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130 results on '"Steuernagel, B."'

2. A complex receptor locus confers responsiveness to necrosis and ethylene-inducing like peptides in Brassica napus

Author

Universidad de Sevilla. Departamento de Microbiología, UK Research & Innovation (UKRI), Biotechnology and Biological Sciences Research Council (BBSRC), Yalcin, HA., Jacott, Catherine N., Ramírez-González, R, Steuernagel, B, Sidhu, GS, Kirby, R., Verbeek, E., Schoonbeek, HJ., Ridout, CJ., Wells, R., Universidad de Sevilla. Departamento de Microbiología, UK Research & Innovation (UKRI), Biotechnology and Biological Sciences Research Council (BBSRC), Yalcin, HA., Jacott, Catherine N., Ramírez-González, R, Steuernagel, B, Sidhu, GS, Kirby, R., Verbeek, E., Schoonbeek, HJ., Ridout, CJ., and Wells, R.

Abstract

Brassica crops are susceptible to diseases which can be mitigated by breeding for resistance. MAMPs (microbe-associated molecular patterns) are conserved molecules of pathogens that elicit host defences known as pattern-triggered immunity (PTI). Necrosis and Ethylene-inducing peptide 1-like proteins (NLPs) are MAMPs found in a wide range of phytopathogens. We studied the response to BcNEP2, a representative NLP from Botrytis cinerea, and showed that it contributes to disease resistance in Brassica napus. To map regions conferring NLP response, we used the production of reactive oxygen species (ROS) induced during PTI across a population of diverse B. napus accessions for associative transcriptomics (AT), and bulk segregant analysis (BSA) on DNA pools created from a cross of NLP-responsive and non-responsive lines. In silico mapping with AT identified two peaks for NLP responsiveness on chromosomes A04 and C05 whereas the BSA identified one peak on A04. BSA delimited the region for NLP-responsiveness to 3 Mbp, containing 245 genes on the Darmor-bzh reference genome and four co-segregating KASP markers were identified. The same pipeline with the ZS11 genome confirmed the highest-associated region on chromosome A04. Comparative BLAST analysis revealed unannotated clusters of receptor-like protein (RLP) homologues on ZS11 chromosome A04. However, no specific RLP homologue conferring NLP response could be identified. Our results also suggest that BR-SIGNALLING KINASE1 may be involved with modulating the NLP response. Overall, we demonstrate that responsiveness to NLP contributes to disease resistance in B. napus and define the associated genomic location. These results can have practical application in crop improvement.

Published
2024

3. 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

4. BIOLOGICAL SESSION“THE IMPORTANCE OF G. GAMOW'S IDEAS FOR BIOLOGY OF THE 21st CENTURY” AT THE XXІI GAMOW INTERNATIONAL ASTRONOMICAL CONFERENCE-SCHOOL IN ODESA (25 AUGUST, 2022)

Author

Alqudah, A.M., primary, Artemenko A.Yu., A.Yu., additional, Awal R., R., additional, Banson, A., additional, Вlagodarova, O.M., additional, Boerner, А, additional, Wang, F., additional, Volkov R.A., R.A., additional, Wingen, L., additional, Goram, R., additional, Gorodna, O., additional, Gretsky, I.O., additional, Griffiths, S., additional, Hrytsak, L.R., additional, Gromyko, O.M., additional, Gromozova, O.M., additional, Doneva, D., additional, Drobyk, N.M, additional, Zelinska, N., additional, Kartseva, T., additional, Kolisnyk, Kh. M., additional, Collier, S., additional, Kusz-Zamelczyk, K., additional, Lovegrove, A., additional, Lauber-Biason, A., additional, Leverington-Waite M., M., additional, Livshits, L., additional, Luzhetskyy, A.M., additional, Mayorova, O.Yu., additional, Martyniuk, V.S., additional, Misheva, S., additional, Myronovskyi, M.L, additional, Monczak, Yu., additional, Nef, S., additional, Novikov, A.V., additional, Aleksandrov, V., additional, Orford, S., additional, Popovych, Yu.A., additional, Prokopiak, M.Z., additional, Riche, A, additional, Roshka N.M., N.M., additional, Segrè, G., additional, Sirokha, D., additional, Tynkevich, Y.O., additional, Tistechok, S.I., additional, Fedorenko, V.O., additional, Philp Ch., Ch., additional, Hawkesford, M., additional, Tseysler, Yu.V., additional, Chayut, N., additional, Chebotar, S.V., additional, Cheng Sh., Sh., additional, Chorney, I.I., additional, Steuernagel, B., additional, Shewry, P., additional, and Jaruzelska, J., additional

Published
2022
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5. Shifting the limits in wheat research and breeding using a fully annotated reference genome

