. Here, we report the assembly and analysis of gap-free reference genome sequences for two elite O. sativa xian/indica rice varieties, Zhenshan 97 and Minghui 63, which are being used as a model system for studying heterosis and yield. Gap-free reference genomes provide the opportunity for a global view of the structure and function of centromeres. We show that all rice centromeric regions share conserved centromere-specific satellite motifs with different copy numbers and structures. In addition, the similarity of CentO repeats in the same chromosome is higher than across chromosomes, supporting a model of local expansion and homogenization. Both genomes have over 395 non-TE genes located in centromere regions, of which ∼41% are actively transcribed. Two large structural variants at the end of chromosome 11 affect the copy number of resistance genes between the two genomes. The availability of the two gap-free genomes lays a solid foundation for further understanding genome structure and function in plants and breeding climate-resilient varieties., (Copyright © 2021 The Author. Published by Elsevier Inc. All rights reserved.)

Published

2021

17. A genome assembly and the somatic genetic and epigenetic mutation rate in a wild long-lived perennial Populus trichocarpa.

Author

Hofmeister BT, Denkena J, Colomé-Tatché M, Shahryary Y, Hazarika R, Grimwood J, Mamidi S, Jenkins J, Grabowski PP, Sreedasyam A, Shu S, Barry K, Lail K, Adam C, Lipzen A, Sorek R, Kudrna D, Talag J, Wing R, Hall DW, Jacobsen D, Tuskan GA, Schmutz J, Johannes F, and Schmitz RJ

Subjects

Age Factors, DNA Methylation, Epigenesis, Genetic, Gene Expression, Molecular Sequence Annotation, Genome, Plant, Mutation Rate, Populus genetics

Abstract

Background: Plants can transmit somatic mutations and epimutations to offspring, which in turn can affect fitness. Knowledge of the rate at which these variations arise is necessary to understand how plant development contributes to local adaption in an ecoevolutionary context, particularly in long-lived perennials., Results: Here, we generate a new high-quality reference genome from the oldest branch of a wild Populus trichocarpa tree with two dominant stems which have been evolving independently for 330 years. By sampling multiple, age-estimated branches of this tree, we use a multi-omics approach to quantify age-related somatic changes at the genetic, epigenetic, and transcriptional level. We show that the per-year somatic mutation and epimutation rates are lower than in annuals and that transcriptional variation is mainly independent of age divergence and cytosine methylation. Furthermore, a detailed analysis of the somatic epimutation spectrum indicates that transgenerationally heritable epimutations originate mainly from DNA methylation maintenance errors during mitotic rather than during meiotic cell divisions., Conclusion: Taken together, our study provides unprecedented insights into the origin of nucleotide and functional variation in a long-lived perennial plant.

Published

2020

18. Genome sequence of the model rice variety KitaakeX.

Author

Jain R, Jenkins J, Shu S, Chern M, Martin JA, Copetti D, Duong PQ, Pham NT, Kudrna DA, Talag J, Schackwitz WS, Lipzen AM, Dilworth D, Bauer D, Grimwood J, Nelson CR, Xing F, Xie W, Barry KW, Wing RA, Schmutz J, Li G, and Ronald PC

Subjects

Computational Biology methods, Genetic Variation, Molecular Sequence Annotation, Oryza classification, Phenotype, Genome, Plant, Genomics methods, Oryza genetics, Whole Genome Sequencing

Abstract

Background: The availability of thousands of complete rice genome sequences from diverse varieties and accessions has laid the foundation for in-depth exploration of the rice genome. One drawback to these collections is that most of these rice varieties have long life cycles, and/or low transformation efficiencies, which limits their usefulness as model organisms for functional genomics studies. In contrast, the rice variety Kitaake has a rapid life cycle (9 weeks seed to seed) and is easy to transform and propagate. For these reasons, Kitaake has emerged as a model for studies of diverse monocotyledonous species., Results: Here, we report the de novo genome sequencing and analysis of Oryza sativa ssp. japonica variety KitaakeX, a Kitaake plant carrying the rice XA21 immune receptor. Our KitaakeX sequence assembly contains 377.6 Mb, consisting of 33 scaffolds (476 contigs) with a contig N50 of 1.4 Mb. Complementing the assembly are detailed gene annotations of 35,594 protein coding genes. We identified 331,335 genomic variations between KitaakeX and Nipponbare (ssp. japonica), and 2,785,991 variations between KitaakeX and Zhenshan97 (ssp. indica). We also compared Kitaake resequencing reads to the KitaakeX assembly and identified 219 small variations. The high-quality genome of the model rice plant KitaakeX will accelerate rice functional genomics., Conclusions: The high quality, de novo assembly of the KitaakeX genome will serve as a useful reference genome for rice and will accelerate functional genomics studies of rice and other species.

