Your search keyword '"Institute of Plant Science and Resources"' showing total 867 results

1. 50-plus years of fungal viruses

Author

Suzuki, Nobuhiro [Institute of Plant Science and Resources, Okayama University, Kurashiki, Okayama (Japan)]

Published

2015

2. Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

Author

Jörg Schaller, Robin Heimes, Ji Feng Shao, Jian Feng Ma, Klaus-Holger Knorr, Jean-Dominique Meunier, Miho Fujii-Kashino, Technische Universität DresdenTharandt, Faculty of Environmental Sciences, Centre européen de recherche et d'enseignement des géosciences de l'environnement (CEREGE), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Collège de France (CdF)-Institut national des sciences de l'Univers (INSU - CNRS)-Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA), Bayreuth Center of Ecology and Environmental Research (BayCEER), Institute of Plant Science and Resources, Okayama University, Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Collège de France (CdF (institution))-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Recherche Agronomique (INRA), University of Münster, Institut de Recherche pour le Développement (IRD)-Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), and Westfälische Wilhelms-Universität Münster = University of Münster (WWU)

Subjects

Carbon compounds, inorganic chemicals, 0106 biological sciences, Silicon, Rice pigmentation, Soil Science, chemistry.chemical_element, Biomass, Plant Science, [SDV.SA.SDS]Life Sciences [q-bio]/Agricultural sciences/Soil study, complex mixtures, 01 natural sciences, chemistry.chemical_compound, Carbon quality, Lignin, Compounds of carbon, Rice plant tissues, Cellulose, ComputingMilieux_MISCELLANEOUS, 2. Zero hunger, chemistry.chemical_classification, Wax, fungi, technology, industry, and agriculture, Red rice, food and beverages, Silica, 04 agricultural and veterinary sciences, 15. Life on land, Horticulture, chemistry, visual_art, 040103 agronomy & agriculture, visual_art.visual_art_medium, 0401 agriculture, forestry, and fisheries, [SDU.OTHER]Sciences of the Universe [physics]/Other, Carbon, 010606 plant biology & botany

Abstract

International audience; Background and aim Silicon is known to be able to substitute carbon in plant biomass, especially in cellulose, lignin and phenols. However, a more comprehensive picture regarding the effect of silicon accumulation on plant carbon quality (cellu-lose, lignin, phenol, wax, lipids, and free organic acids content) with regard to potential decompos-ability is still missing. Methods Two different rice varieties (French brown and red rice cultivars) were cultivated under five different soil silicon availabilities. After maturity we harvested the plants and analyzed them regarding carbon quality by FTIR spectroscopy and regarding plant silicon concentrations. Results Silicon accumulation was found to be dependent on silicon availability and on the specific rice cultivar. The lowering of carbon compounds content by silicon was found not to be restricted to cellulose, lignin and phenol. Silicon accumulation was able to decrease other carbon compounds such as fat, wax, lipids, and free organic acids, too. Conclusions Consequently, silicon is important for the carbon quality of silicon accumulating plants. Furthermore , silicon accumulation in plants is interfering with a large range of different carbon compounds potentially altering the leaf economic spectra, decomposability, and thus potentially interfering with the whole performance of ecosystems dominated by silicon accumulating plant species.

Published

2019

3. Editorial: Use of Barley and Wheat Reference Sequences: Downstream Applications in Breeding, Gene Isolation, GWAS, and Evolution

Author

Pierre Sourdille, Dragan Perovic, Kazuhiro Sato, Hikmet Budak, Institut for Resistance Research and Stress Tolerance, Julius Kühn-Institut - Federal Research Centre for Cultivated Plants (JKI), Montana Bioagriculture Inc, Institute of Plant Science and Resources-Kurashiki (IPSR), Okayama University, Génétique Diversité et Ecophysiologie des Céréales (GDEC), Université Clermont Auvergne [2017-2020] (UCA [2017-2020])-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), German Federal Ministry of Education and Research [031B0199B], German Federal Ministry of Nutrition and Agriculture [2818410B18], and Agrogen, LLC, USA.

Subjects

0106 biological sciences, Genome reference sequence, Gene isolation, [SDV]Life Sciences [q-bio], Genome-wide association study, Plant Science, lcsh:Plant culture, Biology, Breeding, 01 natural sciences, [SDV.GEN.GPL]Life Sciences [q-bio]/Genetics/Plants genetics, 03 medical and health sciences, Downstream (manufacturing), Barley, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, lcsh:SB1-1110, Gene, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, 2. Zero hunger, Genetics, 0303 health sciences, [SDV.GEN]Life Sciences [q-bio]/Genetics, Isolation (microbiology), Editorial, Wheat, 010606 plant biology & botany