Author

Appels, R., Eversole, K., Feuillet, C., Keller, B., Rogers, J., Stein, N., Pozniak, C.J., Choulet, F., Distelfeld, A., Poland, J., Ronen, G., Barad, O., Baruch, K., Keeble-Gagnère, G., Mascher, M., Sharpe, A.G., Ben-Zvi, G., Josselin, A-A, Himmelbach, A., Balfourier, F., Gutierrez-Gonzalez, J., Hayden, M., Koh, C., Muehlbauer, G., Pasam, R.K., Paux, E., Rigault, P., Tibbits, J., Tiwari, V., Spannagl, M., Lang, D., Gundlach, H., Haberer, G., Mayer, K.F.X., Ormanbekova, D., Prade, V., Šimková, H., Wicker, T., Swarbreck, D., Rimbert, H., Felder, M., Guilhot, N., Kaithakottil, G., Keilwagen, J., Leroy, P., Lux, T., Twardziok, S., Venturini, L., Juhász, A., Abrouk, M., Fischer, I., Uauy, C., Borrill, P., Ramirez-Gonzalez, R.H., Arnaud, D., Chalabi, S., Chalhoub, B., Cory, A., Datla, R., Davey, M.W., Jacobs, J., Robinson, S.J., Steuernagel, B., van Ex, F., Wulff, B.B.H., Benhamed, M., Bendahmane, A., Concia, L., Latrasse, D., Alaux, M., Bartoš, J., Bellec, A., Berges, H., Doležel, J., Frenkel, Z., Gill, B., Korol, A., Letellier, T., Olsen, O-A, Singh, K., Valárik, M., van der Vossen, E., Vautrin, S., Weining, S., Fahima, T., Glikson, V., Raats, D., Číhalíková, J., Toegelová, H., Vrána, J., Sourdille, P., Darrier, B., Barabaschi, D., Cattivelli, L., Hernandez, P., Galvez, S., Budak, H., Jones, J.D.G., Witek, K., Yu, G., Small, I., Melonek, J., Zhou, R., Belova, T., Kanyuka, K., King, R., Nilsen, K., Walkowiak, S., Cuthbert, R., Knox, R., Wiebe, K., Xiang, D., Rohde, A., Gold, T., Čížková, J., Akpinar, B.A., Biyiklioglu, S., Gao, L., N’Daiye, A., Kubaláková, M., Šafář, J., Alfama, F., Adam-Blondon, A-F, Flores, R., Guerche, C., Loaec, M., Quesneville, H., Condie, J., Ens, J., Koh, C.S., Maclachlan, R., Tan, Y., Alberti, A., Aury, J-M, Barbe, V., Couloux, A., Cruaud, C., Labadie, K., Mangenot, S., Wincker, P., Kaur, G., Luo, M., Sehgal, S., Chhuneja, P., Gupta, O.P., Jindal, S., Kaur, P., Malik, P., Sharma, P., Yadav, B., Singh, N.K., Khurana, J.P., Chaudhary, C., Khurana, P., Kumar, V., Mahato, A., Mathur, S., Sevanthi, A., Sharma, N., Tomar, R.S., Holušová, K., Plíhal, O., Clark, M.D., Heavens, D., Kettleborough, G., Wright, J., Balcárková, B., Hu, Y., Salina, E., Ravin, N., Skryabin, K., Beletsky, A., Kadnikov, V., Mardanov, A., Nesterov, M., Rakitin, A., Sergeeva, E., Handa, H., Kanamori, H., Katagiri, S., Kobayashi, F., Nasuda, S., Tanaka, T., Wu, J., Cattonaro, F., Jiumeng, M., Kugler, K.G., Pfeifer, M., Sandve, S., Xun, X., Zhan, B., Batley, J., Bayer, P.E., Edwards, D., Hayashi, S., Tulpová, Z., Visendi, P., Cui, L., Du, X., Feng, K., Nie, X., Tong, W., Wang, L., Appels, R., Eversole, K., Feuillet, C., Keller, B., Rogers, J., Stein, N., Pozniak, C.J., Choulet, F., Distelfeld, A., Poland, J., Ronen, G., Barad, O., Baruch, K., Keeble-Gagnère, G., Mascher, M., Sharpe, A.G., Ben-Zvi, G., Josselin, A-A, Himmelbach, A., Balfourier, F., Gutierrez-Gonzalez, J., Hayden, M., Koh, C., Muehlbauer, G., Pasam, R.K., Paux, E., Rigault, P., Tibbits, J., Tiwari, V., Spannagl, M., Lang, D., Gundlach, H., Haberer, G., Mayer, K.F.X., Ormanbekova, D., Prade, V., Šimková, H., Wicker, T., Swarbreck, D., Rimbert, H., Felder, M., Guilhot, N., Kaithakottil, G., Keilwagen, J., Leroy, P., Lux, T., Twardziok, S., Venturini, L., Juhász, A., Abrouk, M., Fischer, I., Uauy, C., Borrill, P., Ramirez-Gonzalez, R.H., Arnaud, D., Chalabi, S., Chalhoub, B., Cory, A., Datla, R., Davey, M.W., Jacobs, J., Robinson, S.J., Steuernagel, B., van Ex, F., Wulff, B.B.H., Benhamed, M., Bendahmane, A., Concia, L., Latrasse, D., Alaux, M., Bartoš, J., Bellec, A., Berges, H., Doležel, J., Frenkel, Z., Gill, B., Korol, A., Letellier, T., Olsen, O-A, Singh, K., Valárik, M., van der Vossen, E., Vautrin, S., Weining, S., Fahima, T., Glikson, V., Raats, D., Číhalíková, J., Toegelová, H., Vrána, J., Sourdille, P., Darrier, B., Barabaschi, D., Cattivelli, L., Hernandez, P., Galvez, S., Budak, H., Jones, J.D.G., Witek, K., Yu, G., Small, I., Melonek, J., Zhou, R., Belova, T., Kanyuka, K., King, R., Nilsen, K., Walkowiak, S., Cuthbert, R., Knox, R., Wiebe, K., Xiang, D., Rohde, A., Gold, T., Čížková, J., Akpinar, B.A., Biyiklioglu, S., Gao, L., N’Daiye, A., Kubaláková, M., Šafář, J., Alfama, F., Adam-Blondon, A-F, Flores, R., Guerche, C., Loaec, M., Quesneville, H., Condie, J., Ens, J., Koh, C.S., Maclachlan, R., Tan, Y., Alberti, A., Aury, J-M, Barbe, V., Couloux, A., Cruaud, C., Labadie, K., Mangenot, S., Wincker, P., Kaur, G., Luo, M., Sehgal, S., Chhuneja, P., Gupta, O.P., Jindal, S., Kaur, P., Malik, P., Sharma, P., Yadav, B., Singh, N.K., Khurana, J.P., Chaudhary, C., Khurana, P., Kumar, V., Mahato, A., Mathur, S., Sevanthi, A., Sharma, N., Tomar, R.S., Holušová, K., Plíhal, O., Clark, M.D., Heavens, D., Kettleborough, G., Wright, J., Balcárková, B., Hu, Y., Salina, E., Ravin, N., Skryabin, K., Beletsky, A., Kadnikov, V., Mardanov, A., Nesterov, M., Rakitin, A., Sergeeva, E., Handa, H., Kanamori, H., Katagiri, S., Kobayashi, F., Nasuda, S., Tanaka, T., Wu, J., Cattonaro, F., Jiumeng, M., Kugler, K.G., Pfeifer, M., Sandve, S., Xun, X., Zhan, B., Batley, J., Bayer, P.E., Edwards, D., Hayashi, S., Tulpová, Z., Visendi, P., Cui, L., Du, X., Feng, K., Nie, X., Tong, W., and Wang, L.

Abstract

Wheat is one of the major sources of food for much of the world. However, because bread wheat's genome is a large hybrid mix of three separate subgenomes, it has been difficult to produce a high-quality reference sequence. Using recent advances in sequencing, the International Wheat Genome Sequencing Consortium presents an annotated reference genome with a detailed analysis of gene content among subgenomes and the structural organization for all the chromosomes. Examples of quantitative trait mapping and CRISPR-based genome modification show the potential for using this genome in agricultural research and breeding. Ramírez-González et al. exploited the fruits of this endeavor to identify tissue-specific biased gene expression and coexpression networks during development and exposure to stress. These resources will accelerate our understanding of the genetic basis of bread wheat.

Published
2018

6. The transcriptional landscape of polyploid wheat

Author

Ramirez-Gonzalez, 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., Uauy, C., Ramirez-Gonzalez, 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.

Abstract

Wheat is one of the major sources of food for much of the world. However, because bread wheat's genome is a large hybrid mix of three separate subgenomes, it has been difficult to produce a high-quality reference sequence. Using recent advances in sequencing, the International Wheat Genome Sequencing Consortium presents an annotated reference genome with a detailed analysis of gene content among subgenomes and the structural organization for all the chromosomes. Examples of quantitative trait mapping and CRISPR-based genome modification show the potential for using this genome in agricultural research and breeding. Ramírez-González et al. exploited the fruits of this endeavor to identify tissue-specific biased gene expression and coexpression networks during development and exposure to stress. These resources will accelerate our understanding of the genetic basis of bread wheat.

Published
2018

7. 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
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8. A physical, genetic and functional sequence assembly of the barley genome

Author

Mayer, Kf, Waugh, R, Langridge, P, Close, Tj, Wise, Rp, Graner, A, Matsumoto, T, Sato, K, Schulman, A, Muehlbauer, Gj, Stein, N, Ariyadasa, R, Schulte, D, Poursarebani, N, Zhou, R, Steuernagel, B, Mascher, M, Scholz, U, Shi, B, Madishetty, K, Svensson, Jt, Bhat, P, Moscou, M, Resnik, J, Hedley, P, Liu, H, Morris, J, Frenkel, Z, Korol, A, Bergès, H, Taudien, S, Felder, M, Groth, M, Platzer, M, Himmelbach, A, Lonardi, S, Duma, D, Alpert, M, Cordero, Francesca, Beccuti, Marco, Ciardo, G, Ma, Y, Wanamaker, S, Cattonaro, F, Vendramin, V, Scalabrin, S, Radovic, S, Wing, R, Morgante, M, Nussbaumer, T, Gundlach, H, Martis, M, Poland, J, Spannagl, M, Pfeifer, M, Moisy, C, Tanskanen, J, Zuccolo, A, Russell, J, Druka, A, Marshall, D, Bayer, M, Swarbreck, D, Sampath, D, Ayling, S, Febrer, M, Caccamo, M, Tanaka, T, Wannamaker, S, Schmutzer, T, Brown, Jw, Fincher, Gb, Stein, N., MIPS/IBIS, Helmholtz-Zentrum München (HZM), The James Hutton Institute, University of Adelaide, Iowa State University (ISU), Leibniz Institute of Plant Genetics and Crop Plant Research, Natl Inst Agrobiol Sci, Partenaires INRAE, Okayama University, University of Helsinki, University of Minnesota [Twin Cities] (UMN), University of Minnesota System, Inst Evolut, University of Haifa [Haifa], German Ministry of Education and Research (BMBF) [0314000], Leibniz Association, European project of the 7th framework programme 'TriticeaeGenome', Austrian Wissenschaftsfond (FWF) [SFB F3705], ERA-NET PG project 'BARCODE', Scottish Government/BBSRC [BB/100663X/1], National Science Foundation [DBI 0321756, DBI-1062301], USDA-CSREES-NRI [2006-55606-16722], Agriculture and Food Research Initiative Plant Genome, Genetics and Breeding Program of USDA-CSREES-NIFA [2009-65300-05645], BRAIN and NBRP-Japan, and Japanese MAFF [TRG1008]

