Your search keyword '"Ramirez-Gonzalez, R"' showing total 20 results

1. The transcriptional landscape of polyploid wheat

Author

International Wheat Genome Sequencing Consortium, Ramírez-González, R. H., Borrill, P., Lang, D., Harrington, S. A., Brinton, J., Venturini, L., Davey, M., Jacobs, J., van Ex, F., Pasha, A., Khedikar, Y., Robinson, S. J., Cory, A. T., Florio, T., Concia, L., Juery, C., Schoonbeek, H., Steuernagel, B., Xiang, D., Ridout, C. J., Chalhoub, B., Mayer, K. F. X., Benhamed, M., Latrasse, D., Bendahmane, A., Wulff, B. B. H., Appels, R., Tiwari, V., Datla, R., Choulet, F., Pozniak, C. J., Provart, N. J., Sharpe, A. G., Paux, E., Spannagl, M., Bräutigam, A., and Uauy, C.

Published

2018

2. Mapping a Type 1 FHB resistance on chromosome 4AS of Triticum macha and deployment in combination with two Type 2 resistances

Author

Burt, C., Steed, A., Gosman, N., Lemmens, M., Bird, N., Ramirez-Gonzalez, R., Holdgate, S., and Nicholson, P.

Published

2015

3. Ancient hybridizations among the ancestral genomes of bread wheat

Author

Marcussen, T., Sandve, S., Heier, L., Spannagl, M., Pfeifer, M., Jakobsen, K., Wulff, B., Steuernagel, B., Mayer, K., Olsen, O.-A., Rogers, J., Dole el, J., Pozniak, C., Eversole, K., Feuillet, C., Gill, B., Friebe, B., Lukaszewski, A., Sourdille, Pierre, Endo, T., Kubalakova, M., ihalikova, J., Dubska, Z., Vrana, J., perkova, R., imkova, H., Febrer, M., Clissold, L., McLay, K., Singh, K., Chhuneja, P., Singh, N., Khurana, J., Akhunov, E., Choulet, F., Alberti, A., Barbe, Valérie, Wincker, P., Kanamori, H., Kobayashi, F., Itoh, T., Matsumoto, T., Sakai, H., Tanaka, T., Wu, J., Ogihara, Y., Handa, H., Maclachlan, P., Sharpe, A., Klassen, D., Edwards, D., Batley, J., Lien, S., Caccamo, M., Ayling, S., Ramirez-Gonzalez, R., Clavijo, B., Wright, J., Martis, M., Mascher, M., Chapman, J., Poland, J., Scholz, U., Barry, K., Waugh, R., Rokhsar, D., Muehlbauer, G., Stein, N., Gundlach, H., Zytnicki, M., Jamilloux, V., Quesneville, H., Wicker, T., Faccioli, P., Colaiacovo, M., Stanca, A., Budak, H., Cattivelli, L., Glover, N., Pingault, L., Paux, E., Sharma, S., Appels, R., Bellgard, M., Chapman, B., Nussbaumer, T., Bader, K., Rimbert, H., Wang, S., Knox, R., Kilian, A., Alaux, M., Alfama, F., Couderc, L., Guilhot, N., Viseux, C., Loaec, M., Keller, B., Praud, S., Norwegian University of Life Sciences (NMBU), Helmholtz-Zentrum München (HZM), Helmholtz Centre Munich, Plant Genome and Systems Biology, Helmholtz Zentrum München, German Research Center for Environmental Health - Helmholtz Center München (GmbH), John Innes Centre [Norwich], Eversole Associates, Bayer Corporation, Génétique Diversité et Ecophysiologie des Céréales (GDEC), Institut National de la Recherche Agronomique (INRA)-Université Blaise Pascal - Clermont-Ferrand 2 (UBP), Institute of Experimental Botany of the Czech Academy of Sciences (IEB / CAS), Czech Academy of Sciences [Prague] (CAS), Laboratoire d'hydrodynamique (LadHyX), École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS), Laboratoire Chrono-environnement - CNRS - UBFC (UMR 6249) (LCE), Centre National de la Recherche Scientifique (CNRS)-Université de Franche-Comté (UFC), Université Bourgogne Franche-Comté [COMUE] (UBFC)-Université Bourgogne Franche-Comté [COMUE] (UBFC), Istituto per la Microelettronica e Microsistemi [Catania] (IMM), Consiglio Nazionale delle Ricerche (CNR), Institut de Génomique d'Evry (IG), Institut de Biologie François JACOB (JACOB), 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)-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)-Université Paris-Saclay, Structure et évolution des génomes (SEG), CNS-Université d'Évry-Val-d'Essonne (UEVE)-Centre National de la Recherche Scientifique (CNRS), Seismological Laboratory, California Institute of Technology (CALTECH), Japan Agency for Marine-Earth Science and Technology (JAMSTEC), Department of Physics, University of Tokyo, The University of Tokyo (UTokyo), National Institute for Environmental Studies (NIES), Université de Lille, Sciences et Technologies, The University of Western Australia (UWA), Leibniz Institute of Plant Genetics and Crop Plant Research, Unité de Recherche Génomique Info (URGI), Institut National de la Recherche Agronomique (INRA), Laboratoire Evolution, Génomes et Spéciation (LEGS), Centre National de la Recherche Scientifique (CNRS), Consiglio per la Ricerca e Sperimentazione in Agricoltura, Climate Research Division [Toronto], Environment and Climate Change Canada, School of Biosciences, University of Birmingham [Birmingham], Centre for Comparative Genomics, Murdoch University, Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Plant Genome and Systems Biology, Helmholtz Diabetes Center at Helmholtz Zentrum, BIOGEMMA, Centre de Recherche de Chappes, Diversity Arrays Technology Pty Ltd (DArT P/L), Institute of plant biology, Universität Zürich [Zürich] = University of Zurich (UZH), Research Council of Norway 199387Biotechnology and Biological Sciences Research Council (BBSRC) BB/J003166/1,BBS/E/T/000PR6193National Science Foundation (NSF) - Directorate for Computer & Information Science & Engineering (CISE) 1126709, Helmholtz Zentrum München = German Research Center for Environmental Health, Biotechnology and Biological Sciences Research Council (BBSRC), Laboratoire Chrono-environnement (UMR 6249) (LCE), National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), Université Paris-Saclay-Institut de Biologie François JACOB (JACOB), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), University of Oslo (UiO), The Sainsbury Laboratory (TSL), and Norwegian Research Council 199387