Abstract

International audience

Published

2020

4. Taxonomy of the order Mononegavirales: update 2018

Author

Kang Seuk Choi, Nikos Vasilakis, Claudio Verdugo, Janusz T. Paweska, Thomas Briese, Víctor Manuel Neira Ramírez, Andrew J. Bennett, Masayuki Horie, Charles H. Calisher, Robert Kityo, Anthony R. Fooks, Martin Schwemmle, Sunil K. Mor, Nidia G. Aréchiga Ceballos, Timothy H. Hyndman, Ayato Takada, Yíngyún Caì, Robert A. Lamb, Alexander Bukreyev, Paul A. Rota, Tony L. Goldberg, Lin-Fa Wang, Benhur Lee, Kartik Chandran, Hideki Ebihara, Michael R. Wiley, Ralf G. Dietzgen, Anna E. Whitfield, Mark D. Stenglein, Piet Maes, Andrew J. Easton, Jean L. Patterson, Valerian V. Dolja, Olga Dolnik, Eugene V. Koonin, James F. X. Wellehan, Ralf Dürrwald, Peter L. Collins, Qisheng Song, Susan Payne, Jonathan S. Towner, Sina Bavari, Sonia Vázquez-Morón, Pierre Formenty, Sophie J. Smither, Keizō Tomonaga, Leslie L. Domier, Dàohóng Jiāng, Gael Kurath, Robert B. Tesh, Sergey V. Netesov, Elodie Ghedin, Andrea Maisner, Denise A. Marston, Cristine Campos Lawson, Elke Mühlberger, Christopher F. Basler, Conrad M. Freuling, Yǒng Zhèn Zhāng, Dennis Rubbenstroth, Peter J. Walker, Gōngyín Yè, David Wang, Ron A. M. Fouchier, Gustavo Palacios, Gary P. Kobinger, Yuri I. Wolf, Timothy Song, Hideki Kondō, Mart Krupovic, Karla Prieto, David M. Stone, Luciano M. Thomazelli, Colin A. Chapman, Ashley C. Banyard, Jens H. Kuhn, Stuart G. Siddell, Noël Tordo, John M. Dye, Terry Fei Fan Ng, Charles Y. Chiu, Kim R. Blasdell, Bertus K. Rima, Victoria Wahl, Eric M. Leroy, Gaya K. Amarasinghe, Juan Emilio Echevarría, Norbert Nowotny, Roger Hewson, Thomas Müller, Viktor E. Volchkov, Washington University School of Medicine (WUSM), University of Washington [Seattle], Laboratorio de Rabia, Instituto de Diagnóstico y Referencias Epidemiológicos, Animal and Plant Health Agency [Weybridge] (APHA), Georgia State University, University System of Georgia (USG), U.S. Army Medical Research Institute of Infectious Diseases (USAMRIID), School of Veterinary Medicine, Department of Pathobiological Sciences, University of Wisconsin-Madison-Influenza Research Institute, Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Columbia Mailman School of Public Health, Columbia University [New York], The University of Texas Medical Branch (UTMB), Integrated Research Facility at Fort Detrick, National Institute of Allergy and Infectious Diseases, National Institutes of Health, College of Veterinary Medicine and Biomedical Sciences, Colorado State University [Fort Collins] (CSU), Albert Einstein College of Medicine [New York], Department of Anthropology [Montréal], McGill University = Université McGill [Montréal, Canada], Wildlife Conservation Society (WCS), Primate Research Institute, Kyoto University, University of California [San Francisco] (UC San Francisco), University of California (UC), Avian Disease Research Division, Animal and Plant Quarantine Agency, National Institute of Allergy and Infectious Diseases [Bethesda] (NIAID-NIH), National Institutes of Health [Bethesda] (NIH), Queensland Alliance for Agriculture and Food Innovation (QAAFI), University of Queensland [Brisbane], Department of Botany and Plant Pathology, Oregon State University (OSU), Center for Genome Research and Biocomputing, Philipps Universität Marburg = Philipps University of Marburg, University of Chicago, IDT Biologika, School of Life Sciences, University of Warwick [Coventry], Department of Biochemistry and Molecular Biology, University of Rochester [USA], Institute of Health Carlos III, Organisation Mondiale de la Santé / World Health Organization Office (OMS / WHO), Department of Viroscience [Rotterdam, The Netherlands], Erasmus University Medical Center [Rotterdam] (Erasmus MC), Institute of Molecular Virology and Cell Biology, Federal Research Institute for Animal Health - Friedrich-Loeffler-Institut, Center for Genomics and Systems Biology, Department of Biology [New York], New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU)-New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU), Public Health England [Salisbury] (PHE), Kagoshima University, Murdoch University, State Key Laboratory of Agricultural Microbiology, Huazhong Agricultural University [Wuhan] (HZAU), Makerere University [Kampala, Ouganda] (MAK), Research Centre in Infectious Diseases, CHUL