Subjects
0106 biological sciences, [SDV]Life Sciences [q-bio], Sequence assembly, 01 natural sciences, Genome, Gene Expression Regulation, Plant, 2. Zero hunger, Genetics, 0303 health sciences, MESSENGER-RNA DECAY, Multidisciplinary, food and beverages, Genomics, ARABIDOPSIS, Physical Chromosome Mapping, Molecular Sequence Annotation, Codon, Nonsense, MAP, HORDEUM-VULGARE L, Genome, Plant, EXPRESSION, Crops, Agricultural, Sequence analysis, Computational biology, Biology, MILDEW RESISTANCE LOCUS, Genes, Plant, Polymorphism, Single Nucleotide, Plant sciences, Evolution, Molecular, 03 medical and health sciences, REVEALS, RICE, Gene, 030304 developmental biology, Repetitive Sequences, Nucleic Acid, Comparative genomics, Hordeum, Sequence Analysis, DNA, 15. Life on land, EVOLUTION, Alternative Splicing, NONCODING RNAS, Hordeum vulgare, Transcriptome, 010606 plant biology & botany
Abstract

International audience; Barley (Hordeum vulgare L.) is among the world's earliest domesticated and most important crop plants. It is diploid with a large haploid genome of 5.1 gigabases (Gb). Here we present an integrated and ordered physical, genetic and functional sequence resource that describes the barley gene-space in a structured whole-genome context. We developed a physical map of 4.98 Gb, with more than 3.90 Gb anchored to a high-resolution genetic map. Projecting a deep whole-genome shotgun assembly, complementary DNA and deep RNA sequence data onto this framework supports 79,379 transcript clusters, including 26,159 'high-confidence' genes with homology support from other plant genomes. Abundant alternative splicing, premature termination codons and novel transcriptionally active regions suggest that post-transcriptional processing forms an important regulatory layer. Survey sequences from diverse accessions reveal a landscape of extensive single-nucleotide variation. Our data provide a platform for both genome-assisted research and enabling contemporary crop improvement.

Published
2012
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11. A chromosome-based draft sequence of the hexaploid bread wheat (Triticum aestivum) genome

Author

Mayer, K.F.X., Rogers, J., Dole el, J., Pozniak, C., Eversole, K., Feuillet, C., Gill, B., Friebe, B., Lukaszewski, A.J., Sourdille, P., Endo, T.R., Kubalakova, M., Ihalikova, J., Dubska, Z., Vrana, J., Perkova, R., Imkova, H., Febrer, M., Clissold, L., McLay, K., Singh, K., Chuneja, P., Singh, N.K., Khurana, J., Akhunov, E., Choulet, F., Alberti, A., Barbe, V., Wincker, P., Kanamori, H., Kobayashi, F., Itoh, T., Matsumoto, T., Sakai, H., Tanaka, T., Wu, J., Ogihara, Y., Handa, H., Maclachlan, P.R., Sharpe, A., Klassen, D., Edwards, D., Batley, J., Olsen, O-A, Sandve, S.R., Lien, S., Steuernagel, B., Wulff, B., Caccamo, M., Ayling, S., Ramirez-Gonzalez, R.H., Clavijo, B.J., Wright, J., Pfeifer, M., Spannagl, M., Martis, M.M., Mascher, M., Chapman, J., Poland, J.A., Scholz, U., Barry, K., Waugh, R., Rokhsar, D.S., Muehlbauer, G.J., Stein, N., Gundlach, H., Zytnicki, M., Jamilloux, V., Quesneville, H., Wicker, T., Faccioli, P., Colaiacovo, M., Stanca, A.M., Budak, H., Cattivelli, L., Glover, N., Pingault, L., Paux, E., Sharma, S., Appels, R., Bellgard, M., Chapman, B., Nussbaumer, T., Bader, K.C., Rimbert, H., Wang, S., Knox, R., Kilian, A., Alaux, M., Alfama, F., Couderc, L., Guilhot, N., Viseux, C., Loaec, M., Keller, B., Praud, S., Mayer, K.F.X., Rogers, J., Dole el, J., Pozniak, C., Eversole, K., Feuillet, C., Gill, B., Friebe, B., Lukaszewski, A.J., Sourdille, P., Endo, T.R., Kubalakova, M., Ihalikova, J., Dubska, Z., Vrana, J., Perkova, R., Imkova, H., Febrer, M., Clissold, L., McLay, K., Singh, K., Chuneja, P., Singh, N.K., Khurana, J., Akhunov, E., Choulet, F., Alberti, A., Barbe, V., Wincker, P., Kanamori, H., Kobayashi, F., Itoh, T., Matsumoto, T., Sakai, H., Tanaka, T., Wu, J., Ogihara, Y., Handa, H., Maclachlan, P.R., Sharpe, A., Klassen, D., Edwards, D., Batley, J., Olsen, O-A, Sandve, S.R., Lien, S., Steuernagel, B., Wulff, B., Caccamo, M., Ayling, S., Ramirez-Gonzalez, R.H., Clavijo, B.J., Wright, J., Pfeifer, M., Spannagl, M., Martis, M.M., Mascher, M., Chapman, J., Poland, J.A., Scholz, U., Barry, K., Waugh, R., Rokhsar, D.S., Muehlbauer, G.J., Stein, N., Gundlach, H., Zytnicki, M., Jamilloux, V., Quesneville, H., Wicker, T., Faccioli, P., Colaiacovo, M., Stanca, A.M., Budak, H., Cattivelli, L., Glover, N., Pingault, L., Paux, E., Sharma, S., Appels, R., Bellgard, M., Chapman, B., Nussbaumer, T., Bader, K.C., Rimbert, H., Wang, S., Knox, R., Kilian, A., Alaux, M., Alfama, F., Couderc, L., Guilhot, N., Viseux, C., Loaec, M., Keller, B., and Praud, S.

Abstract

An ordered draft sequence of the 17-gigabase hexaploid bread wheat (Triticum aestivum) genome has been produced by sequencing isolated chromosome arms. We have annotated 124,201 gene loci distributed nearly evenly across the homeologous chromosomes and subgenomes. Comparative gene analysis of wheat subgenomes and extant diploid and tetraploid wheat relatives showed that high sequence similarity and structural conservation are retained, with limited gene loss, after polyploidization. However, across the genomes there was evidence of dynamic gene gain, loss, and duplication since the divergence of the wheat lineages. A high degree of transcriptional autonomy and no global dominance was found for the subgenomes. These insights into the genome biology of a polyploid crop provide a springboard for faster gene isolation, rapid genetic marker development, and precise breeding to meet the needs of increasing food demand worldwide.

Published
2014

12. Frequent gene movement and pseudogene evolution is common to the large and complex genomes of wheat, barley, and their relatives

Author

Wicker, Thomas, Mayer, K F X, Gundlach, H, Martis, M, Steuernagel, B, Scholz, Uwe, Simková, H, Kubaláková, M, Choulet, F, Taudien, S, Platzer, M, Feuillet, C, Fahima, T, Budak, H, Dolezel, J, Keller, B, Stein, N, Wicker, Thomas, Mayer, K F X, Gundlach, H, Martis, M, Steuernagel, B, Scholz, Uwe, Simková, H, Kubaláková, M, Choulet, F, Taudien, S, Platzer, M, Feuillet, C, Fahima, T, Budak, H, Dolezel, J, Keller, B, and Stein, N

Abstract

All six arms of the group 1 chromosomes of hexaploid wheat (Triticum aestivum) were sequenced with Roche/454 to 1.3- to 2.2-fold coverage and compared with similar data sets from the homoeologous chromosome 1H of barley (Hordeum vulgare). Six to ten thousand gene sequences were sampled per chromosome. These were classified into genes that have their closest homologs in the Triticeae group 1 syntenic region in Brachypodium, rice (Oryza sativa), and/or sorghum (Sorghum bicolor) and genes that have their homologs elsewhere in these model grass genomes. Although the number of syntenic genes was similar between the homologous groups, the amount of nonsyntenic genes was found to be extremely diverse between wheat and barley and even between wheat subgenomes. Besides a small core group of genes that are nonsyntenic in other grasses but conserved among Triticeae, we found thousands of genic sequences that are specific to chromosomes of one single species or subgenome. By examining in detail 50 genes from chromosome 1H for which BAC sequences were available, we found that many represent pseudogenes that resulted from transposable element activity and double-strand break repair. Thus, Triticeae seem to accumulate nonsyntenic genes frequently. Since many of them are likely to be pseudogenes, total gene numbers in Triticeae are prone to pronounced overestimates.