Subjects

0106 biological sciences, TRITICUM, GENES, [SDV]Life Sciences [q-bio], Biology, Genes, Plant, 01 natural sciences, Genome, Evolution, Molecular, Polyploidy, [SDV.GEN.GPL]Life Sciences [q-bio]/Genetics/Plants genetics, 03 medical and health sciences, Polyploid, Phylogenetics, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Gene, DRAFT GENOME, Phylogeny, AEGILOPS-TAUSCHII, 030304 developmental biology, 2. Zero hunger, Genetics, 0303 health sciences, [SDV.GEN]Life Sciences [q-bio]/Genetics, Multidisciplinary, Phylogenetic tree, A-GENOME, myr, food and beverages, Bread, EVOLUTION, ALIGNMENT, DOMESTICATION, Hybridization, Genetic, Hybrid speciation, Ploidy, Genome, Plant, 010606 plant biology & botany, PACKAGE

Abstract

International audience; The allohexaploid bread wheat genome consists of three closely related subgenomes (A, B, and D), but a clear understanding of their phylogenetic history has been lacking. We used genome assemblies of bread wheat and five diploid relatives to analyze genome-wide samples of gene trees, as well as to estimate evolutionary relatedness and divergence times. We show that the A and B genomes diverged from a common ancestor similar to 7 million years ago and that these genomes gave rise to the D genome through homoploid hybrid speciation 1 to 2 million years later. Our findings imply that the present-day bread wheat genome is a product of multiple rounds of hybrid speciation (homoploid and polyploid) and lay the foundation for a new framework for understanding the wheat genome as a multilevel phylogenetic mosaic.

Published

2014

4. Analyses of pig genomes provide insight into porcine demography and evolution

Author

Groenen, M. A., Archibald, A. L., Uenishi, H., Tuggle, C. K., Takeuchi, Y., Rothschild, M. F., Rogel-Gaillard, C., Park, C., Milan, D., Megens, H. J., Li, S., Larkin, D. M., Kim, H., Frantz, L. A., Caccamo, M., Ahn, H., Aken, B. L., Anselmo, A., Anthon, C., Auvil, L., Badaoui, B., Beattie, C. W., Bendixen, C., Berman, D., Blecha, F., Blomberg, Jonas, Bolund, L., Bosse, M., Botti, S., Bujie, Z., Byström, M., Capitanu, B., Carvalho-Silva, D., Chardon, P., Chen, C., Cheng, R., Choi, S. H., Chow, W., Clark, R. C., Clee, C., Crooijmans, R. P., Dawson, H. D., Dehais, P., De Sapio, F., Dibbits, B., Drou, N., Du, Z. Q., Eversole, K., Fadista, J., Fairley, S., Faraut, T., Faulkner, G. J., Fowler, K. E., Fredholm, M., Fritz, E., Gilbert, J. G., Giuffra, E., Gorodkin, J., Griffin, D. K., Harrow, J. L., Hayward, Alexander, Howe, K., Hu, Z. L., Humphray, S. J., Hunt, T., Hornshoj, H., Jeon, J. T., Jern, Patric, Jones, M., Jurka, J., Kanamori, H., Kapetanovic, R., Kim, J., Kim, J. H., Kim, K. W., Kim, T. H., Larson, G., Lee, K., Lee, K. T., Leggett, R., Lewin, H. A., Li, Y., Liu, W., Loveland, J. E., Lu, Y., Lunney, J. K., Ma, J., Madsen, O., Mann, K., Matthews, L., McLaren, S., Morozumi, T., Murtaugh, M. P., Narayan, J., Nguyen, D. T., Ni, P., Oh, S. J., Onteru, S., Panitz, F., Park, E. W., Park, H. S., Pascal, G., Paudel, Y., Perez-Enciso, M., Ramirez-Gonzalez, R., Reecy, J. M., Rodriguez-Zas, S., Rohrer, G. A., Rund, L., Sang, Y., Schachtschneider, K., Schraiber, J. G., Schwartz, J., Scobie, L., Scott, C., Searle, S., Servin, B., Southey, B. R., Sperber, Göran, Stadler, P., Sweedler, J. V., Tafer, H., Thomsen, B., Wali, R., Wang, J., White, S., Xu, X., Yerle, M., Zhang, G., Zhang, J., Zhao, S., Rogers, J., Churcher, C., Schook, L. B., Groenen, M. A., Archibald, A. L., Uenishi, H., Tuggle, C. K., Takeuchi, Y., Rothschild, M. F., Rogel-Gaillard, C., Park, C., Milan, D., Megens, H. J., Li, S., Larkin, D. M., Kim, H., Frantz, L. A., Caccamo, M., Ahn, H., Aken, B. L., Anselmo, A., Anthon, C., Auvil, L., Badaoui, B., Beattie, C. W., Bendixen, C., Berman, D., Blecha, F., Blomberg, Jonas, Bolund, L., Bosse, M., Botti, S., Bujie, Z., Byström, M., Capitanu, B., Carvalho-Silva, D., Chardon, P., Chen, C., Cheng, R., Choi, S. H., Chow, W., Clark, R. C., Clee, C., Crooijmans, R. P., Dawson, H. D., Dehais, P., De Sapio, F., Dibbits, B., Drou, N., Du, Z. Q., Eversole, K., Fadista, J., Fairley, S., Faraut, T., Faulkner, G. J., Fowler, K. E., Fredholm, M., Fritz, E., Gilbert, J. G., Giuffra, E., Gorodkin, J., Griffin, D. K., Harrow, J. L., Hayward, Alexander, Howe, K., Hu, Z. L., Humphray, S. J., Hunt, T., Hornshoj, H., Jeon, J. T., Jern, Patric, Jones, M., Jurka, J., Kanamori, H., Kapetanovic, R., Kim, J., Kim, J. H., Kim, K. W., Kim, T. H., Larson, G., Lee, K., Lee, K. T., Leggett, R., Lewin, H. A., Li, Y., Liu, W., Loveland, J. E., Lu, Y., Lunney, J. K., Ma, J., Madsen, O., Mann, K., Matthews, L., McLaren, S., Morozumi, T., Murtaugh, M. P., Narayan, J., Nguyen, D. T., Ni, P., Oh, S. J., Onteru, S., Panitz, F., Park, E. W., Park, H. S., Pascal, G., Paudel, Y., Perez-Enciso, M., Ramirez-Gonzalez, R., Reecy, J. M., Rodriguez-Zas, S., Rohrer, G. A., Rund, L., Sang, Y., Schachtschneider, K., Schraiber, J. G., Schwartz, J., Scobie, L., Scott, C., Searle, S., Servin, B., Southey, B. R., Sperber, Göran, Stadler, P., Sweedler, J. V., Tafer, H., Thomsen, B., Wali, R., Wang, J., White, S., Xu, X., Yerle, M., Zhang, G., Zhang, J., Zhao, S., Rogers, J., Churcher, C., and Schook, L. B.