Research Centre and Department of Microbiology and Immunology, Université Laval [Québec] (ULaval)-Faculty of Medicine, Institute of Plant Science and Resources, Okayama University, National Center for Biotechnology Information (NCBI), Biologie Moléculaire du Gène chez les Extrêmophiles (BMGE), Institut Pasteur [Paris] (IP), US Geological Survey [Seattle], United States Geological Survey [Reston] (USGS), Northwestern University [Evanston], Icahn School of Medicine at Mount Sinai [New York] (MSSM), Centre International de Recherches Médicales de Franceville (CIRMF), Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Neuromuscular Diagnostic Laboratory, University of Minnesota [Twin Cities] (UMN), University of Minnesota System-University of Minnesota System, Boston University School of Medicine (BUSM), Boston University [Boston] (BU), Universidad de Chile = University of Chile [Santiago] (UCHILE), Novosibirsk State University (NSU), Department of Medicine [San Francisco], University of California (UC)-University of California (UC), University of Veterinary Medicine [Vienna] (Vetmeduni), Mohammed Bin Rashid University of Medicine and Health Sciences (MBRU), Texas Biomedical Research Institute [San Antonio, TX], National Institute for Communicable Diseases [Johannesburg] (NICD), Queen's University [Belfast] (QUB), National Center for Immunization and Respiratory Diseases, CDC, Centers for Disease Control and Prevention (CDC), University of Freiburg [Freiburg], University of Bristol [Bristol], Defence Science and Technology Laboratory (Dstl), Ministry of Defence (UK) (MOD), University of Missouri [Columbia] (Mizzou), University of Missouri System, Department of Microbiology, Immunology and Pathology, Centre for Environment, Fisheries and Aquaculture Science [Weymouth] (CEFAS), Hokkaido University [Sapporo, Japan], Universidade de São Paulo - USP (BRAZIL), Institute for Virus Research, Stratégies antivirales, Institut Pasteur de Guinée, Réseau International des Instituts Pasteur (RIIP), Viral Special Pathogens Branch, Centers for Disease Control and Prevention-WHO Collaborative Centre for Viral Hemorrhagic Fevers, Facultad de Ciencias Veterinarias [Buenos Aires], Universidad de Buenos Aires [Buenos Aires] (UBA), Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity (BMPV), Centre International de Recherche en Infectiologie (CIRI), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), National Biodefense Analysis and Countermeasures Center [Frederick], U.S. Social Security Administration, CSIRO Health & Biosecurity, Department of Agriculture, Fisheries and Forestry, Ecoscience Precinct, GPO Box 267, Brisbane, Duke-NUS Medical School [Singapore], University of Florida [Gainesville] (UF), University of Nebraska Medical Center, University of Nebraska System, Kansas State University, State Key Laboratory of Rice Biology, China National Rice Research Institute, Chinese Academy of Agricultural Sciences (CAAS), State Key Laboratory for Infectious Disease prevention and Control, Beijing Institute of Technology (BIT), Army Medical Research Institute of Infectious Diseases [USA] (USAMRIID), Albert Einstein College of Medicine, McGill University, Kyoto University [Kyoto], University of California [San Francisco] (UCSF), University of California, Queensland Alliance for Agriculture and Food Innovation, University of Queensland (UQ), Philipps University of Marburg, Warwick University, Public Health England [Porton Down, Salisbury], Huazhong Agricultural University, Makerere University (MAK), Faculty of Medicine-Laval University [Québec], Okayama University [Okayama], Institut Pasteur [Paris], Centre International de Recherches Médicales de Franceville, University of Minnesota [Twin Cities], Universidad de Chile, University of California-University of California, Texas Biomedical Research Institute [San Antonio, Texas], National Institute for Communicable Diseases (NICD), Centre for Experimental Medicine [Queen’s University of Belfast], University of Bristol (School of Cellular and Molecular Medicine), University of Missouri [Columbia], Hokkaido University, Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity, Centre International de Recherche en Infectiologie - UMR (CIRI), Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Duke NUS Medical School, University of Florida [Gainesville], and Virology