Published
2011

13. Genes driving potato tuber initiation and growth: identification based on transcriptional changes using the POCI array

Author

Kloosterman, B.A., de Koeyer, D., Griffiths, R., Flinn, B., Steuernagel, B., Scholz, U., Sonnewald, S., Sonnewald, U., Bryan, G.J., Prat, S., Banfalvi, Z., Hammond, J.P., Geigenberger, P., Nielsen, K.L., Visser, R.G.F., Bachem, C.W.B., Kloosterman, B.A., de Koeyer, D., Griffiths, R., Flinn, B., Steuernagel, B., Scholz, U., Sonnewald, S., Sonnewald, U., Bryan, G.J., Prat, S., Banfalvi, Z., Hammond, J.P., Geigenberger, P., Nielsen, K.L., Visser, R.G.F., and Bachem, C.W.B.

Abstract

The increasing amount of available expressed gene sequence data makes whole-transcriptome analysis of certain crop species possible. Potato currently has the second largest number of publicly available expressed sequence tag (EST) sequences among the Solanaceae. Most of these ESTs, plus other proprietary sequences, were combined and used to generate a unigene assembly. The set of 246,182 sequences produced 46,345 unigenes, which were used to design a 44K 60-mer oligo array (Potato Oligo Chip Initiative: POCI). In this study, we attempt to identify genes controlling and driving the process of tuber initiation and growth by implementing large-scale transcriptional changes using the newly developed POCI array. Major gene expression profiles could be identified exhibiting differential expression at key developmental stages. These profiles were associated with functional roles in cell division and growth. A subset of genes involved in the regulation of the cell cycle, based on their Gene Ontology classification, exhibit a clear transient upregulation at tuber onset indicating increased cell division during these stages. The POCI array allows the study of potato gene expression on a much broader level than previously possible and will greatly enhance analysis of transcriptional control mechanisms in a wide range of potato research areas. POCI sequence and annotation data are publicly available through the POCI database

Published
2008

26. The transcriptional landscape of polyploid wheat.

Author

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., and Ridout, C. J.

Published
2018

27. A barley MLA immune receptor is activated by a fungal nonribosomal peptide effector for disease susceptibility.

Author

Leng Y, Kümmel F, Zhao M, Molnár I, Doležel J, Logemann E, Köchner P, Xi P, Yang S, Moscou MJ, Fiedler JD, Du Y, Steuernagel B, Meinhardt S, Steffenson BJ, Schulze-Lefert P, and Zhong S

Subjects
Disease Susceptibility, Phylogeny, Plants, Genetically Modified, Fungal Proteins metabolism, Fungal Proteins genetics, Receptors, Immunologic metabolism, Genes, Plant, Protein Domains, Hordeum microbiology, Hordeum genetics, Hordeum immunology, Plant Proteins metabolism, Plant Proteins genetics, Plant Diseases microbiology, Plant Diseases immunology, Ascomycota pathogenicity, Ascomycota physiology, Peptides metabolism
Abstract

The barley Mla locus contains functionally diversified genes that encode intracellular nucleotide-binding leucine-rich repeat receptors (NLRs) and confer strain-specific immunity to biotrophic and hemibiotrophic fungal pathogens. In this study, we isolated a barley gene Scs6, which is an allelic variant of Mla genes but confers susceptibility to the isolate ND90Pr (Bs ND90Pr ) of the necrotrophic fungus Bipolaris sorokiniana. We generated Scs6 transgenic barley lines and showed that Scs6 is sufficient to confer susceptibility to Bs ND90Pr in barley genotypes naturally lacking the receptor. The Scs6-encoded NLR (SCS6) is activated by a nonribosomal peptide (NRP) effector produced by Bs ND90Pr to induce cell death in barley and Nicotiana benthamiana. Domain swaps between MLAs and SCS6 reveal that the SCS6 leucine-rich repeat domain is a specificity determinant for receptor activation by the NRP effector. Scs6 is maintained in both wild and domesticated barley populations. Our phylogenetic analysis suggests that Scs6 is a Hordeum-specific innovation. We infer that SCS6 is a bona fide immune receptor that is likely directly activated by the nonribosomal peptide effector of Bs ND90Pr for disease susceptibility in barley. Our study provides a stepping stone for the future development of synthetic NLR receptors in crops that are less vulnerable to modification by necrotrophic pathogens., (© 2024 The Author(s). New Phytologist © 2024 New Phytologist Foundation. This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.)

Published
2025
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28. Rebalancing the seed proteome following deletion of vicilin-related genes in pea (Pisum sativum L.).

Author

Rayner T, Saalbach G, Vickers M, Paajanen P, Martins C, Wouters RHM, Chinoy C, Mulholland F, Bal M, Isaac P, Novak P, Macas J, Ellis N, Steuernagel B, and Domoney C

Abstract

Null mutations for genes encoding a major seed storage protein in pea, vicilin, were sought through screening a fast-neutron mutant population. Deletion mutations at four or five vicilin loci, where all vicilin genes within each locus were deleted, were combined to address the question of how removal or reduction of a major storage protein and potential allergen might impact the final concentration of protein per unit mature seed weight, seed yield and viability. While the concentration of seed protein was not reduced in mature seeds of mutant lines, indicative of a re-balancing of the proteome, notable differences were apparent in the metabolite, proteomic and amino acid profiles of the seeds, as well as in some functional properties. Major effects of the deletions on the proteome were documented. The genomic regions which were deleted were defined by whole genome sequencing of the parental line, JI2822 and its quintuple vicilin null derivative, providing a comprehensive description of each vicilin locus and its genic arrangement. An annotated reference genome has been generated for JI2822, which will serve as a very valuable resource for the research community and support further study of the associated deletion mutant population., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published
2024
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29. A chromosome-scale reference genome of grasspea (Lathyrus sativus).

Author

Vigouroux M, Novák P, Oliveira LC, Santos C, Cheema J, Wouters RHM, Paajanen P, Vickers M, Koblížková A, Vaz Patto MC, Macas J, Steuernagel B, Martin C, and Emmrich PMF

Subjects
Lathyrus genetics, Genome, Plant, Chromosomes, Plant genetics
Abstract

Grasspea (Lathyrus sativus L.) is an underutilised but promising legume crop with tolerance to a wide range of abiotic and biotic stress factors, and potential for climate-resilient agriculture. Despite a long history and wide geographical distribution of cultivation, only limited breeding resources are available. This paper reports a 5.96 Gbp genome assembly of grasspea genotype LS007, of which 5.03 Gbp is scaffolded into 7 pseudo-chromosomes. The assembly has a BUSCO completeness score of 99.1% and is annotated with 31719 gene models and repeat elements. This represents the most contiguous and accurate assembly of the grasspea genome to date., (© 2024. The Author(s).)

Published
2024
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30. An optimised CRISPR Cas9 and Cas12a mutagenesis toolkit for Barley and Wheat.

Author

Lawrenson T, Clarke M, Kirby R, Forner M, Steuernagel B, Brown JKM, and Harwood W

Abstract

Background: CRISPR Cas9 and Cas12a are the two most frequently used programmable nucleases reported in plant systems. There is now a wide range of component parts for both which likely have varying degrees of effectiveness and potentially applicability to different species. Our aim was to develop and optimise Cas9 and Cas12a based systems for highly efficient genome editing in the monocotyledons barley and wheat and produce a user-friendly toolbox facilitating simplex and multiplex editing in the cereal community., Results: We identified a Zea mays codon optimised Cas9 with 13 introns in conjunction with arrayed guides driven by U6 and U3 promoters as the best performer in barley where 100% of T0 plants were simultaneously edited in all three target genes. When this system was used in wheat > 90% of T0 plants were edited in all three subgenome targets. For Cas12a, an Arabidopsis codon optimised sequence with 8 introns gave the best editing efficiency in barley when combined with a tRNA based multiguide array, resulting in 90% mutant alleles in three simultaneously targeted genes. When we applied this Cas12a system in wheat 86% & 93% of T0 plants were mutated in two genes simultaneously targeted. We show that not all introns contribute equally to enhanced mutagenesis when inserted into a Cas12a coding sequence and that there is rationale for including multiple introns. We also show that the combined effect of two features which boost Cas12a mutagenesis efficiency (D156R mutation and introns) is more than the sum of the features applied separately., Conclusion: Based on the results of our testing, we describe and provide a GoldenGate modular cloning system for Cas9 and Cas12a use in barley and wheat. Proven Cas nuclease and guide expression cassette options found in the toolkit will facilitate highly efficient simplex and multiplex mutagenesis in both species. We incorporate GRF-GIF transformation boosting cassettes in wheat options to maximise workflow efficiency., (© 2024. Crown.)