Published

2019

19. Genome-wide association mapping of date palm fruit traits.

Author

Hazzouri KM, Gros-Balthazard M, Flowers JM, Copetti D, Lemansour A, Lebrun M, Masmoudi K, Ferrand S, Dhar MI, Fresquez ZA, Rosas U, Zhang J, Talag J, Lee S, Kudrna D, Powell RF, Leitch IJ, Krueger RR, Wing RA, Amiri KMA, and Purugganan MD

Subjects

Alleles, Chromosome Mapping, Codon, Initiator, DNA, Plant genetics, Fructose, Fruit genetics, Genome, Plant genetics, Genome-Wide Association Study, Glucose, Mutation, Phenotype, Polymorphism, Genetic, Retroelements, Sequence Analysis, DNA, Starch, Sucrose, beta-Fructofuranosidase genetics, Fruit chemistry, Phoeniceae genetics, Pigmentation genetics, Sex Determination Processes genetics

Abstract

Date palms (Phoenix dactylifera) are an important fruit crop of arid regions of the Middle East and North Africa. Despite its importance, few genomic resources exist for date palms, hampering evolutionary genomic studies of this perennial species. Here we report an improved long-read genome assembly for P. dactylifera that is 772.3 Mb in length, with contig N50 of 897.2 Kb, and use this to perform genome-wide association studies (GWAS) of the sex determining region and 21 fruit traits. We find a fruit color GWAS at the R2R3-MYB transcription factor VIRESCENS gene and identify functional alleles that include a retrotransposon insertion and start codon mutation. We also find a GWAS peak for sugar composition spanning deletion polymorphisms in multiple linked invertase genes. MYB transcription factors and invertase are implicated in fruit color and sugar composition in other crops, demonstrating the importance of parallel evolution in the evolutionary diversification of domesticated species.

Published

2019

20. Publisher Correction: Genomes of 13 domesticated and wild rice relatives highlight genetic conservation, turnover and innovation across the genus Oryza.

Author

Stein JC, Yu Y, Copetti D, Zwickl DJ, Zhang L, Zhang C, Chougule K, Gao D, Iwata A, Goicoechea JL, Wei S, Wang J, Liao Y, Wang M, Jacquemin J, Becker C, Kudrna D, Zhang J, Londono CEM, Song X, Lee S, Sanchez P, Zuccolo A, Ammiraju JSS, Talag J, Danowitz A, Rivera LF, Gschwend AR, Noutsos C, Wu CC, Kao SM, Zeng JW, Wei FJ, Zhao Q, Feng Q, El Baidouri M, Carpentier MC, Lasserre E, Cooke R, da Rosa Farias D, da Maia LC, Dos Santos RS, Nyberg KG, McNally KL, Mauleon R, Alexandrov N, Schmutz J, Flowers D, Fan C, Weigel D, Jena KK, Wicker T, Chen M, Han B, Henry R, Hsing YC, Kurata N, de Oliveira AC, Panaud O, Jackson SA, Machado CA, Sanderson MJ, Long M, Ware D, and Wing RA

Abstract

This article was not made open access when initially published online, which was corrected before print publication. In addition, ORCID links were missing for 12 authors and have been added to the HTML and PDF versions of the article.

Published

2018

21. Genomic variation in 3,010 diverse accessions of Asian cultivated rice.

Author

Wang W, Mauleon R, Hu Z, Chebotarov D, Tai S, Wu Z, Li M, Zheng T, Fuentes RR, Zhang F, Mansueto L, Copetti D, Sanciangco M, Palis KC, Xu J, Sun C, Fu B, Zhang H, Gao Y, Zhao X, Shen F, Cui X, Yu H, Li Z, Chen M, Detras J, Zhou Y, Zhang X, Zhao Y, Kudrna D, Wang C, Li R, Jia B, Lu J, He X, Dong Z, Xu J, Li Y, Wang M, Shi J, Li J, Zhang D, Lee S, Hu W, Poliakov A, Dubchak I, Ulat VJ, Borja FN, Mendoza JR, Ali J, Li J, Gao Q, Niu Y, Yue Z, Naredo MEB, Talag J, Wang X, Li J, Fang X, Yin Y, Glaszmann JC, Zhang J, Li J, Hamilton RS, Wing RA, Ruan J, Zhang G, Wei C, Alexandrov N, McNally KL, Li Z, and Leung H

Subjects

Asia, Evolution, Molecular, Genes, Plant genetics, Genetics, Population, Genomics, Haplotypes, INDEL Mutation genetics, Phylogeny, Plant Breeding, Polymorphism, Single Nucleotide genetics, Crops, Agricultural classification, Crops, Agricultural genetics, Genetic Variation, Genome, Plant genetics, Oryza classification, Oryza genetics

Abstract

Here we analyse genetic variation, population structure and diversity among 3,010 diverse Asian cultivated rice (Oryza sativa L.) genomes from the 3,000 Rice Genomes Project. Our results are consistent with the five major groups previously recognized, but also suggest several unreported subpopulations that correlate with geographic location. We identified 29 million single nucleotide polymorphisms, 2.4 million small indels and over 90,000 structural variations that contribute to within- and between-population variation. Using pan-genome analyses, we identified more than 10,000 novel full-length protein-coding genes and a high number of presence-absence variations. The complex patterns of introgression observed in domestication genes are consistent with multiple independent rice domestication events. The public availability of data from the 3,000 Rice Genomes Project provides a resource for rice genomics research and breeding.