Subjects

0301 basic medicine, Order Mononegavirales, 040301 veterinary sciences, Mononegavirales Infections, 04 agricultural and veterinary sciences, General Medicine, Biology, Data science, Virology, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Article, 0403 veterinary science, 03 medical and health sciences, 030104 developmental biology, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, Humans, Animals, [SDV.IMM]Life Sciences [q-bio]/Immunology, Taxonomy (biology), Mononegavirales, Phylogeny

Abstract

International audience; In 2018, the order Mononegavirales was expanded by inclusion of 1 new genus and 12 novel species. This article presents the updated taxonomy of the order Mononegavirales as now accepted by the International Committee on Taxonomy of Viruses (ICTV) and summarizes additional taxonomic proposals that may affect the order in the near future.

Published

2018

5. Taxonomy of the order Mononegavirales : update 2017

Author

Andrew J. Easton, Gael Kurath, Jonathan S. Towner, Qi Fang, Calogero Terregino, Noël Tordo, Jean L. Patterson, John H. Werren, John M. Dye, Andrea Maisner, Qisheng Song, Peter J. Walker, Benhur Lee, Pierre Formenty, Richard E. Randall, Ralf Dürrwald, Kim R. Blasdell, Alisa Bochnowski, Bertus K. Rima, Robert A. Lamb, Paul A. Rota, Kartik Chandran, Ralf G. Dietzgen, David M. Stone, Norbert Nowotny, Hideki Kondo, Roger Hewson, Anna E. Whitfield, Janusz T. Paweska, Masayuki Horie, Peter L. Collins, Keizo Tomonaga, Martin Schwemmle, Anthony P. James, Olga Dolnik, Gary P. Kobinger, Beibei Wang, Michael N. Pearson, Nicolás Bejerman, Susan Payne, Ming Li, Jian Hong, Fei Wang, Christopher F. Basler, Robert M. Harding, Jens H. Kuhn, Ron A. M. Fouchier, Charles H. Calisher, Eric M. Leroy, Viktor E. Volchkov, Hideki Ebihara, Lin-Fa Wang, Dàohóng Jiāng, Sina Bavari, Gaya K. Amarasinghe, Ayato Takada, Sergey V. Netesov, Elke Mühlberger, Sophie J. Smither, David Wang, Gongyin Ye, Peter Revill, Martin Beer, Colleen M. Higgins, Yīmíng Bào, Robert B. Tesh, Victoria Wahl-Jensen, Thomas Briese, Zhichao Yan, Dennis Rubbenstroth, Elodie Ghedin, Alexander Bukreyev, Nikos Vasilakis, Virology, Washington University School of Medicine (WUSM), University of Washington [Seattle], National Center for Biotechnology Information (NCBI), Georgia State University, University System of Georgia (USG), Army Medical Research Institute of Infectious Diseases [USA] (USAMRIID), Institute of Diagnostic Virology (IVD), Friedrich-Loeffler-Institut (FLI), Instituto Nacional de Tecnología Agropecuaria, Universidad Nacional de la Patagonia Austral (UNPA), Consejo Nacional de Investigaciones Científicas y Técnicas [Buenos Aires] (CONICET), Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Integrated Research Facility at Fort Detrick, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Columbia Mailman School of Public Health, The University of Texas Medical Branch (UTMB), College of Veterinary Medicine and Biomedical Sciences, Colorado State University [Fort Collins] (CSU), Albert Einstein College of Medicine [New York], National Institute of Allergy and Infectious Diseases [Bethesda] (NIAID-NIH), National Institutes of Health [Bethesda] (NIH), Queensland Alliance for Agriculture and Food Innovation (QAAFI), University of Queensland [Brisbane], Philipps University of Marburg, IDT Biologika, School of Life Sciences, Warwick University, Department of Biochemistry and Molecular Biology, University of Rochester [USA], State Key Laboratory of Rice Biology, China National Rice Research Institute, Chinese Academy of Agricultural Sciences (CAAS), Organisation Mondiale de la Santé / World Health Organization Office (OMS / WHO), Department of Viroscience [Rotterdam, The Netherlands], Erasmus University Medical Center [Rotterdam] (Erasmus MC), Center for Genomics and Systems Biology, Department of Biology [New York], New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU)-New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU), Centre for Tropical Crops and Biocommodities, Queensland University of Technology, Public Health England [Salisbury] (PHE), Auckland University of Technology (AUT), Infections Virales et Pathologie Comparée - UMR 754 (IVPC), Institut National de la Recherche Agronomique (INRA)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon, Kagoshima University, State Key Laboratory of Agricultural Microbiology, Huazhong Agricultural University, Research Centre in Infectious Diseases, CHUL Research Centre and Department of Microbiology and Immunology, Université Laval [Québec] (ULaval)-Faculty of Medicine, Institute of Plant Science and Resources, Okayama University, US Geological Survey [Seattle], United States Geological Survey [Reston] (USGS), Northwestern University [Evanston], Icahn School of Medicine at Mount Sinai [New York] (MSSM), Centre International de Recherches Médicales de Franceville (CIRMF), Institute for Applied Ecology New Zealand (AENZ), Boston University School of Medicine (BUSM), Boston University [Boston] (BU), Novosibirsk State University (NSU), University of Veterinary Medicine [Vienna] (Vetmeduni), Mohammed Bin Rashid University of Medicine and Health Sciences (MBRU), Texas Biomedical Research Institute [San Antonio, TX], Texas A&M University System, National Institute for Communicable Diseases [Johannesburg] (NICD), University of Auckland [Auckland], Biomedical Sciences Research Complex [St Andrews, Scotland] (BSRC), University of St Andrews [Scotland], Victorian Infectious Diseases Reference Laboratory, Queen's University [Belfast] (QUB), National Center for Immunization and Respiratory Diseases, CDC, Centers for Disease Control and Prevention (CDC), University of Freiburg [Freiburg], Defence Science and Technology Laboratory (Dstl), Ministry of Defence (UK) (MOD), University of Missouri School of Medicine, University of Missouri System, Centre for Environment, Fisheries and Aquaculture Science [Weymouth] (CEFAS), Hokkaido University [Sapporo, Japan], Istituto Zooprofilattico Sperimentale delle Venezie (IZSVe), Institute for Virus Research, Kyoto University [Kyoto], Stratégies antivirales, Institut Pasteur [Paris], Institut Pasteur de Guinée, Réseau International des Instituts Pasteur (RIIP), Viral Special Pathogens Branch, Centers for Disease Control and Prevention-WHO Collaborative Centre for Viral Hemorrhagic Fevers, Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity (BMPV), Centre International de Recherche en Infectiologie - UMR (CIRI), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), National Biodefense Analysis and Countermeasures Center [Frederick], U.S. Social Security Administration, CSIRO Health & Biosecurity, Washington University School of Medicine, Department of Agriculture, Fisheries and Forestry, Ecoscience Precinct, GPO Box 267, Brisbane, Duke-NUS Medical School [Singapore], Department of Biology, Kansas State University, Albert Einstein College of Medicine, Queensland Alliance for Agriculture and Food Innovation, University of Queensland (UQ), Public Health England [Porton Down, Salisbury], Institut National de la Recherche Agronomique (INRA)-École pratique des hautes études (EPHE)-Université Claude Bernard Lyon 1 (UCBL), Faculty of Medicine-Laval University [Québec], Okayama University [Okayama], Centre International de Recherches Médicales de Franceville, Institute for Applied Ecology New Zealand, Texas Biomedical Research Institute [San Antonio, Texas], A&M University, National Institute for Communicable Diseases (NICD), The University of Auckland, Centre for Experimental Medicine [Queen’s University of Belfast], Hokkaido University, Istituto Zooprofilattico Sperimentale delle Venezie, Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity, Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Duke NUS Medical School, U.S. Army Medical Research Institute of Infectious Diseases (USAMRIID), Columbia University [New York], Philipps Universität Marburg = Philipps University of Marburg, University of Warwick [Coventry], Queensland University of Technology [Brisbane] (QUT), Institut National de la Recherche Agronomique (INRA)-École Pratique des Hautes Études (EPHE), Huazhong Agricultural University [Wuhan] (HZAU), Victorian Infectious Diseases Reference Laboratory [Melbourne, Australia] (VIDRL), Kyoto University, Institut Pasteur [Paris] (IP), Centre International de Recherche en Infectiologie (CIRI), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), and Biomedical Sciences Research Complex