Published
2024
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31. Harnessing landrace diversity empowers wheat breeding.

Author

Cheng S, Feng C, Wingen LU, Cheng H, Riche AB, Jiang M, Leverington-Waite M, Huang Z, Collier S, Orford S, Wang X, Awal R, Barker G, O'Hara T, Lister C, Siluveru A, Quiroz-Chávez J, Ramírez-González RH, Bryant R, Berry S, Bansal U, Bariana HS, Bennett MJ, Bicego B, Bilham L, Brown JKM, Burridge A, Burt C, Buurman M, Castle M, Chartrain L, Chen B, Denbel W, Elkot AF, Fenwick P, Feuerhelm D, Foulkes J, Gaju O, Gauley A, Gaurav K, Hafeez AN, Han R, Horler R, Hou J, Iqbal MS, Kerton M, Kondic-Spica A, Kowalski A, Lage J, Li X, Liu H, Liu S, Lovegrove A, Ma L, Mumford C, Parmar S, Philp C, Playford D, Przewieslik-Allen AM, Sarfraz Z, Schafer D, Shewry PR, Shi Y, Slafer GA, Song B, Song B, Steele D, Steuernagel B, Tailby P, Tyrrell S, Waheed A, Wamalwa MN, Wang X, Wei Y, Winfield M, Wu S, Wu Y, Wulff BBH, Xian W, Xu Y, Xu Y, Yuan Q, Zhang X, Edwards KJ, Dixon L, Nicholson P, Chayut N, Hawkesford MJ, Uauy C, Sanders D, Huang S, and Griffiths S

Subjects
Alleles, Genetic Introgression, Genome, Plant genetics, Haplotypes genetics, Linkage Disequilibrium genetics, Quantitative Trait Loci genetics, Whole Genome Sequencing, Phylogeny, Genetic Association Studies, Food Security, Crops, Agricultural genetics, Genetic Variation genetics, Phenotype, Plant Breeding methods, Triticum classification, Triticum genetics, Biodiversity
Abstract

Harnessing genetic diversity in major staple crops through the development of new breeding capabilities is essential to ensure food security 1 . Here we examined the genetic and phenotypic diversity of the A. E. Watkins landrace collection 2 of bread wheat (Triticum aestivum), a major global cereal, by whole-genome re-sequencing of 827 Watkins landraces and 208 modern cultivars and in-depth field evaluation spanning a decade. We found that modern cultivars are derived from two of the seven ancestral groups of wheat and maintain very long-range haplotype integrity. The remaining five groups represent untapped genetic sources, providing access to landrace-specific alleles and haplotypes for breeding. Linkage disequilibrium-based haplotypes and association genetics analyses link Watkins genomes to the thousands of identified high-resolution quantitative trait loci and significant marker-trait associations. Using these structured germplasm, genotyping and informatics resources, we revealed many Watkins-unique beneficial haplotypes that can confer superior traits in modern wheat. Furthermore, we assessed the phenotypic effects of 44,338 Watkins-unique haplotypes, introgressed from 143 prioritized quantitative trait loci in the context of modern cultivars, bridging the gap between landrace diversity and current breeding. This study establishes a framework for systematically utilizing genetic diversity in crop improvement to achieve sustainable food security., (© 2024. The Author(s).)

Published
2024
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32. A complex receptor locus confers responsiveness to necrosis and ethylene-inducing like peptides in Brassica napus.

Author

Yalcin HA, Jacott CN, Ramirez-Gonzalez RH, Steuernagel B, Sidhu GS, Kirby R, Verbeek E, Schoonbeek HJ, Ridout CJ, and Wells R

Subjects
Botrytis physiology, Reactive Oxygen Species metabolism, Peptides metabolism, Peptides genetics, Gene Expression Regulation, Plant, Chromosome Mapping, Ethylenes metabolism, Brassica napus genetics, Brassica napus microbiology, Brassica napus metabolism, Plant Diseases microbiology, Plant Diseases genetics, Plant Diseases immunology, Disease Resistance genetics, Plant Proteins genetics, Plant Proteins metabolism
Abstract

Brassica crops are susceptible to diseases which can be mitigated by breeding for resistance. MAMPs (microbe-associated molecular patterns) are conserved molecules of pathogens that elicit host defences known as pattern-triggered immunity (PTI). Necrosis and Ethylene-inducing peptide 1-like proteins (NLPs) are MAMPs found in a wide range of phytopathogens. We studied the response to BcNEP2, a representative NLP from Botrytis cinerea, and showed that it contributes to disease resistance in Brassica napus. To map regions conferring NLP response, we used the production of reactive oxygen species (ROS) induced during PTI across a population of diverse B. napus accessions for associative transcriptomics (AT), and bulk segregant analysis (BSA) on DNA pools created from a cross of NLP-responsive and non-responsive lines. In silico mapping with AT identified two peaks for NLP responsiveness on chromosomes A04 and C05 whereas the BSA identified one peak on A04. BSA delimited the region for NLP-responsiveness to 3 Mbp, containing ~245 genes on the Darmor-bzh reference genome and four co-segregating KASP markers were identified. The same pipeline with the ZS11 genome confirmed the highest-associated region on chromosome A04. Comparative BLAST analysis revealed unannotated clusters of receptor-like protein (RLP) homologues on ZS11 chromosome A04. However, no specific RLP homologue conferring NLP response could be identified. Our results also suggest that BR-SIGNALLING KINASE1 may be involved with modulating the NLP response. Overall, we demonstrate that responsiveness to NLP contributes to disease resistance in B. napus and define the associated genomic location. These results can have practical application in crop improvement., (© 2024 The Authors. The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published
2024
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33. Pathogen lifestyle determines host genetic signature of quantitative disease resistance loci in oilseed rape (Brassica napus).

Author

Jacott CN, Schoonbeek HJ, Sidhu GS, Steuernagel B, Kirby R, Zheng X, von Tiedermann A, Macioszek VK, Kononowicz AK, Fell H, Fitt BDL, Mitrousia GK, Stotz HU, Ridout CJ, and Wells R

Subjects
Plant Breeding, Disease Resistance genetics, Brassica napus genetics, Brassica napus microbiology
Abstract

Key Message: Using associative transcriptomics, our study identifies genes conferring resistance to four diverse fungal pathogens in crops, emphasizing key genetic determinants of multi-pathogen resistance. Crops are affected by several pathogens, but these are rarely studied in parallel to identify common and unique genetic factors controlling diseases. Broad-spectrum quantitative disease resistance (QDR) is desirable for crop breeding as it confers resistance to several pathogen species. Here, we use associative transcriptomics (AT) to identify candidate gene loci associated with Brassica napus constitutive QDR to four contrasting fungal pathogens: Alternaria brassicicola, Botrytis cinerea, Pyrenopeziza brassicae, and Verticillium longisporum. We did not identify any shared loci associated with broad-spectrum QDR to fungal pathogens with contrasting lifestyles. Instead, we observed QDR dependent on the lifestyle of the pathogen-hemibiotrophic and necrotrophic pathogens had distinct QDR responses and associated loci, including some loci associated with early immunity. Furthermore, we identify a genomic deletion associated with resistance to V. longisporum and potentially broad-spectrum QDR. This is the first time AT has been used for several pathosystems simultaneously to identify host genetic loci involved in broad-spectrum QDR. We highlight constitutive expressed candidate loci for broad-spectrum QDR with no antagonistic effects on susceptibility to the other pathogens studies as candidates for crop breeding. In conclusion, this study represents an advancement in our understanding of broad-spectrum QDR in B. napus and is a significant resource for the scientific community., (© 2024. The Author(s).)

Published
2024
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34. Single amino acid change alters specificity of the multi-allelic wheat stem rust resistance locus SR9.