Published

2018

22. Genomes of 13 domesticated and wild rice relatives highlight genetic conservation, turnover and innovation across the genus Oryza.

Author

Stein JC, Yu Y, Copetti D, Zwickl DJ, Zhang L, Zhang C, Chougule K, Gao D, Iwata A, Goicoechea JL, Wei S, Wang J, Liao Y, Wang M, Jacquemin J, Becker C, Kudrna D, Zhang J, Londono CEM, Song X, Lee S, Sanchez P, Zuccolo A, Ammiraju JSS, Talag J, Danowitz A, Rivera LF, Gschwend AR, Noutsos C, Wu CC, Kao SM, Zeng JW, Wei FJ, Zhao Q, Feng Q, El Baidouri M, Carpentier MC, Lasserre E, Cooke R, Rosa Farias DD, da Maia LC, Dos Santos RS, Nyberg KG, McNally KL, Mauleon R, Alexandrov N, Schmutz J, Flowers D, Fan C, Weigel D, Jena KK, Wicker T, Chen M, Han B, Henry R, Hsing YC, Kurata N, de Oliveira AC, Panaud O, Jackson SA, Machado CA, Sanderson MJ, Long M, Ware D, and Wing RA

Subjects

Conserved Sequence, Domestication, Genetic Speciation, Genome, Plant, Phylogeny, Crops, Agricultural genetics, Evolution, Molecular, Genetic Variation, Oryza classification, Oryza genetics

Abstract

The genus Oryza is a model system for the study of molecular evolution over time scales ranging from a few thousand to 15 million years. Using 13 reference genomes spanning the Oryza species tree, we show that despite few large-scale chromosomal rearrangements rapid species diversification is mirrored by lineage-specific emergence and turnover of many novel elements, including transposons, and potential new coding and noncoding genes. Our study resolves controversial areas of the Oryza phylogeny, showing a complex history of introgression among different chromosomes in the young 'AA' subclade containing the two domesticated species. This study highlights the prevalence of functionally coupled disease resistance genes and identifies many new haplotypes of potential use for future crop protection. Finally, this study marks a milestone in modern rice research with the release of a complete long-read assembly of IR 8 'Miracle Rice', which relieved famine and drove the Green Revolution in Asia 50 years ago.

Published

2018

23. Publisher correction: Young inversion with multiple linked QTLs under selection in a hybrid zone.

Author

Lee CR, Wang B, Mojica JP, Mandáková T, Prasad KVSK, Luis Goicoechea J, Perera N, Hellsten U, Hundley HN, Johnson J, Grimwood J, Barry K, Fairclough S, Jenkins JW, Yu Y, Kudrna D, Zhang J, Talag J, Golser W, Ghattas K, Schranz ME, Wing R, Lysak MA, Schmutz J, Rokhsar DS, and Mitchell-Olds T

Abstract

In Fig. 5 of the version of this Article originally published, the final number on the x axes of each panel was incorrectly written as 1.5; it should have read 7.5. This has now been corrected in all versions of the Article.

Published

2017

24. Young inversion with multiple linked QTLs under selection in a hybrid zone.

Author

Lee CR, Wang B, Mojica JP, Mandáková T, Prasad KVSK, Goicoechea JL, Perera N, Hellsten U, Hundley HN, Johnson J, Grimwood J, Barry K, Fairclough S, Jenkins JW, Yu Y, Kudrna D, Zhang J, Talag J, Golser W, Ghattas K, Schranz ME, Wing R, Lysak MA, Schmutz J, Rokhsar DS, and Mitchell-Olds T

Abstract

Fixed chromosomal inversions can reduce gene flow and promote speciation in two ways: by suppressing recombination and by carrying locally favoured alleles at multiple loci. However, it is unknown whether favoured mutations slowly accumulate on older inversions or if young inversions spread because they capture pre-existing adaptive quantitative trait loci (QTLs). By genetic mapping, chromosome painting and genome sequencing, we have identified a major inversion controlling ecologically important traits in Boechera stricta. The inversion arose since the last glaciation and subsequently reached local high frequency in a hybrid speciation zone. Furthermore, the inversion shows signs of positive directional selection. To test whether the inversion could have captured existing, linked QTLs, we crossed standard, collinear haplotypes from the hybrid zone and found multiple linked phenology QTLs within the inversion region. These findings provide the first direct evidence that linked, locally adapted QTLs may be captured by young inversions during incipient speciation.