Subjects

0301 basic medicine, 030106 microbiology, Genome, Viral, Article, 03 medical and health sciences, Species Specificity, Genus, Phylogenetics, Virology, Gene Order, Viral, Mononegavirales, Phylogeny, Order Mononegavirales, Genome, biology, General Medicine, Pneumovirus, biology.organism_classification, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, 030104 developmental biology, Evolutionary biology, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, [SDV.IMM]Life Sciences [q-bio]/Immunology, Taxonomy (biology)

Abstract

International audience; In 2017, the order Mononegavirales was expanded by the inclusion of a total of 69 novel species. Five new rhabdovirus genera and one new nyamivirus genus were established to harbor 41 of these species, whereas the remaining new species were assigned to already established genera. Furthermore, non-Latinized binomial species names replaced all paramyxovirus and pneumovirus species names, thereby accomplishing application of binomial species names throughout the entire order. This article presents the updated taxonomy of the order Mononegavirales as now accepted by the International Committee on Taxonomy of Viruses (ICTV).

Published

2017

6. Root cone angle is enlarged in docs1 LRR- RLK mutants in rice

Author

M, Bettembourg, M, Dal-Soglio, C, Bureau, A, Vernet, A, Dardoux, M, Portefaix, M, Bes, D, Meynard, D, Mieulet, B, Cayrol, C, Perin, B, Courtois, J F, Ma, A, Dievart, Amélioration génétique et adaptation des plantes méditerranéennes et tropicales (UMR AGAP), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Institut National de la Recherche Agronomique (INRA)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro), Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro), Institute of Plant Science and Resources, Okayama University, Shanghai Jiao Tong University [Shanghai], and Centre de cooperation Internationale de Recherche en Agronomie pour le Developpement (CIRAD) PhD fellowship

Subjects

Short Communication, Lrr, GSA, F62 - Physiologie végétale - Croissance et développement, Oryza sativa, lcsh:Plant culture, Rlk, F50 - Anatomie et morphologie des plantes, docs1, F30 - Génétique et amélioration des plantes, Système racinaire, Gravitropism, Tropisme, Aluminium, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Expression des gènes, lcsh:SB1-1110, Stade de développement végétal, Génie génétique, Morphologie végétale, RCA, RGA, Mutant, Gène, Anatomie végétale, Gravité, Rice, Root cap, Angle, Racine

Abstract

Background The DEFECTIVE IN OUTER CELL LAYER SPECIFICATION 1 (DOCS1) gene belongs to the Leucine-Rich Repeat Receptor-Like Kinase (LRR-RLK) subfamily. It has been discovered few years ago in Oryza sativa (rice) in a screen to isolate mutants with defects in sensitivity to aluminum. The c68 (docs1–1) mutant possessed a nonsense mutation in the C-terminal part of the DOCS1 kinase domain. Findings We have generated a new loss-of-function mutation in the DOCS1 gene (docs1–2) using the CRISPR-Cas9 technology. This new loss-of-function mutant and docs1–1 present similar phenotypes suggesting the original docs1–1 was a null allele. Besides the aluminum sensitivity phenotype, both docs1 mutants shared also several root phenotypes described previously: less root hairs and mixed identities of the outer cell layers. Moreover, our new results suggest that DOCS1 could also play a role in root cap development. We hypothesized these docs1 root phenotypes may affect gravity responses. As expected, in seedlings, the early gravitropic response was delayed. Furthermore, at adult stage, the root gravitropic set angle of docs1 mutants was also affected since docs1 mutant plants displayed larger root cone angles. Conclusions All these observations add new insights into the DOCS1 gene function in gravitropic responses at several stages of plant development. Electronic supplementary material The online version of this article (10.1186/s12284-017-0190-1) contains supplementary material, which is available to authorized users.