Author

Zhang J, Nirmala J, Chen S, Jost M, Steuernagel B, Karafiatova M, Hewitt T, Li H, Edae E, Sharma K, Hoxha S, Bhatt D, Antoniou-Kourounioti R, Dodds P, Wulff BBH, Dolezel J, Ayliffe M, Hiebert C, McIntosh R, Dubcovsky J, Zhang P, Rouse MN, and Lagudah E

Subjects
Chromosome Mapping, Alleles, Haplotypes, Amino Acid Sequence, Plant Diseases genetics, Disease Resistance genetics, Basidiomycota genetics
Abstract

Most rust resistance genes thus far isolated from wheat have a very limited number of functional alleles. Here, we report the isolation of most of the alleles at wheat stem rust resistance gene locus SR9. The seven previously reported resistance alleles (Sr9a, Sr9b, Sr9d, Sr9e, Sr9f, Sr9g, and Sr9h) are characterised using a synergistic strategy. Loss-of-function mutants and/or transgenic complementation are used to confirm Sr9b, two haplotypes of Sr9e (Sr9e_h1 and Sr9e_h2), Sr9g, and Sr9h. Each allele encodes a highly related nucleotide-binding site leucine-rich repeat (NB-LRR) type immune receptor, containing an unusual long LRR domain, that confers resistance to a unique spectrum of isolates of the wheat stem rust pathogen. The only SR9 protein effective against stem rust pathogen race TTKSK (Ug99), SR9H, differs from SR9B by a single amino acid. SR9B and SR9G resistance proteins are also distinguished by only a single amino acid. The SR9 allelic series found in the B subgenome are orthologs of wheat stem rust resistance gene Sr21 located in the A subgenome with around 85% identity in protein sequences. Together, our results show that functional diversification of allelic variants at the SR9 locus involves single and multiple amino acid changes that recognize isolates of wheat stem rust., (© 2023. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published
2023
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35. Author Correction: Genomics and biochemical analyses reveal a metabolon key to β-L-ODAP biosynthesis in Lathyrus sativus.

Author

Edwards A, Njaci I, Sarkar A, Jiang Z, Kaithakottil GG, Moore C, Cheema J, Stevenson CEM, Rejzek M, Novák P, Vigouroux M, Vickers M, Wouters RHM, Paajanen P, Steuernagel B, Moore JD, Higgins J, Swarbreck D, Martens S, Kim CY, Weng JK, Mundree S, Kilian B, Kumar S, Loose M, Yant L, Macas J, Wang TL, Martin C, and Emmrich PMF

Published
2023
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36. The wheat stem rust resistance gene Sr43 encodes an unusual protein kinase.

Author

Yu G, Matny O, Gourdoupis S, Rayapuram N, Aljedaani FR, Wang YL, Nürnberger T, Johnson R, Crean EE, Saur IM, Gardener C, Yue Y, Kangara N, Steuernagel B, Hayta S, Smedley M, Harwood W, Patpour M, Wu S, Poland J, Jones JDG, Reuber TL, Ronen M, Sharon A, Rouse MN, Xu S, Holušová K, Bartoš J, Molnár I, Karafiátová M, Hirt H, Blilou I, Jaremko Ł, Doležel J, Steffenson BJ, and Wulff BBH

Subjects
Plant Diseases genetics, Plant Breeding, Genes, Plant, Disease Resistance genetics, Basidiomycota genetics
Abstract

To safeguard bread wheat against pests and diseases, breeders have introduced over 200 resistance genes into its genome, thus nearly doubling the number of designated resistance genes in the wheat gene pool 1 . Isolating these genes facilitates their fast-tracking in breeding programs and incorporation into polygene stacks for more durable resistance. We cloned the stem rust resistance gene Sr43, which was crossed into bread wheat from the wild grass Thinopyrum elongatum 2,3 . Sr43 encodes an active protein kinase fused to two domains of unknown function. The gene, which is unique to the Triticeae, appears to have arisen through a gene fusion event 6.7 to 11.6 million years ago. Transgenic expression of Sr43 in wheat conferred high levels of resistance to a wide range of isolates of the pathogen causing stem rust, highlighting the potential value of Sr43 in resistance breeding and engineering., (© 2023. The Author(s).)

Published
2023
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37. A wheat kinase and immune receptor form host-specificity barriers against the blast fungus.

Author

Arora S, Steed A, Goddard R, Gaurav K, O'Hara T, Schoen A, Rawat N, Elkot AF, Korolev AV, Chinoy C, Nicholson MH, Asuke S, Antoniou-Kourounioti R, Steuernagel B, Yu G, Awal R, Forner-Martínez M, Wingen L, Baggs E, Clarke J, Saunders DGO, Krasileva KV, Tosa Y, Jones JDG, Tiwari VK, Wulff BBH, and Nicholson P

Subjects
Plant Diseases genetics, Plant Diseases microbiology, Brazil, Bangladesh, Triticum genetics, Triticum microbiology, Magnaporthe
Abstract

Since emerging in Brazil in 1985, wheat blast has spread throughout South America and recently appeared in Bangladesh and Zambia. Here we show that two wheat resistance genes, Rwt3 and Rwt4, acting as host-specificity barriers against non-Triticum blast pathotypes encode a nucleotide-binding leucine-rich repeat immune receptor and a tandem kinase, respectively. Molecular isolation of these genes will enable study of the molecular interaction between pathogen effector and host resistance genes., (© 2023. The Author(s).)

Published
2023
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39. Genomics and biochemical analyses reveal a metabolon key to β-L-ODAP biosynthesis in Lathyrus sativus.

Author

Edwards A, Njaci I, Sarkar A, Jiang Z, Kaithakottil GG, Moore C, Cheema J, Stevenson CEM, Rejzek M, Novák P, Vigouroux M, Vickers M, Wouters RHM, Paajanen P, Steuernagel B, Moore JD, Higgins J, Swarbreck D, Martens S, Kim CY, Weng JK, Mundree S, Kilian B, Kumar S, Loose M, Yant L, Macas J, Wang TL, Martin C, and Emmrich PMF

Subjects
Neurotoxins metabolism, Genomics, Lathyrus genetics, Lathyrus metabolism, Amino Acids, Diamino metabolism
Abstract

Grass pea (Lathyrus sativus L.) is a rich source of protein cultivated as an insurance crop in Ethiopia, Eritrea, India, Bangladesh, and Nepal. Its resilience to both drought and flooding makes it a promising crop for ensuring food security in a changing climate. The lack of genetic resources and the crop's association with the disease neurolathyrism have limited the cultivation of grass pea. Here, we present an annotated, long read-based assembly of the 6.5 Gbp L. sativus genome. Using this genome sequence, we have elucidated the biosynthetic pathway leading to the formation of the neurotoxin, β-L-oxalyl-2,3-diaminopropionic acid (β-L-ODAP). The final reaction of the pathway depends on an interaction between L. sativus acyl-activating enzyme 3 (LsAAE3) and a BAHD-acyltransferase (LsBOS) that form a metabolon activated by CoA to produce β-L-ODAP. This provides valuable insight into the best approaches for developing varieties which produce substantially less toxin., (© 2023. The Author(s).)

Published
2023
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40. Haplotype variants of the stripe rust resistance gene Yr28 in Aegilops tauschii.

Author

Athiyannan N, Zhang P, McIntosh R, Chakraborty S, Hewitt T, Bhatt D, Forrest K, Upadhyaya N, Steuernagel B, Arora S, Huerta J, Hayden M, Wulff BBH, Ayliffe M, Hickey LT, Lagudah E, and Periyannan S

Subjects
Disease Resistance genetics, Plant Diseases genetics, Chromosome Mapping, Leucine genetics, Genes, Plant, Poaceae genetics, Nucleotides, Aegilops genetics, Basidiomycota physiology
Abstract

Key Message: Stripe rust resistance gene YrAet672 from Aegilops tauschii accession CPI110672 encodes a nucleotide-binding and leucine-rich repeat domain containing protein similar to YrAS2388 and both these members were haplotypes of Yr28. New sources of host resistance are required to counter the continued emergence of new pathotypes of the wheat stripe rust pathogen Puccinia striiformis Westend. f. sp. tritici Erikss. (Pst). Here, we show that CPI110672, an Aegilops tauschii accession from Turkmenistan, carries a single Pst resistance gene, YrAet672, that is effective against multiple Pst pathotypes, including the four predominant Pst lineages present in Australia. The YRAet672 locus was fine mapped to the short arm of chromosome 4D, and a nucleotide-binding and leucine-rich repeat gene was identified at the locus. A transgene encoding the YrAet672 genomic sequence, but lacking a copy of a duplicated sequence present in the 3' UTR, was transformed into wheat cultivar Fielder and Avocet S. This transgene conferred a weak resistance response, suggesting that the duplicated 3' UTR region was essential for function. Subsequent analyses demonstrated that YrAet672 is the same as two other Pst resistance genes described in Ae. tauschii, namely YrAS2388 and Yr28. They were identified as haplotypes encoding identical protein sequences but are polymorphic in non-translated regions of the gene. Suppression of resistance conferred by YrAet672 and Yr28 in synthetic hexaploid wheat lines (AABBDD) involving Langdon (AABB) as the tetraploid parent was associated with a reduction in transcript accumulation., (© 2022. Crown.)