Published

2017

25. Building two indica rice reference genomes with PacBio long-read and Illumina paired-end sequencing data.

Author

Zhang J, Chen LL, Sun S, Kudrna D, Copetti D, Li W, Mu T, Jiao WB, Xing F, Lee S, Talag J, Song JM, Du B, Xie W, Luo M, Maldonado CE, Goicoechea JL, Xiong L, Wu C, Xing Y, Zhou DX, Yu S, Zhao Y, Wang G, Yu Y, Luo Y, Hurtado BE, Danowitz A, Wing RA, and Zhang Q

Subjects

Genome, Oryza genetics

Abstract

Over the past 30 years, we have performed many fundamental studies on two Oryza sativa subsp. indica varieties, Zhenshan 97 (ZS97) and Minghui 63 (MH63). To improve the resolution of many of these investigations, we generated two reference-quality reference genome assemblies using the most advanced sequencing technologies. Using PacBio SMRT technology, we produced over 108 (ZS97) and 174 (MH63) Gb of raw sequence data from 166 (ZS97) and 209 (MH63) pools of BAC clones, and generated ~97 (ZS97) and ~74 (MH63) Gb of paired-end whole-genome shotgun (WGS) sequence data with Illumina sequencing technology. With these data, we successfully assembled two platinum standard reference genomes that have been publicly released. Here we provide the full sets of raw data used to generate these two reference genome assemblies. These data sets can be used to test new programs for better genome assembly and annotation, aid in the discovery of new insights into genome structure, function, and evolution, and help to provide essential support to biological research in general., Competing Interests: The authors declare no competing financial interests.

Published

2016

26. Extensive sequence divergence between the reference genomes of two elite indica rice varieties Zhenshan 97 and Minghui 63.

Author

Zhang J, Chen LL, Xing F, Kudrna DA, Yao W, Copetti D, Mu T, Li W, Song JM, Xie W, Lee S, Talag J, Shao L, An Y, Zhang CL, Ouyang Y, Sun S, Jiao WB, Lv F, Du B, Luo M, Maldonado CE, Goicoechea JL, Xiong L, Wu C, Xing Y, Zhou DX, Yu S, Zhao Y, Wang G, Yu Y, Luo Y, Zhou ZW, Hurtado BE, Danowitz A, Wing RA, and Zhang Q

Subjects

Chromosome Mapping methods, Gene Expression Profiling, Gene Expression Regulation, Plant, Genes, Plant genetics, INDEL Mutation, Oryza classification, Polymorphism, Single Nucleotide, Species Specificity, Chromosomes, Plant genetics, Genetic Variation, Genome, Plant genetics, Oryza genetics

Abstract

Asian cultivated rice consists of two subspecies: Oryza sativa subsp. indica and O. sativa subsp. japonica Despite the fact that indica rice accounts for over 70% of total rice production worldwide and is genetically much more diverse, a high-quality reference genome for indica rice has yet to be published. We conducted map-based sequencing of two indica rice lines, Zhenshan 97 (ZS97) and Minghui 63 (MH63), which represent the two major varietal groups of the indica subspecies and are the parents of an elite Chinese hybrid. The genome sequences were assembled into 237 (ZS97) and 181 (MH63) contigs, with an accuracy >99.99%, and covered 90.6% and 93.2% of their estimated genome sizes. Comparative analyses of these two indica genomes uncovered surprising structural differences, especially with respect to inversions, translocations, presence/absence variations, and segmental duplications. Approximately 42% of nontransposable element related genes were identical between the two genomes. Transcriptome analysis of three tissues showed that 1,059-2,217 more genes were expressed in the hybrid than in the parents and that the expressed genes in the hybrid were much more diverse due to their divergence between the parental genomes. The public availability of two high-quality reference genomes for the indica subspecies of rice will have large-ranging implications for plant biology and crop genetic improvement., Competing Interests: The authors declare no conflict of interest.

Published

2016

27. DNA methylation changes facilitated evolution of genes derived from Mutator-like transposable elements.

Author

Wang J, Yu Y, Tao F, Zhang J, Copetti D, Kudrna D, Talag J, Lee S, Wing RA, and Fan C

Subjects

Gene Expression Regulation, Plant, Genome, Plant, Genomics, RNA, Small Untranslated genetics, DNA Methylation genetics, DNA Transposable Elements genetics, Evolution, Molecular, Oryza genetics

Abstract

Background: Mutator-like transposable elements, a class of DNA transposons, exist pervasively in both prokaryotic and eukaryotic genomes, with more than 10,000 copies identified in the rice genome. These elements can capture ectopic genomic sequences that lead to the formation of new gene structures. Here, based on whole-genome comparative analyses, we comprehensively investigated processes and mechanisms of the evolution of putative genes derived from Mutator-like transposable elements in ten Oryza species and the outgroup Leersia perieri, bridging ~20 million years of evolutionary history., Results: Our analysis identified thousands of putative genes in each of the Oryza species, a large proportion of which have evidence of expression and contain chimeric structures. Consistent with previous reports, we observe that the putative Mutator-like transposable element-derived genes are generally GC-rich and mainly derive from GC-rich parental sequences. Furthermore, we determine that Mutator-like transposable elements capture parental sequences preferentially from genomic regions with low methylation levels and high recombination rates. We explicitly show that methylation levels in the internal and terminated inverted repeat regions of these elements, which might be directed by the 24-nucleotide small RNA-mediated pathway, are different and change dynamically over evolutionary time. Lastly, we demonstrate that putative genes derived from Mutator-like transposable elements tend to be expressed in mature pollen, which have undergone de-methylation programming, thereby providing a permissive expression environment for newly formed/transposable element-derived genes., Conclusions: Our results suggest that DNA methylation may be a primary mechanism to facilitate the origination, survival, and regulation of genes derived from Mutator-like transposable elements, thus contributing to the evolution of gene innovation and novelty in plant genomes.