Published

2017

7. Taxonomy of the order Mononegavirales: update 2016

Author

Ralf Dürrwald, Krisztián Bányai, Robert A. Lamb, Hideki Kondo, Alexander Bukreyev, Anna N. Clawson, Calogero Terregino, Robert B. Tesh, Andrew J. Easton, Andrea Maisner, Paul A. Rota, Gael Kurath, Kartik Chandran, Charles H. Calisher, Ralf G. Dietzgen, Janusz T. Paweska, Szilvia Marton, Dennis Rubbenstroth, Masayuki Horie, Juliana Freitas-Astúa, Bertus K. Rima, Jonathan S. Towner, Viktor E. Volchkov, Eric M. Leroy, David M. Stone, Susan Payne, Kwok-Yung Yuen, Hideki Ebihara, Lin-Fa Wang, Lìjiāng Liú, C. Li, Nikos Vasilakis, Olga Dolnik, Gaya K. Amarasinghe, Gary P. Kobinger, Jean L. Patterson, Sergio Lenardon, Xian Dan Lin, Leslie L. Domier, Mang Shi, Pierre Formenty, Ben Longdon, Anna E. Whitfield, Sina Bavari, Timothy H. Hyndman, Martin Verbeek, E. W. Kitajima, Elke Mühlberger, Peter J. Walker, Ayato Takada, Mark D. Stenglein, François Xavier Briand, David Wang, Elodie Ghedin, Jiāsēn Chéng, Keizo Tomonaga, Norbert Nowotny, Roger Hewson, Noël Tordo, Jun Hua Tian, Nicolás Bejerman, John M. Dye, Christopher F. Basler, Yong-Zhen Zhang, Kim R. Blasdell, Yanping Fu, Sophie J. Smither, Richard E. Randall, Jens H. Kuhn, Jiǎtāo Xiè, Victoria Wahl-Jensen, Thierry Wetzel, Martin Schwemmle, Michael M. Goodin, John A. Walsh, Thomas Briese, Yīmíng Bào, Peter L. Collins, Dàohóng Jiāng, Sergey V. Netesov, Ron A. M. Fouchier, Szilvia L. Farkas, Claudio L. Afonso, US Department of Agriculture, Washington University School of Medicine (WUSM), University of Washington [Seattle], Centre for Agricultural Research [Budapest] (ATK), Hungarian Academy of Sciences (MTA), National Center for Biotechnology Information (NCBI), Georgia State University, University System of Georgia (USG), Army Medical Research Institute of Infectious Diseases [USA] (USAMRIID), Instituto Nacional de Tecnología Agropecuaria, Universidad Nacional de la Patagonia Austral (UNPA), Consejo Nacional de Investigaciones Científicas y Técnicas [Buenos Aires] (CONICET), Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Laboratoire de Ploufragan-Plouzané-Niort [ANSES], Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES), Columbia Mailman School of Public Health, The University of Texas Medical Branch (UTMB), Department of Veterinary Integrative Biosciences, College of Veterinary Medicine and Biomedical Sciences, Texas A&M University System, Albert Einstein College of Medicine [New York], Huazhong Agricultural University, Integrated Research Facility at Fort Detrick, National Institute of Allergy and Infectious Diseases, National Institutes of Health, National Institute of Allergy and Infectious Diseases [Bethesda] (NIAID-NIH), National Institutes of Health [Bethesda] (NIH), Queensland Alliance for Agriculture and Food Innovation - Centre for Animal Science, University of Queensland [Brisbane], Philipps University of Marburg, University of Illinois [Chicago] (UIC), University of Illinois System, IDT Biologika, School of Life Sciences, Warwick University, Laboratory of Persistent Viral Diseases, LABOKLIN, Embrapa Cassava and Fruits, Brazilian Agricultural Research Corporation (Embrapa), Organisation Mondiale de la Santé / World Health Organization Office (OMS / WHO), Department of Viroscience [Rotterdam, The Netherlands], Erasmus University Medical Center [Rotterdam] (Erasmus MC), Center for Genomics and Systems Biology, Department of Biology [New York], New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU)-New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU), Department of Plant Pathology, University of Kentucky, University of Kentucky, Public Health England [Salisbury] (PHE), Kagoshima University, School of Veterinary and Life Sciences [Murdoch], Murdoch University, State Key Laboratory of Agricultural Microbiology, Escola Superior de Agricultura 'Luiz de Queiroz' (ESALQ), Universidade de São Paulo (USP), Research Centre in Infectious Diseases, CHUL Research Centre and Department of Microbiology and Immunology, Université Laval [Québec] (ULaval)-Faculty of Medicine, Institute of Plant Science and Resources, Okayama University, US Geological Survey [Seattle], United States Geological Survey [Reston] (USGS), Northwestern University [Evanston], Centre International de Recherches Médicales de Franceville (CIRMF), State Key Laboratory for Infectious Disease prevention and Control, Beijing Institute of Technology (BIT), Wēnzhōu Center for Disease Control and Prevention, Department of Genetics University of Cambridge, University of Cambridge [UK] (CAM), Boston University School of Medicine (BUSM), Boston University [Boston] (BU), Novosibirsk State University (NSU), University of Veterinary Medicine [Vienna] (Vetmeduni), Mohammed Bin Rashid University of Medicine and Health Sciences (MBRU), Texas Biomedical Research Institute [San Antonio, TX], College of Veterinary Medicine and Biomedical Sciences, National Institute for Communicable Diseases [Johannesburg] (NICD), Biomedical Sciences Research Complex [St Andrews, Scotland] (BSRC), University of St Andrews [Scotland], Queen's University [Belfast] (QUB), National Center for Immunization and Respiratory Diseases, CDC, Centers for Disease Control and Prevention (CDC), University of Freiburg [Freiburg], Chinese Center for Disease Control and Prevention, Defence Science and Technology Laboratory (Dstl), Ministry of Defence (UK) (MOD), Department of Microbiology, Immunology and Pathology, Colorado State University [Fort Collins] (CSU), Centre for Environment, Fisheries and Aquaculture Science [Weymouth] (CEFAS), Hokkaido University [Sapporo, Japan], Istituto Zooprofilattico Sperimentale delle Venezie (IZSVe), Wǔhàn Center for Disease Control and Prevention, Institute for Virus Research, Kyoto University [Kyoto], Stratégies antivirales, Institut Pasteur [Paris], Institut Pasteur de Guinée, Réseau International des Instituts Pasteur (RIIP), Viral Special Pathogens Branch, Centers for Disease Control and Prevention-WHO Collaborative Centre for Viral Hemorrhagic Fevers, Wageningen University and Research [Wageningen] (WUR), Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity (BMPV), Centre International de Recherche en Infectiologie - UMR (CIRI), Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), National Biodefense Analysis and Countermeasures Center [Frederick], U.S. Social Security Administration, CSIRO Health & Biosecurity, Departments of Molecular Microbiology and Pathology & Immunology, Department of Agriculture, Fisheries and Forestry, Ecoscience Precinct, GPO Box 267, Brisbane, Duke-NUS Medical School [Singapore], Kansas State University, State Key Laboratory of Emerging Infectious Diseases & Department of Microbiology, The University of Hong Kong (HKU)-Li Ka Shing Faculty of Medicine, State Key Laboratory of Emerging Infectious Diseases, The University of Hong Kong (HKU), French Agency for Food, Environmental and Occupational Health & Safety (Anses) - Veterinary epidemiology, Albert Einstein College of Medicine, Public Health England [Porton Down, Salisbury], Faculty of Medicine-Laval University [Québec], Okayama University [Okayama], Centre International de Recherches Médicales de Franceville, Texas Biomedical Research Institute [San Antonio, Texas], A&M University, National Institute for Communicable Diseases (NICD), Centre for Experimental Medicine [Queen’s University of Belfast], Hokkaido University, Istituto Zooprofilattico Sperimentale delle Venezie [Padova], Wageningen University and Research Centre [Wageningen] (WUR), Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity, Duke NUS Medical School, U.S. Army Medical Research Institute of Infectious Diseases (USAMRIID), Columbia University [New York], Huazhong Agricultural University [Wuhan] (HZAU), Philipps Universität Marburg = Philipps University of Marburg, University of Warwick [Coventry], University of Kentucky (UK), Universidade de São Paulo = University of São Paulo (USP), Kyoto University, Institut Pasteur [Paris] (IP), Centre International de Recherche en Infectiologie (CIRI), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Virology, and Biomedical Sciences Research Complex