Abstract

For 10,000 years pigs and humans have shared a close and complex relationship. From domestication to modern breeding practices, humans have shaped the genomes of domestic pigs. Here we present the assembly and analysis of the genome sequence of a female domestic Duroc pig (Sus scrofa) and a comparison with the genomes of wild and domestic pigs from Europe and Asia. Wild pigs emerged in South East Asia and subsequently spread across Eurasia. Our results reveal a deep phylogenetic split between European and Asian wild boars approximately 1 million years ago, and a selective sweep analysis indicates selection on genes involved in RNA processing and regulation. Genes associated with immune response and olfaction exhibit fast evolution. Pigs have the largest repertoire of functional olfactory receptor genes, reflecting the importance of smell in this scavenging animal. The pig genome sequence provides an important resource for further improvements of this important livestock species, and our identification of many putative disease-causing variants extends the potential of the pig as a biomedical model.

Published

2012

5. Biogem: an effective tool-based approach for scaling up open source software development in bioinformatics

Author

Bonnal, RJP, Aerts, J, Githinji, G, Goto, N, MacLean, D, Miller, CA, Mishima, H, Pagani, M, Ramirez-Gonzalez, R, Smant, G, Strozzi, F, Syme, R, Vos, R, Wennblom, TJ, Woodcroft, BJ, Katayama, T, Prins, P, Bonnal, RJP, Aerts, J, Githinji, G, Goto, N, MacLean, D, Miller, CA, Mishima, H, Pagani, M, Ramirez-Gonzalez, R, Smant, G, Strozzi, F, Syme, R, Vos, R, Wennblom, TJ, Woodcroft, BJ, Katayama, T, and Prins, P

Abstract

SUMMARY: Biogem provides a software development environment for the Ruby programming language, which encourages community-based software development for bioinformatics while lowering the barrier to entry and encouraging best practices. Biogem, with its targeted modular and decentralized approach, software generator, tools and tight web integration, is an improved general model for scaling up collaborative open source software development in bioinformatics. AVAILABILITY: Biogem and modules are free and are OSS. Biogem runs on all systems that support recent versions of Ruby, including Linux, Mac OS X and Windows. Further information at http://www.biogems.info. A tutorial is available at http://www.biogems.info/howto.html CONTACT: bonnal@ingm.org.