Published
2022
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41. A catalogue of resistance gene homologs and a chromosome-scale reference sequence support resistance gene mapping in winter wheat.

Author

Kale SM, Schulthess AW, Padmarasu S, Boeven PHG, Schacht J, Himmelbach A, Steuernagel B, Wulff BBH, Reif JC, Stein N, and Mascher M

Subjects
Chromosome Mapping, Chromosomes, Disease Resistance genetics, Plant Diseases genetics, Plant Diseases microbiology, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Basidiomycota genetics, Triticum genetics, Triticum microbiology
Abstract

A resistance gene atlas is an integral component of the breeder's arsenal in the fight against evolving pathogens. Thanks to high-throughput sequencing, catalogues of resistance genes can be assembled even in crop species with large and polyploid genomes. Here, we report on capture sequencing and assembly of resistance gene homologs in a diversity panel of 907 winter wheat genotypes comprising ex situ genebank accessions and current elite cultivars. In addition, we use accurate long-read sequencing and chromosome conformation capture sequencing to construct a chromosome-scale genome sequence assembly of cv. Attraktion, an elite variety representative of European winter wheat. We illustrate the value of our resource for breeders and geneticists by (i) comparing the resistance gene complements in plant genetic resources and elite varieties and (ii) conducting genome-wide associations scans (GWAS) for the fungal diseases yellow rust and leaf rust using reference-based and reference-free GWAS approaches. The gene content under GWAS peaks was scrutinized in the assembly of cv. Attraktion., (© 2022 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd.)

Published
2022
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42. MicroRNA-resistant alleles of HOMEOBOX DOMAIN-2 modify inflorescence branching and increase grain protein content of wheat.

Author

Dixon LE, Pasquariello M, Badgami R, Levin KA, Poschet G, Ng PQ, Orford S, Chayut N, Adamski NM, Brinton J, Simmonds J, Steuernagel B, Searle IR, Uauy C, and Boden SA

Subjects
Alleles, Edible Grain genetics, Edible Grain metabolism, Gene Expression Regulation, Plant, Genes, Homeobox, Inflorescence genetics, Plant Proteins genetics, Plant Proteins metabolism, Triticum, Grain Proteins metabolism, MicroRNAs genetics, MicroRNAs metabolism
Abstract

Plant and inflorescence architecture determine the yield potential of crops. Breeders have harnessed natural diversity for inflorescence architecture to improve yields, and induced genetic variation could provide further gains. Wheat is a vital source of protein and calories; however, little is known about the genes that regulate the development of its inflorescence. Here, we report the identification of semidominant alleles for a class III homeodomain-leucine zipper transcription factor, HOMEOBOX DOMAIN-2 ( HB-2 ), on wheat A and D subgenomes, which generate more flower-bearing spikelets and enhance grain protein content. These alleles increase HB-2 expression by disrupting a microRNA 165/166 complementary site with conserved roles in plants; higher HB-2 expression is associated with modified leaf and vascular development and increased amino acid supply to the inflorescence during grain development. These findings enhance our understanding of genes that control wheat inflorescence development and introduce an approach to improve the nutritional quality of grain.

Published
2022
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43. Discovery of Resistance Genes in Rye by Targeted Long-Read Sequencing and Association Genetics.

Author

Vendelbo NM, Mahmood K, Steuernagel B, Wulff BBH, Sarup P, Hovmøller MS, Justesen AF, Kristensen PS, Orabi J, and Jahoor A

Subjects
Disease Resistance genetics, Genes, Plant, Genome-Wide Association Study, Plant Diseases genetics, Puccinia, Basidiomycota genetics, Secale genetics
Abstract

The majority of released rye cultivars are susceptible to leaf rust because of a low level of resistance in the predominant hybrid rye-breeding gene pools Petkus and Carsten. To discover new sources of leaf rust resistance, we phenotyped a diverse panel of inbred lines from the less prevalent Gülzow germplasm using six distinct isolates of Puccinia recondita f. sp. secalis and found that 55 out of 92 lines were resistant to all isolates. By performing a genome-wide association study using 261,406 informative SNP markers, we identified five resistance-associated QTLs on chromosome arms 1RS, 1RL, 2RL, 5RL and 7RS. To identify candidate Puccinia recondita ( Pr ) resistance genes in these QTLs, we sequenced the rye nucleotide-binding leucine-rich repeat (NLR) intracellular immune receptor complement using a Triticeae NLR bait-library and PacBio ® long-read single-molecule high-fidelity (HiFi) sequencing. Trait-genotype correlations across 10 resistant and 10 susceptible lines identified four candidate NLR-encoding Pr genes. One of these physically co-localized with molecular markers delimiting Pr3 on chromosome arm 1RS and the top-most resistance-associated QTL in the panel.

Published
2022
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44. Genome sequences of three Aegilops species of the section Sitopsis reveal phylogenetic relationships and provide resources for wheat improvement.

Author

Avni R, Lux T, Minz-Dub A, Millet E, Sela H, Distelfeld A, Deek J, Yu G, Steuernagel B, Pozniak C, Ens J, Gundlach H, Mayer KFX, Himmelbach A, Stein N, Mascher M, Spannagl M, Wulff BBH, and Sharon A

Subjects
Genome, Plant genetics, Phylogeny, Poaceae genetics, Triticum genetics, Aegilops genetics
Abstract

Aegilops is a close relative of wheat (Triticum spp.), and Aegilops species in the section Sitopsis represent a rich reservoir of genetic diversity for the improvement of wheat. To understand their diversity and advance their utilization, we produced whole-genome assemblies of Aegilops longissima and Aegilops speltoides. Whole-genome comparative analysis, along with the recently sequenced Aegilops sharonensis genome, showed that the Ae. longissima and Ae. sharonensis genomes are highly similar and are most closely related to the wheat D subgenome. By contrast, the Ae. speltoides genome is more closely related to the B subgenome. Haplotype block analysis supported the idea that Ae. speltoides genome is closest to the wheat B subgenome, and highlighted variable and similar genomic regions between the three Aegilops species and wheat. Genome-wide analysis of nucleotide-binding leucine-rich repeat (NLR) genes revealed species-specific and lineage-specific NLR genes and variants, demonstrating the potential of Aegilops genomes for wheat improvement., (© 2022 The Authors. The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published
2022
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45. Characterisation of the Introgression of Brassica villosa Genome Into Broccoli to Enhance Methionine-Derived Glucosinolates and Associated Health Benefits.

Author

Neequaye M, Steuernagel B, Saha S, Trick M, Troncoso-Rey P, van den Bosch F, Traka MH, Østergaard L, and Mithen R

Abstract

Broccoli cultivars that have enhanced accumulation of methionine-derived glucosinolates have been developed through the introgression of a novel allele of the MYB28 transcription factor from the wild species Brassica villosa . Through a novel k-mer approach, we characterised the extent of the introgression of unique B. villosa genome sequences into high glucosinolate broccoli genotypes. RNAseq analyses indicated that the introgression of the B. villosa MYB28 C2 allele resulted in the enhanced expression of the MYB28 transcription factor, and modified expression of genes associated with sulphate absorption and reduction, and methionine and glucosinolate biosynthesis when compared to standard broccoli. A adenine-thymine (AT) short tandem repeat (STR) was identified within the 5' untranslated region (UTR) B. villosa MYB28 allele that was absent from two divergent cultivated forms of Brassica oleracea , which may underpin the enhanced expression of B. villosa MYB28 ., Competing Interests: The broccoli with elevated glucoraphanin is the subject of patents filed by Plant Bioscience Limited (PBL), the technology transfer company of the John Innes Centre. RM and MHT are inventors named on these patents. FB was employed by Bayer. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Neequaye, Steuernagel, Saha, Trick, Troncoso-Rey, van den Bosch, Traka, Østergaard and Mithen.)

Published
2022
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46. Aegilops sharonensis genome-assisted identification of stem rust resistance gene Sr62.