Subjects

0301 basic medicine, 030106 microbiology, Zoology, Genome, Viral, Article, 03 medical and health sciences, Genus, Phylogenetics, Virology, Crustavirus, Life Science, Viral, Mononegavirales, Phylogeny, Order Mononegavirales, QR355, Genome, biology, Entomology & Disease Management, General Medicine, biology.organism_classification, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Pneumoviridae, Subfamily Pneumovirinae, MONONEGAVIRALES, 030104 developmental biology, Evolutionary biology, Wildlife Ecology and Conservation, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, [SDV.IMM]Life Sciences [q-bio]/Immunology, Taxonomy (biology), RA, RC

Abstract

International audience; In 2016, the order Mononegavirales was emended through the addition of two new families (Mymonaviridae and Sunviridae), the elevation of the paramyxoviral subfamily Pneumovirinae to family status (Pneumoviridae), the addition of five free-floating genera (Anphevirus, Arlivirus, Chengtivirus, Crustavirus, and Wastrivirus), and several other changes at the genus and species levels. This article presents the updated taxonomy of the order Mononegavirales as now accepted by the International Committee on Taxonomy of Viruses (ICTV).

Published

2016

8. Plant autophagy is responsible for peroxisomal transition and plays an important role in the maintenance of peroxisomal quality

Author

Michitaro Shibata, Kazusato Oikawa, Kenji Yamada, Kohki Yoshimoto, Maki Kondo, Yoshinori Ohsumi, Makoto Hayashi, Shino Goto-Yamada, Wataru Sakamoto, Shoji Mano, Mikio Nishimura, Department of Cell Biology, National Institute for Basic Biology [Okazaki], Department of Basic Biology, School of Life Science, The Graduate University for Advanced Studies, Department of Applied Biological Chemistry, Niigata University, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Department of Bioscience, Nagahama Institute of Bio-Science and Technology, Institute of Plant Science and Resources, Okayama University, Frontier Research Center, and Tokyo Institute of Technology [Tokyo] (TITECH)

Subjects

0106 biological sciences, Arabidopsis thaliana, Membrane lipids, [SDV]Life Sciences [q-bio], Arabidopsis, hydrogen peroxide, 01 natural sciences, 03 medical and health sciences, Glyoxysome, Autophagy, Peroxisomes, peroxisome, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Reactive oxygen species, biology, glyoxysome leaf peroxisome, Cell Biology, Peroxisome, Plants, Genetically Modified, biology.organism_classification, pexophagy, Autophagic Punctum, Cell biology, Plant Leaves, Metabolic pathway, Biochemistry, chemistry, Photorespiration, peroxisome transition, Reactive Oxygen Species, Oxidation-Reduction, Metabolic Networks and Pathways, 010606 plant biology & botany

Abstract

In photosynthetic cells, a large amount of hydrogen peroxide is produced in peroxisomes through photorespiration, which is a metabolic pathway related to photosynthesis. Hydrogen peroxide, a reactive oxygen species, oxidizes peroxisomal proteins and membrane lipids, resulting in a decrease in peroxisomal quality. We demonstrate that the autophagic system is responsible for the elimination of oxidized peroxisomes in plant. We isolated Arabidopsis mutants that accumulated oxidized peroxisomes, which formed large aggregates. We revealed that these mutants were defective in autophagy-related (ATG) genes and that the aggregated peroxisomes were selectively targeted by the autophagic machinery. These findings suggest that autophagy plays an important role in the quality control of peroxisomes by the selective degradation of oxidized peroxisomes. In addition, the results suggest that autophagy is also responsible for the functional transition of glyoxysomes to leaf peroxisomes.