Published

2012

6. Analyses of pig genomes provide insight into porcine demography and evolution

Author

Groenen, MAM, Archibald, AL, Uenishi, H, Tuggle, CK, Takeuchi, Y, Rothschild, MF, Rogel-Gaillard, C, Park, C, Milan, D, Megens, H-J, Li, S, Larkin, DM, Kim, H, Frantz, LAF, Caccamo, M, Ahn, H, Aken, BL, Anselmo, A, Anthon, C, Auvil, L, Badaoui, B, Beattie, CW, Bendixen, C, Berman, D, Blecha, F, Blomberg, J, Bolund, L, Bosse, M, Botti, S, Zhan, B, Bystrom, M, Capitanu, B, Carvalho-Silva, D, Chardon, P, Chen, C, Cheng, R, Choi, S-H, Chow, W, Clark, RC, Clee, C, Crooijmans, RPMA, Dawson, HD, Dehais, P, De Sapio, F, Dibbits, B, Drou, N, Du, Z-Q, Eversole, K, Fadista, J, Fairley, S, Faraut, T, Faulkner, GJ, Fowler, KE, Fredholm, M, Fritz, E, Gilbert, JGR, Giuffra, E, Gorodkin, J, Griffin, DK, Harrow, JL, Hayward, A, Howe, K, Hu, Z-L, Humphray, SJ, Hunt, T, Hornshoj, H, Jeon, J-T, Jern, P, Jones, M, Jurka, J, Kanamori, H, Kapetanovic, R, Kim, J, Kim, J-H, Kim, K-W, Kim, T-H, Larson, G, Lee, K, Lee, K-T, Leggett, R, Lewin, HA, Li, Y, Liu, W, Loveland, JE, Lu, Y, Lunney, JK, Ma, J, Madsen, O, Mann, K, Matthews, L, McLaren, S, Morozumi, T, Murtaugh, MP, Narayan, J, Dinh, TN, Ni, P, Oh, S-J, Onteru, S, Panitz, F, Park, E-W, Park, H-S, Pascal, G, Paudel, Y, Perez-Enciso, M, Ramirez-Gonzalez, R, Reecy, JM, Rodriguez-Zas, S, Rohrer, GA, Rund, L, Sang, Y, Schachtschneider, K, Schraiber, JG, Schwartz, J, Scobie, L, Scott, C, Searle, S, Servin, B, Southey, BR, Sperber, G, Stadler, P, Sweedler, JV, Tafer, H, Thomsen, B, Wali, R, Wang, J, White, S, Xu, X, Yerle, M, Zhang, G, Zhang, J, Zhao, S, Rogers, J, Churcher, C, Schook, LB, Groenen, MAM, Archibald, AL, Uenishi, H, Tuggle, CK, Takeuchi, Y, Rothschild, MF, Rogel-Gaillard, C, Park, C, Milan, D, Megens, H-J, Li, S, Larkin, DM, Kim, H, Frantz, LAF, Caccamo, M, Ahn, H, Aken, BL, Anselmo, A, Anthon, C, Auvil, L, Badaoui, B, Beattie, CW, Bendixen, C, Berman, D, Blecha, F, Blomberg, J, Bolund, L, Bosse, M, Botti, S, Zhan, B, Bystrom, M, Capitanu, B, Carvalho-Silva, D, Chardon, P, Chen, C, Cheng, R, Choi, S-H, Chow, W, Clark, RC, Clee, C, Crooijmans, RPMA, Dawson, HD, Dehais, P, De Sapio, F, Dibbits, B, Drou, N, Du, Z-Q, Eversole, K, Fadista, J, Fairley, S, Faraut, T, Faulkner, GJ, Fowler, KE, Fredholm, M, Fritz, E, Gilbert, JGR, Giuffra, E, Gorodkin, J, Griffin, DK, Harrow, JL, Hayward, A, Howe, K, Hu, Z-L, Humphray, SJ, Hunt, T, Hornshoj, H, Jeon, J-T, Jern, P, Jones, M, Jurka, J, Kanamori, H, Kapetanovic, R, Kim, J, Kim, J-H, Kim, K-W, Kim, T-H, Larson, G, Lee, K, Lee, K-T, Leggett, R, Lewin, HA, Li, Y, Liu, W, Loveland, JE, Lu, Y, Lunney, JK, Ma, J, Madsen, O, Mann, K, Matthews, L, McLaren, S, Morozumi, T, Murtaugh, MP, Narayan, J, Dinh, TN, Ni, P, Oh, S-J, Onteru, S, Panitz, F, Park, E-W, Park, H-S, Pascal, G, Paudel, Y, Perez-Enciso, M, Ramirez-Gonzalez, R, Reecy, JM, Rodriguez-Zas, S, Rohrer, GA, Rund, L, Sang, Y, Schachtschneider, K, Schraiber, JG, Schwartz, J, Scobie, L, Scott, C, Searle, S, Servin, B, Southey, BR, Sperber, G, Stadler, P, Sweedler, JV, Tafer, H, Thomsen, B, Wali, R, Wang, J, White, S, Xu, X, Yerle, M, Zhang, G, Zhang, J, Zhao, S, Rogers, J, Churcher, C, and Schook, LB

Abstract

For 10,000 years pigs and humans have shared a close and complex relationship. From domestication to modern breeding practices, humans have shaped the genomes of domestic pigs. Here we present the assembly and analysis of the genome sequence of a female domestic Duroc pig (Sus scrofa) and a comparison with the genomes of wild and domestic pigs from Europe and Asia. Wild pigs emerged in South East Asia and subsequently spread across Eurasia. Our results reveal a deep phylogenetic split between European and Asian wild boars ∼1 million years ago, and a selective sweep analysis indicates selection on genes involved in RNA processing and regulation. Genes associated with immune response and olfaction exhibit fast evolution. Pigs have the largest repertoire of functional olfactory receptor genes, reflecting the importance of smell in this scavenging animal. The pig genome sequence provides an important resource for further improvements of this important livestock species, and our identification of many putative disease-causing variants extends the potential of the pig as a biomedical model.

Published

2012

7. Biogem: An effective tool-based approach for scaling up open source software development in bioinformatics

Author

Bonnal, R., Aerts, J., Githinji, G., Goto, N., Maclean, D., Miller, C., Mishima, H., Pagani, M., Ramirez-gonzalez, R., Smant, G., Strozzi, F., Syme, Robert, Vos, R., Wennblom, T., Woodcroft, B., Katayama, T., Prins, P., Bonnal, R., Aerts, J., Githinji, G., Goto, N., Maclean, D., Miller, C., Mishima, H., Pagani, M., Ramirez-gonzalez, R., Smant, G., Strozzi, F., Syme, Robert, Vos, R., Wennblom, T., Woodcroft, B., Katayama, T., and Prins, P.

Abstract

Summary: Biogem provides a software development environment for the Ruby programming language, which encourages community-based software development for bioinformatics while lowering the barrier to entry and encouraging best practices. Biogem, with its targeted modular and decentralized approach, software generator, tools and tight web integration, is an improved general model for scaling up collaborative open source software development in bioinformatics. © The Author(s) 2012. Published by Oxford University Press.