Published

2016

28. A BAC library of the SP80-3280 sugarcane variety (saccharum sp.) and its inferred microsynteny with the sorghum genome.

Author

Figueira TR, Okura V, Rodrigues da Silva F, Jose da Silva M, Kudrna D, Ammiraju JS, Talag J, Wing R, and Arruda P

Subjects

Chromosomes, Plant genetics, Mutagenesis, Insertional genetics, Oryza genetics, Repetitive Sequences, Nucleic Acid genetics, Sequence Analysis, DNA, Zea mays genetics, Chromosomes, Artificial, Bacterial genetics, Gene Library, Genome, Plant genetics, Saccharum genetics, Sorghum genetics, Synteny genetics

Abstract

Background: Sugarcane breeding has significantly progressed in the last 30 years, but achieving additional yield gains has been difficult because of the constraints imposed by the complex ploidy of this crop. Sugarcane cultivars are interspecific hybrids between Saccharum officinarum and Saccharum spontaneum. S. officinarum is an octoploid with 2n = 80 chromosomes while S. spontaneum has 2n = 40 to 128 chromosomes and ploidy varying from 5 to 16. The hybrid genome is composed of 70-80% S. officinaram and 5-20% S. spontaneum chromosomes and a small proportion of recombinants. Sequencing the genome of this complex crop may help identify useful genes, either per se or through comparative genomics using closely related grasses. The construction and sequencing of a bacterial artificial chromosome (BAC) library of an elite commercial variety of sugarcane could help assembly the sugarcane genome., Results: A BAC library designated SS_SBa was constructed with DNA isolated from the commercial sugarcane variety SP80-3280. The library contains 36,864 clones with an average insert size of 125 Kb, 88% of which has inserts larger than 90 Kb. Based on the estimated genome size of 760-930 Mb, the library exhibits 5-6 times coverage the monoploid sugarcane genome. Bidirectional BAC end sequencing (BESs) from a random sample of 192 BAC clones sampled genes and repetitive elements of the sugarcane genome. Forty-five per cent of the total BES nucleotides represents repetitive elements, 83% of which belonging to LTR retrotransposons. Alignment of BESs corresponding to 42 BACs to the genome sequence of the 10 sorghum chromosomes revealed regions of microsynteny, with expansions and contractions of sorghum genome regions relative to the sugarcane BAC clones. In general, the sampled sorghum genome regions presented an average 29% expansion in relation to the sugarcane syntenic BACs., Conclusion: The SS_SBa BAC library represents a new resource for sugarcane genome sequencing. An analysis of insert size, genome coverage and orthologous alignment with the sorghum genome revealed that the library presents whole genome coverage. The comparison of syntenic regions of the sorghum genome to 42 SS_SBa BES pairs revealed that the sorghum genome is expanded in relation to the sugarcane genome.

Published

2012

29. Spatio-temporal patterns of genome evolution in allotetraploid species of the genus Oryza.

Author

Ammiraju JS, Fan C, Yu Y, Song X, Cranston KA, Pontaroli AC, Lu F, Sanyal A, Jiang N, Rambo T, Currie J, Collura K, Talag J, Bennetzen JL, Chen M, Jackson S, and Wing RA

Subjects

Chromosomes, Artificial, Bacterial, Genes, Plant, Molecular Sequence Data, Phylogeny, Retroelements, Evolution, Molecular, Genome, Plant, Oryza genetics, Tetraploidy

Abstract

Despite knowledge that polyploidy is widespread and a major evolutionary force in flowering plant diversification, detailed comparative molecular studies on polyploidy have been confined to only a few species and families. The genus Oryza is composed of 23 species that are classified into ten distinct 'genome types' (six diploid and four polyploid), and is emerging as a powerful new model system to study polyploidy. Here we report the identification, sequence and comprehensive comparative annotation of eight homoeologous genomes from a single orthologous region (Adh1-Adh2) from four allopolyploid species representing each of the known Oryza genome types (BC, CD, HJ and KL). Detailed comparative phylogenomic analyses of these regions within and across species and ploidy levels provided several insights into the spatio-temporal dynamics of genome organization and evolution of this region in 'natural' polyploids of Oryza. The major findings of this study are that: (i) homoeologous genomic regions within the same nucleus experience both independent and parallel evolution, (ii) differential lineage-specific selection pressures do not occur between polyploids and their diploid progenitors, (iii) there have been no dramatic structural changes relative to the diploid ancestors, (iv) a variation in the molecular evolutionary rate exists between the two genomes in the BC complex species even though the BC and CD polyploid species appear to have arisen <2 million years ago, and (v) there are no clear distinctions in the patterns of genome evolution in the diploid versus polyploid species., (© 2010 The Authors. Journal compilation © 2010 Blackwell Publishing Ltd.)