Author

Yu G, Matny O, Champouret N, Steuernagel B, Moscou MJ, Hernández-Pinzón I, Green P, Hayta S, Smedley M, Harwood W, Kangara N, Yue Y, Gardener C, Banfield MJ, Olivera PD, Welchin C, Simmons J, Millet E, Minz-Dub A, Ronen M, Avni R, Sharon A, Patpour M, Justesen AF, Jayakodi M, Himmelbach A, Stein N, Wu S, Poland J, Ens J, Pozniak C, Karafiátová M, Molnár I, Doležel J, Ward ER, Reuber TL, Jones JDG, Mascher M, Steffenson BJ, and Wulff BBH

Subjects
Disease Resistance genetics, Genes, Plant genetics, Plant Breeding, Plant Diseases genetics, Triticum genetics, Aegilops genetics, Basidiomycota genetics
Abstract

The wild relatives and progenitors of wheat have been widely used as sources of disease resistance (R) genes. Molecular identification and characterization of these R genes facilitates their manipulation and tracking in breeding programmes. Here, we develop a reference-quality genome assembly of the wild diploid wheat relative Aegilops sharonensis and use positional mapping, mutagenesis, RNA-Seq and transgenesis to identify the stem rust resistance gene Sr62, which has also been transferred to common wheat. This gene encodes a tandem kinase, homologues of which exist across multiple taxa in the plant kingdom. Stable Sr62 transgenic wheat lines show high levels of resistance against diverse isolates of the stem rust pathogen, highlighting the utility of Sr62 for deployment as part of a polygenic stack to maximize the durability of stem rust resistance., (© 2022. The Author(s).)

Published
2022
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47. Population genomic analysis of Aegilops tauschii identifies targets for bread wheat improvement.

Author

Gaurav K, Arora S, Silva P, Sánchez-Martín J, Horsnell R, Gao L, Brar GS, Widrig V, John Raupp W, Singh N, Wu S, Kale SM, Chinoy C, Nicholson P, Quiroz-Chávez J, Simmonds J, Hayta S, Smedley MA, Harwood W, Pearce S, Gilbert D, Kangara N, Gardener C, Forner-Martínez M, Liu J, Yu G, Boden SA, Pascucci A, Ghosh S, Hafeez AN, O'Hara T, Waites J, Cheema J, Steuernagel B, Patpour M, Justesen AF, Liu S, Rudd JC, Avni R, Sharon A, Steiner B, Kirana RP, Buerstmayr H, Mehrabi AA, Nasyrova FY, Chayut N, Matny O, Steffenson BJ, Sandhu N, Chhuneja P, Lagudah E, Elkot AF, Tyrrell S, Bian X, Davey RP, Simonsen M, Schauser L, Tiwari VK, Randy Kutcher H, Hucl P, Li A, Liu DC, Mao L, Xu S, Brown-Guedira G, Faris J, Dvorak J, Luo MC, Krasileva K, Lux T, Artmeier S, Mayer KFX, Uauy C, Mascher M, Bentley AR, Keller B, Poland J, and Wulff BBH

Subjects
Bread, Genomics, Metagenomics, Plant Breeding, Triticum genetics, Aegilops genetics
Abstract

Aegilops tauschii, the diploid wild progenitor of the D subgenome of bread wheat, is a reservoir of genetic diversity for improving bread wheat performance and environmental resilience. Here we sequenced 242 Ae. tauschii accessions and compared them to the wheat D subgenome to characterize genomic diversity. We found that a rare lineage of Ae. tauschii geographically restricted to present-day Georgia contributed to the wheat D subgenome in the independent hybridizations that gave rise to modern bread wheat. Through k-mer-based association mapping, we identified discrete genomic regions with candidate genes for disease and pest resistance and demonstrated their functional transfer into wheat by transgenesis and wide crossing, including the generation of a library of hexaploids incorporating diverse Ae. tauschii genomes. Exploiting the genomic diversity of the Ae. tauschii ancestral diploid genome permits rapid trait discovery and functional genetic validation in a hexaploid background amenable to breeding., (© 2021. The Author(s).)

Published
2022
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48. An Integrated Linkage Map of Three Recombinant Inbred Populations of Pea ( Pisum sativum L.).

Author

Sawada C, Moreau C, Robinson GHJ, Steuernagel B, Wingen LU, Cheema J, Sizer-Coverdale E, Lloyd D, Domoney C, and Ellis N

Subjects
Chromosome Mapping, Genetic Linkage, Phenotype, Pisum sativum genetics, Quantitative Trait Loci
Abstract

Biparental recombinant inbred line (RIL) populations are sets of genetically stable lines and have a simple population structure that facilitates the dissection of the genetics of interesting traits. On the other hand, populations derived from multiparent intercrosses combine both greater diversity and higher numbers of recombination events than RILs. Here, we describe a simple population structure: a three-way recombinant inbred population combination. This structure was easy to produce and was a compromise between biparental and multiparent populations. We show that this structure had advantages when analyzing cultivar crosses, and could achieve a mapping resolution of a few genes.

Published
2022
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49. Validation of a novel associative transcriptomics pipeline in Brassica oleracea: identifying candidates for vernalisation response.

Author

Woodhouse S, He Z, Woolfenden H, Steuernagel B, Haerty W, Bancroft I, Irwin JA, Morris RJ, and Wells R

Subjects
Genome-Wide Association Study, Plant Breeding, Transcriptome, Brassica genetics, Brassica napus genetics
Abstract

Background: Associative transcriptomics has been used extensively in Brassica napus to enable the rapid identification of markers correlated with traits of interest. However, within the important vegetable crop species, Brassica oleracea, the use of associative transcriptomics has been limited due to a lack of fixed genetic resources and the difficulties in generating material due to self-incompatibility. Within Brassica vegetables, the harvestable product can be vegetative or floral tissues and therefore synchronisation of the floral transition is an important goal for growers and breeders. Vernalisation is known to be a key determinant of the floral transition, yet how different vernalisation treatments influence flowering in B. oleracea is not well understood., Results: Here, we present results from phenotyping a diverse set of 69 B. oleracea accessions for heading and flowering traits under different environmental conditions. We developed a new associative transcriptomics pipeline, and inferred and validated a population structure, for the phenotyped accessions. A genome-wide association study identified miR172D as a candidate for the vernalisation response. Gene expression marker association identified variation in expression of BoFLC.C2 as a further candidate for vernalisation response., Conclusions: This study describes a new pipeline for performing associative transcriptomics studies in B. oleracea. Using flowering time as an example trait, it provides insights into the genetic basis of vernalisation response in B. oleracea through associative transcriptomics and confirms its characterisation as a complex G x E trait. Candidate leads were identified in miR172D and BoFLC.C2. These results could facilitate marker-based breeding efforts to produce B. oleracea lines with more synchronous heading dates, potentially leading to improved yields., (© 2021. The Author(s).)

Published
2021
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50. A recombined Sr26 and Sr61 disease resistance gene stack in wheat encodes unrelated NLR genes.

Author

Zhang J, Hewitt TC, Boshoff WHP, Dundas I, Upadhyaya N, Li J, Patpour M, Chandramohan S, Pretorius ZA, Hovmøller M, Schnippenkoetter W, Park RF, Mago R, Periyannan S, Bhatt D, Hoxha S, Chakraborty S, Luo M, Dodds P, Steuernagel B, Wulff BBH, Ayliffe M, McIntosh RA, Zhang P, and Lagudah ES

Subjects
Chromosomes, Plant genetics, Genes, Plant, Genetic Engineering, Genetic Markers, Plant Breeding methods, Plant Diseases genetics, Plant Diseases microbiology, Plant Proteins genetics, Plant Stems microbiology, Plants, Genetically Modified genetics, Puccinia isolation & purification, Triticum genetics, Disease Resistance genetics, NLR Proteins genetics, Plants, Genetically Modified microbiology, Puccinia pathogenicity, Triticum microbiology
Abstract

The re-emergence of stem rust on wheat in Europe and Africa is reinforcing the ongoing need for durable resistance gene deployment. Here, we isolate from wheat, Sr26 and Sr61, with both genes independently introduced as alien chromosome introgressions from tall wheat grass (Thinopyrum ponticum). Mutational genomics and targeted exome capture identify Sr26 and Sr61 as separate single genes that encode unrelated (34.8%) nucleotide binding site leucine rich repeat proteins. Sr26 and Sr61 are each validated by transgenic complementation using endogenous and/or heterologous promoter sequences. Sr61 orthologs are absent from current Thinopyrum elongatum and wheat pan genome sequences, contrasting with Sr26 where homologues are present. Using gene-specific markers, we validate the presence of both genes on a single recombinant alien segment developed in wheat. The co-location of these genes on a small non-recombinogenic segment simplifies their deployment as a gene stack and potentially enhances their resistance durability.

Published
2021
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