Published

2012

8. Assemblathon 1: A competitive assessment of de novo short read assembly methods

Author

Earl, D, Bradnam, K, St. John, J, Darling, A, Lin, D, Fass, J, Yu, HOK, Buffalo, V, Zerbino, DR, Diekhans, M, Nguyen, N, Ariyaratne, PN, Sung, WK, Ning, Z, Haimel, M, Simpson, JT, Fonseca, NA, Birol, I, Docking, TR, Ho, IY, Rokhsar, DS, Chikhi, R, Lavenier, D, Chapuis, G, Naquin, D, Maillet, N, Schatz, MC, Kelley, DR, Phillippy, AM, Koren, S, Yang, SP, Wu, W, Chou, WC, Srivastava, A, Shaw, TI, Ruby, JG, Skewes-Cox, P, Betegon, M, Dimon, MT, Solovyev, V, Seledtsov, I, Kosarev, P, Vorobyev, D, Ramirez-Gonzalez, R, Leggett, R, MacLean, D, Xia, F, Luo, R, Li, Z, Xie, Y, Liu, B, Gnerre, S, MacCallum, I, Przybylski, D, Ribeiro, FJ, Sharpe, T, Hall, G, Kersey, PJ, Durbin, R, Jackman, SD, Chapman, JA, Huang, X, DeRisi, JL, Caccamo, M, Li, Y, Jaffe, DB, Green, RE, Haussler, D, Korf, I, Paten, B, Earl, D, Bradnam, K, St. John, J, Darling, A, Lin, D, Fass, J, Yu, HOK, Buffalo, V, Zerbino, DR, Diekhans, M, Nguyen, N, Ariyaratne, PN, Sung, WK, Ning, Z, Haimel, M, Simpson, JT, Fonseca, NA, Birol, I, Docking, TR, Ho, IY, Rokhsar, DS, Chikhi, R, Lavenier, D, Chapuis, G, Naquin, D, Maillet, N, Schatz, MC, Kelley, DR, Phillippy, AM, Koren, S, Yang, SP, Wu, W, Chou, WC, Srivastava, A, Shaw, TI, Ruby, JG, Skewes-Cox, P, Betegon, M, Dimon, MT, Solovyev, V, Seledtsov, I, Kosarev, P, Vorobyev, D, Ramirez-Gonzalez, R, Leggett, R, MacLean, D, Xia, F, Luo, R, Li, Z, Xie, Y, Liu, B, Gnerre, S, MacCallum, I, Przybylski, D, Ribeiro, FJ, Sharpe, T, Hall, G, Kersey, PJ, Durbin, R, Jackman, SD, Chapman, JA, Huang, X, DeRisi, JL, Caccamo, M, Li, Y, Jaffe, DB, Green, RE, Haussler, D, Korf, I, and Paten, B

Abstract

Low-cost short read sequencing technology has revolutionized genomics, though it is only just becoming practical for the high-quality de novo assembly of a novel large genome. We describe the Assemblathon 1 competition, which aimed to comprehensively assess the state of the art in de novo assembly methods when applied to current sequencing technologies. In a collaborative effort, teams were asked to assemble a simulated Illumina HiSeq data set of an unknown, simulated diploid genome. A total of 41 assemblies from 17 different groups were received. Novel haplotype aware assessments of coverage, contiguity, structure, base calling, and copy number were made. We establish that within this benchmark: (1) It is possible to assemble the genome to a high level of coverage and accuracy, and that (2) large differences exist between the assemblies, suggesting room for further improvements in current methods. The simulated benchmark, including the correct answer, the assemblies, and the code that was used to evaluate the assemblies is now public and freely available from http://www.assemblathon.org/. © 2011 by Cold Spring Harbor Laboratory Press.

Published

2011

9. Wheat in vivo RNA structure landscape reveals a prevalent role of RNA structure in modulating translational subgenome expression asymmetry.

Author

Yang X, Yu H, Sun W, Ding L, Li J, Cheema J, Ramirez-Gonzalez R, Zhao X, Martín AC, Lu F, Liu B, Uauy C, Ding Y, and Zhang H

Subjects

Arabidopsis genetics, Domestication, Evolution, Molecular, Gene Expression Profiling, Genome, Plant, Hybridization, Genetic, Polyploidy, Tetraploidy, Transcriptome, Gene Expression Regulation, Plant, RNA, Plant chemistry, RNA, Plant genetics, Triticum genetics, Triticum metabolism

Abstract

Background: Polyploidy, especially allopolyploidy, which entails merging divergent genomes via hybridization and whole-genome duplication (WGD), is a major route to speciation in plants. The duplication among the parental genomes (subgenomes) often leads to one subgenome becoming dominant over the other(s), resulting in subgenome asymmetry in gene content and expression. Polyploid wheats are allopolyploids with most genes present in two (tetraploid) or three (hexaploid) functional copies, which commonly show subgenome expression asymmetry. It is unknown whether a similar subgenome asymmetry exists during translation. We aim to address this key biological question and explore the major contributing factors to subgenome translation asymmetry., Results: Here, we obtain the first tetraploid wheat translatome and reveal that subgenome expression asymmetry exists at the translational level. We further perform in vivo RNA structure profiling to obtain the wheat RNA structure landscape and find that mRNA structure has a strong impact on translation, independent of GC content. We discover a previously uncharacterized contribution of RNA structure in subgenome translation asymmetry. We identify 3564 single-nucleotide variations (SNVs) across the transcriptomes between the two tetraploid wheat subgenomes, which induce large RNA structure disparities. These SNVs are highly conserved within durum wheat cultivars but are divergent in both domesticated and wild emmer wheat., Conclusions: We successfully determine both the translatome and in vivo RNA structurome in tetraploid wheat. We reveal that RNA structure serves as an important modulator of translational subgenome expression asymmetry in polyploids. Our work provides a new perspective for molecular breeding of major polyploid crops., (© 2021. The Author(s).)

Published

2021

10. A carbohydrate-binding protein, B-GRANULE CONTENT 1, influences starch granule size distribution in a dose-dependent manner in polyploid wheat.

Author

Chia T, Chirico M, King R, Ramirez-Gonzalez R, Saccomanno B, Seung D, Simmonds J, Trick M, Uauy C, Verhoeven T, and Trafford K

Subjects

Edible Grain genetics, Plant Proteins metabolism, Polyploidy, Receptors, Cell Surface metabolism, Triticum growth & development, Edible Grain growth & development, Gene Dosage, Plant Proteins genetics, Receptors, Cell Surface genetics, Starch metabolism, Triticum genetics

Abstract

In Triticeae endosperm (e.g. wheat and barley), starch granules have a bimodal size distribution (with A- and B-type granules) whereas in other grasses the endosperm contains starch granules with a unimodal size distribution. Here, we identify the gene, BGC1 (B-GRANULE CONTENT 1), responsible for B-type starch granule content in Aegilops and wheat. Orthologues of this gene are known to influence starch synthesis in diploids such as rice, Arabidopsis, and barley. However, using polyploid Triticeae species, we uncovered a more complex biological role for BGC1 in starch granule initiation: BGC1 represses the initiation of A-granules in early grain development but promotes the initiation of B-granules in mid grain development. We provide evidence that the influence of BGC1 on starch synthesis is dose dependent and show that three very different starch phenotypes are conditioned by the gene dose of BGC1 in polyploid wheat: normal bimodal starch granule morphology; A-granules with few or no B-granules; or polymorphous starch with few normal A- or B-granules. We conclude from this work that BGC1 participates in controlling B-type starch granule initiation in Triticeae endosperm and that its precise effect on granule size and number varies with gene dose and stage of development., (© The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2020

11. expVIP: a Customizable RNA-seq Data Analysis and Visualization Platform.