Published

2010

30. The B73 maize genome: complexity, diversity, and dynamics.

Author

Schnable PS, Ware D, Fulton RS, Stein JC, Wei F, Pasternak S, Liang C, Zhang J, Fulton L, Graves TA, Minx P, Reily AD, Courtney L, Kruchowski SS, Tomlinson C, Strong C, Delehaunty K, Fronick C, Courtney B, Rock SM, Belter E, Du F, Kim K, Abbott RM, Cotton M, Levy A, Marchetto P, Ochoa K, Jackson SM, Gillam B, Chen W, Yan L, Higginbotham J, Cardenas M, Waligorski J, Applebaum E, Phelps L, Falcone J, Kanchi K, Thane T, Scimone A, Thane N, Henke J, Wang T, Ruppert J, Shah N, Rotter K, Hodges J, Ingenthron E, Cordes M, Kohlberg S, Sgro J, Delgado B, Mead K, Chinwalla A, Leonard S, Crouse K, Collura K, Kudrna D, Currie J, He R, Angelova A, Rajasekar S, Mueller T, Lomeli R, Scara G, Ko A, Delaney K, Wissotski M, Lopez G, Campos D, Braidotti M, Ashley E, Golser W, Kim H, Lee S, Lin J, Dujmic Z, Kim W, Talag J, Zuccolo A, Fan C, Sebastian A, Kramer M, Spiegel L, Nascimento L, Zutavern T, Miller B, Ambroise C, Muller S, Spooner W, Narechania A, Ren L, Wei S, Kumari S, Faga B, Levy MJ, McMahan L, Van Buren P, Vaughn MW, Ying K, Yeh CT, Emrich SJ, Jia Y, Kalyanaraman A, Hsia AP, Barbazuk WB, Baucom RS, Brutnell TP, Carpita NC, Chaparro C, Chia JM, Deragon JM, Estill JC, Fu Y, Jeddeloh JA, Han Y, Lee H, Li P, Lisch DR, Liu S, Liu Z, Nagel DH, McCann MC, SanMiguel P, Myers AM, Nettleton D, Nguyen J, Penning BW, Ponnala L, Schneider KL, Schwartz DC, Sharma A, Soderlund C, Springer NM, Sun Q, Wang H, Waterman M, Westerman R, Wolfgruber TK, Yang L, Yu Y, Zhang L, Zhou S, Zhu Q, Bennetzen JL, Dawe RK, Jiang J, Jiang N, Presting GG, Wessler SR, Aluru S, Martienssen RA, Clifton SW, McCombie WR, Wing RA, and Wilson RK

Subjects

Base Sequence, Centromere genetics, Chromosome Mapping, Chromosomes, Plant genetics, Crops, Agricultural genetics, DNA Copy Number Variations, DNA Methylation, DNA Transposable Elements, DNA, Plant genetics, Genes, Plant, Inbreeding, MicroRNAs genetics, Molecular Sequence Data, Ploidies, RNA, Plant genetics, Recombination, Genetic, Retroelements, Genetic Variation, Genome, Plant, Sequence Analysis, DNA, Zea mays genetics

Abstract

We report an improved draft nucleotide sequence of the 2.3-gigabase genome of maize, an important crop plant and model for biological research. Over 32,000 genes were predicted, of which 99.8% were placed on reference chromosomes. Nearly 85% of the genome is composed of hundreds of families of transposable elements, dispersed nonuniformly across the genome. These were responsible for the capture and amplification of numerous gene fragments and affect the composition, sizes, and positions of centromeres. We also report on the correlation of methylation-poor regions with Mu transposon insertions and recombination, and copy number variants with insertions and/or deletions, as well as how uneven gene losses between duplicated regions were involved in returning an ancient allotetraploid to a genetically diploid state. These analyses inform and set the stage for further investigations to improve our understanding of the domestication and agricultural improvements of maize.

Published

2009

31. Methylation-sensitive linking libraries enhance gene-enriched sequencing of complex genomes and map DNA methylation domains.

Author

Nelson W, Luo M, Ma J, Estep M, Estill J, He R, Talag J, Sisneros N, Kudrna D, Kim H, Ammiraju JS, Collura K, Bharti AK, Messing J, Wing RA, SanMiguel P, Bennetzen JL, and Soderlund C

Subjects

Chromosomes, Artificial, Bacterial, DNA, Plant genetics, Epigenesis, Genetic, Gene Library, Genomics methods, Sequence Alignment, Sequence Analysis, DNA methods, Chromosome Mapping methods, DNA Methylation, Genome, Plant, Zea mays genetics