Author

Borrill P, Ramirez-Gonzalez R, and Uauy C

Subjects

Gene Expression Profiling, Gene Expression Regulation, Plant, Genes, Plant, Genetic Association Studies, Internet, Reference Standards, Reproducibility of Results, Sequence Homology, Nucleic Acid, Stress, Physiological genetics, Triticum genetics, User-Computer Interface, Sequence Analysis, RNA, Software, Statistics as Topic

Abstract

The majority of transcriptome sequencing (RNA-seq) expression studies in plants remain underutilized and inaccessible due to the use of disparate transcriptome references and the lack of skills and resources to analyze and visualize these data. We have developed expVIP, an expression visualization and integration platform, which allows easy analysis of RNA-seq data combined with an intuitive and interactive interface. Users can analyze public and user-specified data sets with minimal bioinformatics knowledge using the expVIP virtual machine. This generates a custom Web browser to visualize, sort, and filter the RNA-seq data and provides outputs for differential gene expression analysis. We demonstrate expVIP's suitability for polyploid crops and evaluate its performance across a range of biologically relevant scenarios. To exemplify its use in crop research, we developed a flexible wheat (Triticum aestivum) expression browser (www.wheat-expression.com) that can be expanded with user-generated data in a local virtual machine environment. The open-access expVIP platform will facilitate the analysis of gene expression data from a wide variety of species by enabling the easy integration, visualization, and comparison of RNA-seq data across experiments., (© 2016 American Society of Plant Biologists. All Rights Reserved.)

Published

2016

12. transPLANT Resources for Triticeae Genomic Data.

Author

Spannagl M, Alaux M, Lange M, Bolser DM, Bader KC, Letellier T, Kimmel E, Flores R, Pommier C, Kerhornou A, Walts B, Nussbaumer T, Grabmuller C, Chen J, Colmsee C, Beier S, Mascher M, Schmutzer T, Arend D, Thanki A, Ramirez-Gonzalez R, Ayling M, Ayling S, Caccamo M, Mayer KF, Scholz U, Steinbach D, Quesneville H, and Kersey PJ

Subjects

Evolution, Molecular, Hordeum genetics, Polyploidy, Triticum genetics, Genome, Plant, Genomics methods, Poaceae genetics

Abstract

The genome sequences of many important Triticeae species, including bread wheat ( L.) and barley ( L.), remained uncharacterized for a long time because their high repeat content, large sizes, and polyploidy. As a result of improvements in sequencing technologies and novel analyses strategies, several of these have recently been deciphered. These efforts have generated new insights into Triticeae biology and genome organization and have important implications for downstream usage by breeders, experimental biologists, and comparative genomicists. transPLANT () is an EU-funded project aimed at constructing hardware, software, and data infrastructure for genome-scale research in the life sciences. Since the Triticeae data are intrinsically complex, heterogenous, and distributed, the transPLANT consortium has undertaken efforts to develop common data formats and tools that enable the exchange and integration of data from distributed resources. Here we present an overview of the individual Triticeae genome resources hosted by transPLANT partners, introduce the objectives of transPLANT, and outline common developments and interfaces supporting integrated data access., (Copyright © 2016 Crop Science Society of America.)

Published

2016

13. Mutation Scanning in Wheat by Exon Capture and Next-Generation Sequencing.

Author

King R, Bird N, Ramirez-Gonzalez R, Coghill JA, Patil A, Hassani-Pak K, Uauy C, and Phillips AL

Subjects

Alleles, DNA Mutational Analysis, Genome, Plant, High-Throughput Nucleotide Sequencing, Phenotype, Polyploidy, DNA, Plant, Exons, Mutation, Triticum genetics

Abstract

Targeted Induced Local Lesions in Genomes (TILLING) is a reverse genetics approach to identify novel sequence variation in genomes, with the aims of investigating gene function and/or developing useful alleles for breeding. Despite recent advances in wheat genomics, most current TILLING methods are low to medium in throughput, being based on PCR amplification of the target genes. We performed a pilot-scale evaluation of TILLING in wheat by next-generation sequencing through exon capture. An oligonucleotide-based enrichment array covering ~2 Mbp of wheat coding sequence was used to carry out exon capture and sequencing on three mutagenised lines of wheat containing previously-identified mutations in the TaGA20ox1 homoeologous genes. After testing different mapping algorithms and settings, candidate SNPs were identified by mapping to the IWGSC wheat Chromosome Survey Sequences. Where sequence data for all three homoeologues were found in the reference, mutant calls were unambiguous; however, where the reference lacked one or two of the homoeologues, captured reads from these genes were mis-mapped to other homoeologues, resulting either in dilution of the variant allele frequency or assignment of mutations to the wrong homoeologue. Competitive PCR assays were used to validate the putative SNPs and estimate cut-off levels for SNP filtering. At least 464 high-confidence SNPs were detected across the three mutagenized lines, including the three known alleles in TaGA20ox1, indicating a mutation rate of ~35 SNPs per Mb, similar to that estimated by PCR-based TILLING. This demonstrates the feasibility of using exon capture for genome re-sequencing as a method of mutation detection in polyploid wheat, but accurate mutation calling will require an improved genomic reference with more comprehensive coverage of homoeologues.

Published

2015

14. PyroClean: denoising pyrosequences from protein-coding amplicons for the recovery of interspecific and intraspecific genetic variation.

Author

Ramirez-Gonzalez R, Yu DW, Bruce C, Heavens D, Caccamo M, and Emerson BC

Subjects

Animals, Arthropods classification, Base Sequence, DNA, Mitochondrial classification, DNA, Mitochondrial isolation & purification, Electron Transport Complex IV classification, Electron Transport Complex IV isolation & purification, Genetic Variation, High-Throughput Nucleotide Sequencing, Molecular Sequence Data, Phylogeny, Polymerase Chain Reaction, Ribosomes genetics, Sequence Analysis, DNA, Signal-To-Noise Ratio, Algorithms, Arthropods genetics, DNA, Mitochondrial genetics, Electron Transport Complex IV genetics, Open Reading Frames, Software

Abstract

High-throughput parallel sequencing is a powerful tool for the quantification of microbial diversity through the amplification of nuclear ribosomal gene regions. Recent work has extended this approach to the quantification of diversity within otherwise difficult-to-study metazoan groups. However, nuclear ribosomal genes present both analytical challenges and practical limitations that are a consequence of the mutational properties of nuclear ribosomal genes. Here we exploit useful properties of protein-coding genes for cross-species amplification and denoising of 454 flowgrams. We first use experimental mixtures of species from the class Collembola to amplify and pyrosequence the 5' region of the COI barcode, and we implement a new algorithm called PyroClean for the denoising of Roche GS FLX pyrosequences. Using parameter values from the analysis of experimental mixtures, we then analyse two communities sampled from field sites on the island of Tenerife. Cross-species amplification success of target mitochondrial sequences in experimental species mixtures is high; however, there is little relationship between template DNA concentrations and pyrosequencing read abundance. Homopolymer error correction and filtering against a consensus reference sequence reduced the volume of unique sequences to approximately 5% of the original unique raw reads. Filtering of remaining non-target sequences attributed to PCR error, sequencing error, or numts further reduced unique sequence volume to 0.8% of the original raw reads. PyroClean reduces or eliminates the need for an additional, time-consuming step to cluster reads into Operational Taxonomic Units, which facilitates the detection of intraspecific DNA sequence variation. PyroCleaned sequence data from field sites in Tenerife demonstrate the utility of our approach for quantifying evolutionary diversity and its spatial structure. Comparison of our sequence data to public databases reveals that we are able to successfully recover both interspecific and intraspecific sequence diversity.

Published

2013

15. Analyses of pig genomes provide insight into porcine demography and evolution.

Author

Groenen MA, Archibald AL, Uenishi H, Tuggle CK, Takeuchi Y, Rothschild MF, Rogel-Gaillard C, Park C, Milan D, Megens HJ, Li S, Larkin DM, Kim H, Frantz LA, Caccamo M, Ahn H, Aken BL, Anselmo A, Anthon C, Auvil L, Badaoui B, Beattie CW, Bendixen C, Berman D, Blecha F, Blomberg J, Bolund L, Bosse M, Botti S, Bujie Z, Bystrom M, Capitanu B, Carvalho-Silva D, Chardon P, Chen C, Cheng R, Choi SH, Chow W, Clark RC, Clee C, Crooijmans RP, Dawson HD, Dehais P, De Sapio F, Dibbits B, Drou N, Du ZQ, Eversole K, Fadista J, Fairley S, Faraut T, Faulkner GJ, Fowler KE, Fredholm M, Fritz E, Gilbert JG, Giuffra E, Gorodkin J, Griffin DK, Harrow JL, Hayward A, Howe K, Hu ZL, Humphray SJ, Hunt T, Hornshøj H, Jeon JT, Jern P, Jones M, Jurka J, Kanamori H, Kapetanovic R, Kim J, Kim JH, Kim KW, Kim TH, Larson G, Lee K, Lee KT, Leggett R, Lewin HA, Li Y, Liu W, Loveland JE, Lu Y, Lunney JK, Ma J, Madsen O, Mann K, Matthews L, McLaren S, Morozumi T, Murtaugh MP, Narayan J, Nguyen DT, Ni P, Oh SJ, Onteru S, Panitz F, Park EW, Park HS, Pascal G, Paudel Y, Perez-Enciso M, Ramirez-Gonzalez R, Reecy JM, Rodriguez-Zas S, Rohrer GA, Rund L, Sang Y, Schachtschneider K, Schraiber JG, Schwartz J, Scobie L, Scott C, Searle S, Servin B, Southey BR, Sperber G, Stadler P, Sweedler JV, Tafer H, Thomsen B, Wali R, Wang J, Wang J, White S, Xu X, Yerle M, Zhang G, Zhang J, Zhang J, Zhao S, Rogers J, Churcher C, and Schook LB

Subjects

Animals, Demography, Models, Animal, Molecular Sequence Data, Population Dynamics, Genome genetics, Phylogeny, Sus scrofa classification, Sus scrofa genetics

Abstract

For 10,000 years pigs and humans have shared a close and complex relationship. From domestication to modern breeding practices, humans have shaped the genomes of domestic pigs. Here we present the assembly and analysis of the genome sequence of a female domestic Duroc pig (Sus scrofa) and a comparison with the genomes of wild and domestic pigs from Europe and Asia. Wild pigs emerged in South East Asia and subsequently spread across Eurasia. Our results reveal a deep phylogenetic split between European and Asian wild boars ∼1 million years ago, and a selective sweep analysis indicates selection on genes involved in RNA processing and regulation. Genes associated with immune response and olfaction exhibit fast evolution. Pigs have the largest repertoire of functional olfactory receptor genes, reflecting the importance of smell in this scavenging animal. The pig genome sequence provides an important resource for further improvements of this important livestock species, and our identification of many putative disease-causing variants extends the potential of the pig as a biomedical model.

Published

2012

16. Biogem: an effective tool-based approach for scaling up open source software development in bioinformatics.

Author

Bonnal RJ, Aerts J, Githinji G, Goto N, MacLean D, Miller CA, Mishima H, Pagani M, Ramirez-Gonzalez R, Smant G, Strozzi F, Syme R, Vos R, Wennblom TJ, Woodcroft BJ, Katayama T, and Prins P

Subjects

Computational Biology methods, Internet, Programming Languages, Software

Abstract

Summary: Biogem provides a software development environment for the Ruby programming language, which encourages community-based software development for bioinformatics while lowering the barrier to entry and encouraging best practices. Biogem, with its targeted modular and decentralized approach, software generator, tools and tight web integration, is an improved general model for scaling up collaborative open source software development in bioinformatics., Availability: Biogem and modules are free and are OSS. Biogem runs on all systems that support recent versions of Ruby, including Linux, Mac OS X and Windows. Further information at http://www.biogems.info. A tutorial is available at http://www.biogems.info/howto.html, Contact: bonnal@ingm.org.