Abstract

Background: Many plant genomes are resistant to whole-genome assembly due to an abundance of repetitive sequence, leading to the development of gene-rich sequencing techniques. Two such techniques are hypomethylated partial restriction (HMPR) and methylation spanning linker libraries (MSLL). These libraries differ from other gene-rich datasets in having larger insert sizes, and the MSLL clones are designed to provide reads localized to "epigenetic boundaries" where methylation begins or ends., Results: A large-scale study in maize generated 40,299 HMPR sequences and 80,723 MSLL sequences, including MSLL clones exceeding 100 kb. The paired end reads of MSLL and HMPR clones were shown to be effective in linking existing gene-rich sequences into scaffolds. In addition, it was shown that the MSLL clones can be used for anchoring these scaffolds to a BAC-based physical map. The MSLL end reads effectively identified epigenetic boundaries, as indicated by their preferential alignment to regions upstream and downstream from annotated genes. The ability to precisely map long stretches of fully methylated DNA sequence is a unique outcome of MSLL analysis, and was also shown to provide evidence for errors in gene identification. MSLL clones were observed to be significantly more repeat-rich in their interiors than in their end reads, confirming the correlation between methylation and retroelement content. Both MSLL and HMPR reads were found to be substantially gene-enriched, with the SalI MSLL libraries being the most highly enriched (31% align to an EST contig), while the HMPR clones exhibited exceptional depletion of repetitive DNA (to approximately 11%). These two techniques were compared with other gene-enrichment methods, and shown to be complementary., Conclusion: MSLL technology provides an unparalleled approach for mapping the epigenetic status of repetitive blocks and for identifying sequences mis-identified as genes. Although the types and natures of epigenetic boundaries are barely understood at this time, MSLL technology flags both approximate boundaries and methylated genes that deserve additional investigation. MSLL and HMPR sequences provide a valuable resource for maize genome annotation, and are a uniquely valuable complement to any plant genome sequencing project. In order to make these results fully accessible to the community, a web display was developed that shows the alignment of MSLL, HMPR, and other gene-rich sequences to the BACs; this display is continually updated with the latest ESTs and BAC sequences.

Published

2008

32. Dynamic evolution of oryza genomes is revealed by comparative genomic analysis of a genus-wide vertical data set.

Author

Ammiraju JS, Lu F, Sanyal A, Yu Y, Song X, Jiang N, Pontaroli AC, Rambo T, Currie J, Collura K, Talag J, Fan C, Goicoechea JL, Zuccolo A, Chen J, Bennetzen JL, Chen M, Jackson S, and Wing RA

Subjects

Molecular Sequence Data, Oryza classification, Phylogeny, Plant Proteins genetics, Plant Proteins physiology, Evolution, Molecular, Genome, Plant genetics, Genomics methods, Oryza genetics

Abstract

Oryza (23 species; 10 genome types) contains the world's most important food crop - rice. Although the rice genome serves as an essential tool for biological research, little is known about the evolution of the other Oryza genome types. They contain a historical record of genomic changes that led to diversification of this genus around the world as well as an untapped reservoir of agriculturally important traits. To investigate the evolution of the collective Oryza genome, we sequenced and compared nine orthologous genomic regions encompassing the Adh1-Adh2 genes (from six diploid genome types) with the rice reference sequence. Our analysis revealed the architectural complexities and dynamic evolution of this region that have occurred over the past approximately 15 million years. Of the 46 intact genes and four pseudogenes in the japonica genome, 38 (76%) fell into eight multigene families. Analysis of the evolutionary history of each family revealed independent and lineage-specific gain and loss of gene family members as frequent causes of synteny disruption. Transposable elements were shown to mediate massive replacement of intergenic space (>95%), gene disruption, and gene/gene fragment movement. Three cases of long-range structural variation (inversions/deletions) spanning several hundred kilobases were identified that contributed significantly to genome diversification.

Published

2008

33. Evolutionary dynamics of an ancient retrotransposon family provides insights into evolution of genome size in the genus Oryza.

Author

Ammiraju JS, Zuccolo A, Yu Y, Song X, Piegu B, Chevalier F, Walling JG, Ma J, Talag J, Brar DS, SanMiguel PJ, Jiang N, Jackson SA, Panaud O, and Wing RA

Subjects

Genes, Plant, Phylogeny, Plant Proteins, Terminal Repeat Sequences, Evolution, Molecular, Genome, Plant, Multigene Family genetics, Oryza genetics, Retroelements genetics

Abstract

Long terminal repeat (LTR) retrotransposons constitute a significant portion of most eukaryote genomes and can dramatically change genome size and organization. Although LTR retrotransposon content variation is well documented, the dynamics of genomic flux caused by their activity are poorly understood on an evolutionary time scale. This is primarily because of the lack of an experimental system composed of closely related species whose divergence times are within the limits of the ability to detect ancestrally related retrotransposons. The genus Oryza, with 24 species, ten genome types, different ploidy levels and over threefold genome size variation, constitutes an ideal experimental system to explore genus-level transposon dynamics. Here we present data on the discovery and characterization of an LTR retrotransposon family named RWG in the genus Oryza. Comparative analysis of transposon content (approximately 20 to 27,000 copies) and transpositional history of this family across the genus revealed a broad spectrum of independent and lineage-specific changes that have implications for the evolution of genome size and organization. In particular, we provide evidence that the basal GG genome of Oryza (O. granulata) has expanded by nearly 25% by a burst of the RWG lineage Gran3 subsequent to speciation. Finally we describe the recent evolutionary origin of Dasheng, a large retrotransposon derivative of the RWG family, specifically found in the A, B and C genome lineages of Oryza.