Published

2012

17. Assemblathon 1: a competitive assessment of de novo short read assembly methods.

Author

Earl D, Bradnam K, St John J, Darling A, Lin D, Fass J, Yu HO, Buffalo V, Zerbino DR, Diekhans M, Nguyen N, Ariyaratne PN, Sung WK, Ning Z, Haimel M, Simpson JT, Fonseca NA, Birol İ, Docking TR, Ho IY, Rokhsar DS, Chikhi R, Lavenier D, Chapuis G, Naquin D, Maillet N, Schatz MC, Kelley DR, Phillippy AM, Koren S, Yang SP, Wu W, Chou WC, Srivastava A, Shaw TI, Ruby JG, Skewes-Cox P, Betegon M, Dimon MT, Solovyev V, Seledtsov I, Kosarev P, Vorobyev D, Ramirez-Gonzalez R, Leggett R, MacLean D, Xia F, Luo R, Li Z, Xie Y, Liu B, Gnerre S, MacCallum I, Przybylski D, Ribeiro FJ, Yin S, Sharpe T, Hall G, Kersey PJ, Durbin R, Jackman SD, Chapman JA, Huang X, DeRisi JL, Caccamo M, Li Y, Jaffe DB, Green RE, Haussler D, Korf I, and Paten B

Subjects

Genome physiology, Genomics methods, Sequence Analysis, DNA methods

Abstract

Low-cost short read sequencing technology has revolutionized genomics, though it is only just becoming practical for the high-quality de novo assembly of a novel large genome. We describe the Assemblathon 1 competition, which aimed to comprehensively assess the state of the art in de novo assembly methods when applied to current sequencing technologies. In a collaborative effort, teams were asked to assemble a simulated Illumina HiSeq data set of an unknown, simulated diploid genome. A total of 41 assemblies from 17 different groups were received. Novel haplotype aware assessments of coverage, contiguity, structure, base calling, and copy number were made. We establish that within this benchmark: (1) It is possible to assemble the genome to a high level of coverage and accuracy, and that (2) large differences exist between the assemblies, suggesting room for further improvements in current methods. The simulated benchmark, including the correct answer, the assemblies, and the code that was used to evaluate the assemblies is now public and freely available from http://www.assemblathon.org/.

Published

2011

18. Gee Fu: a sequence version and web-services database tool for genomic assembly, genome feature and NGS data.

Author

Ramirez-Gonzalez R, Caccamo M, and MacLean D

Subjects

Animals, Electronic Data Processing, Genome, Humans, Internet, Microarray Analysis, Sequence Alignment, Software, Base Sequence, Databases, Genetic, Genomics, Information Storage and Retrieval methods

Abstract

Summary: Scientists now use high-throughput sequencing technologies and short-read assembly methods to create draft genome assemblies in just days. Tools and pipelines like the assembler, and the workflow management environments make it easy for a non-specialist to implement complicated pipelines to produce genome assemblies and annotations very quickly. Such accessibility results in a proliferation of assemblies and associated files, often for many organisms. These assemblies get used as a working reference by lots of different workers, from a bioinformatician doing gene prediction or a bench scientist designing primers for PCR. Here we describe Gee Fu, a database tool for genomic assembly and feature data, including next-generation sequence alignments. Gee Fu is an instance of a Ruby-On-Rails web application on a feature database that provides web and console interfaces for input, visualization of feature data via AnnoJ, access to data through a web-service interface, an API for direct data access by Ruby scripts and access to feature data stored in BAM files. Gee Fu provides a platform for storing and sharing different versions of an assembly and associated features that can be accessed and updated by bench biologists and bioinformaticians in ways that are easy and useful for each., Availability: http://tinyurl.com/geefu, Contact: dan.maclean@tsl.ac.uk.

Published

2011

19. The effects of metolazone in the long-term treatment of essential hypertension.

Author

Cangiano JL, Campos JA, Trevino A, Ramirez-Gonzalez R, and Ramirez-Muzo O

Subjects

Adult, Blood Pressure drug effects, Body Weight drug effects, Clinical Trials as Topic, Diuretics administration & dosage, Diuretics adverse effects, Diuretics pharmacology, Humans, Male, Middle Aged, Placebos, Quinazolines administration & dosage, Quinazolines adverse effects, Quinazolines pharmacology, Time Factors, Antihypertensive Agents therapeutic use, Diuretics therapeutic use, Hypertension drug therapy, Quinazolines therapeutic use, Sulfonamides

Published

1974

20. Normal renin uremic hypertension. Study of cardiac hemodynamics, plasma volume, extracellular fluid volume, and the renin angiotensin system.

Author

Cangiano JL, Ramirez-Muxó O, Ramirez-Gonzalez R, Trevino A, and Campos JA

Subjects

Adolescent, Adult, Aged, Blood Pressure, Capillary Resistance, Cardiac Output, Child, Child, Preschool, Extracellular Space metabolism, Humans, Hypertension, Renal complications, Hypertension, Renal metabolism, Male, Middle Aged, Plasma Volume, Renal Dialysis, Renin metabolism, Uremia metabolism, Uremia therapy, Hemodynamics, Hypertension, Renal physiopathology, Uremia physiopathology

Abstract

Studies were undertaken in 33 uremic patients with or without hypertension, 11 normal subjects, and 15 essential hypertensive patients to assess cardiac hemodynamics, plasma volume, extracellular fluid volume, and peripheral renin levels. Cardiac output and intraarterial blood pressure were measured and peripheral vascular resistance index calculated. These studies suggest that uremic hypertension with normal renin values and hypervolemia is hemodynamically sustained by an increase in peripheral resistance rather than by an increased cardiac output. The renin angiotensin system plays a secondary role as compared to overexpansion in the genesis of hypertension in normoreninemic uremic hypertension.

Published

1976