Published

2007

34. Transposable element distribution, abundance and role in genome size variation in the genus Oryza.

Author

Zuccolo A, Sebastian A, Talag J, Yu Y, Kim H, Collura K, Kudrna D, and Wing RA

Subjects

Evolution, Molecular, Phylogeny, Terminal Repeat Sequences, DNA Transposable Elements, Genetic Variation, Genome, Plant, Oryza genetics

Abstract

Background: The genus Oryza is composed of 10 distinct genome types, 6 diploid and 4 polyploid, and includes the world's most important food crop - rice (Oryza sativa [AA]). Genome size variation in the Oryza is more than 3-fold and ranges from 357 Mbp in Oryza glaberrima [AA] to 1283 Mbp in the polyploid Oryza ridleyi [HHJJ]. Because repetitive elements are known to play a significant role in genome size variation, we constructed random sheared small insert genomic libraries from 12 representative Oryza species and conducted a comprehensive study of the repetitive element composition, distribution and phylogeny in this genus. Particular attention was paid to the role played by the most important classes of transposable elements (Long Terminal Repeats Retrotransposons, Long interspersed Nuclear Elements, helitrons, DNA transposable elements) in shaping these genomes and in their contributing to genome size variation., Results: We identified the elements primarily responsible for the most strikingly genome size variation in Oryza. We demonstrated how Long Terminal Repeat retrotransposons belonging to the same families have proliferated to very different extents in various species. We also showed that the pool of Long Terminal Repeat Retrotransposons is substantially conserved and ubiquitous throughout the Oryza and so its origin is ancient and its existence predates the speciation events that originated the genus. Finally we described the peculiar behavior of repeats in the species Oryza coarctata [HHKK] whose placement in the Oryza genus is controversial., Conclusion: Long Terminal Repeat retrotransposons are the major component of the Oryza genomes analyzed and, along with polyploidization, are the most important contributors to the genome size variation across the Oryza genus. Two families of Ty3-gypsy elements (RIRE2 and Atlantys) account for a significant portion of the genome size variations present in the Oryza genus.

Published

2007

35. The Oryza bacterial artificial chromosome library resource: construction and analysis of 12 deep-coverage large-insert BAC libraries that represent the 10 genome types of the genus Oryza.

Author

Ammiraju JS, Luo M, Goicoechea JL, Wang W, Kudrna D, Mueller C, Talag J, Kim H, Sisneros NB, Blackmon B, Fang E, Tomkins JB, Brar D, MacKill D, McCouch S, Kurata N, Lambert G, Galbraith DW, Arumuganathan K, Rao K, Walling JG, Gill N, Yu Y, SanMiguel P, Soderlund C, Jackson S, and Wing RA

Subjects

Base Sequence, Molecular Sequence Data, Sequence Analysis, DNA methods, Chromosomes, Artificial, Bacterial, Genome, Plant genetics, Genomic Library, Oryza genetics, Retroelements genetics

Abstract

Rice (Oryza sativa L.) is the most important food crop in the world and a model system for plant biology. With the completion of a finished genome sequence we must now functionally characterize the rice genome by a variety of methods, including comparative genomic analysis between cereal species and within the genus Oryza. Oryza contains two cultivated and 22 wild species that represent 10 distinct genome types. The wild species contain an essentially untapped reservoir of agriculturally important genes that must be harnessed if we are to maintain a safe and secure food supply for the 21st century. As a first step to functionally characterize the rice genome from a comparative standpoint, we report the construction and analysis of a comprehensive set of 12 BAC libraries that represent the 10 genome types of Oryza. To estimate the number of clones required to generate 10 genome equivalent BAC libraries we determined the genome sizes of nine of the 12 species using flow cytometry. Each library represents a minimum of 10 genome equivalents, has an average insert size range between 123 and 161 kb, an average organellar content of 0.4%-4.1% and nonrecombinant content between 0% and 5%. Genome coverage was estimated mathematically and empirically by hybridization and extensive contig and BAC end sequence analysis. A preliminary analysis of BAC end sequences of clones from these libraries indicated that LTR retrotransposons are the predominant class of repeat elements in Oryza and a roughly linear relationship of these elements with genome size was observed.

Published

2006

36. Utilization of a zebra finch BAC library to determine the structure of an avian androgen receptor genomic region.

Author

Luo M, Yu Y, Kim H, Kudrna D, Itoh Y, Agate RJ, Melamed E, Goicoechea JL, Talag J, Mueller C, Wang W, Currie J, Sisneros NB, Wing RA, and Arnold AP

Subjects

Animals, Base Sequence, Behavior, Animal physiology, Chickens genetics, Evolution, Molecular, Female, Molecular Sequence Data, Chromosomes, Artificial, Bacterial genetics, Finches genetics, Genomic Library, Open Reading Frames genetics, Receptors, Androgen genetics

Abstract

The zebra finch (Taeniopygia guttata) is an important model organism for studying behavior, neuroscience, avian biology, and evolution. To support the study of its genome, we constructed a BAC library (TG&#95;&#95;Ba) using DNA from livers of females. The BAC library consists of 147,456 clones with 98% containing inserts of an average size of 134 kb and represents 15.5 haploid genome equivalents. By sequencing a whole BAC, a full-length androgen receptor open reading frame was identified, the first in an avian species. Comparison of BAC end sequences and the whole BAC sequence with the chicken genome draft sequence showed a high degree of conserved synteny between the zebra finch and the chicken genome.

Published

2006