Published

2014

9. Highly Oxidized Peroxisomes Are Selectively Degraded via Autophagy in Arabidopsis[C][W]

Author

Michitaro Shibata, Yoshinori Ohsumi, Mikio Nishimura, Maki Kondo, Kazusato Oikawa, Kenji Yamada, Makoto Hayashi, Kohki Yoshimoto, Wataru Sakamoto, Shoji Mano, Department of Cell Biology, National Institute for Basic Biology [Okazaki], School of Life Science, Department of Basic Biology, The Graduate University for Advanced Studies, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Institute of Plant Science and Resources, Okayama University, Frontier Research Center, Tokyo Institute of Technology [Tokyo] (TITECH), Japan Society for the Promotion of Science [5852], and 22120007

Subjects

0106 biological sciences, Autophagosome, ATG8, [SDV]Life Sciences [q-bio], Mutant, Arabidopsis, Plant Science, 01 natural sciences, In Brief, 03 medical and health sciences, Stress, Physiological, Phagosomes, Autophagy, Peroxisomes, Research Articles, 030304 developmental biology, 0303 health sciences, biology, Arabidopsis Proteins, Wild type, Hydrogen Peroxide, Cell Biology, Peroxisome, biology.organism_classification, Cell biology, Biochemistry, Catalase, Mutation, biology.protein, Oxidation-Reduction, 010606 plant biology & botany

Abstract

The legend for Figure 1B has been corrected; The positioning of peroxisomes in a cell is a regulated process that is closely associated with their functions. Using this feature of the peroxisomal positioning as a criterion, we identified three Arabidopsis thaliana mutants (peroxisome unusual positioning1 [peup1], peup2, and peup4) that contain aggregated peroxisomes. We found that the PEUP1, PEUP2, and PEUP4 were identical to Autophagy-related2 (ATG2), ATG18a, and ATG7, respectively, which are involved in the autophagic system. The number of peroxisomes was increased and the peroxisomal proteins were highly accumulated in the peup1 mutant, suggesting that peroxisome degradation by autophagy (pexophagy) is deficient in the peup1 mutant. These aggregated peroxisomes contained high levels of inactive catalase and were more oxidative than those of the wild type, indicating that peroxisome aggregates comprise damaged peroxisomes. In addition, peroxisome aggregation was induced in wild-type plants by exogenous application of hydrogen peroxide. The cat2 mutant also contained peroxisome aggregates. These findings demonstrate that hydrogen peroxide as a result of catalase inactivation is the inducer of peroxisome aggregation. Furthermore, an autophagosome marker, ATG8, frequently colocalized with peroxisome aggregates, indicating that peroxisomes damaged by hydrogen peroxide are selectively degraded by autophagy in the wild type. Our data provide evidence that autophagy is crucial for quality control mechanisms for peroxisomes in Arabidopsis.

Published

2013

10. Possibility and Challenges of Conversion of Current Virus Species Names to Linnaean Binomials

Author

Sbina Bavari, Susan Payne, Alexander Bukreyev, Arvind Varsani, Víctor Romanowski, Kartik Chandran, Ralf G. Dietzgen, Mark D. Stenglein, Anna N. Clawson, Sead Sabanadzovic, Gael Kurath, Andrea Maisner, Peter J. Walker, Ralf Dürrwald, Juan Carlos de la Torre, Eric M. Leroy, Mária Benko, Keizo Tomonaga, Gary P. Kobinger, Robert A. Lamb, Hideki Kondo, F. Murilo Zerbini, Martin Schwemmle, Robert B. Tesh, Gaya K. Amarasinghe, Andrew J. Easton, Michael J. Buchmeier, Jean-Paul Gonzalez, Anna E. Whitfield, Nikos Vasilakis, Jonathan S. Towner, Pierre Formenty, Jens H. Kuhn, Norbert Nowotny, Roger Hewson, Ayato Takada, Mart Krupovic, Igor S. Lukashevich, David M. Stone, Clarence J. Peters, Sheli R. Radoshitzky, Bertus K. Rima, Janusz T. Paweska, Masayuki Horie, Christopher S. Clegg, Victoria Wahl-Jensen, Christopher F. Basler, Sébastian Emonet, Charles H. Calisher, Lin-Fa Wang, Rémi N. Charrel, Jean L. Patterson, Elodie Ghedin, Dennis Rubbenstroth, Dàohóng Jiāng, Sergey V. Netesov, Hélène Sanfaçon, Thomas S. Postler, Ron A. M. Fouchier, Peter L. Collins, Noël Tordo, Maria S. Salvato, John M. Dye, Arcady Mushegian, Sophie J. Smither, Joseph L. DeRisi, Olga Dolnik, Kim R. Blasdell, Balázs Harrach, Viktor E. Volchkov, Thomas Briese, Andrew M. Kropinski, Columbia University College of Physicians and Surgeons, Integrated Research Facility at Fort Detrick, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Washington University School of Medicine (WUSM), University of Washington [Seattle], Georgia State University, University System of Georgia (USG), Army Medical Research Institute of Infectious Diseases [USA] (USAMRIID), Institute for Soil Sciences and Agricultural Chemistry (ATK TAKI), Centre for Agricultural Research [Budapest] (ATK), Hungarian Academy of Sciences (MTA)-Hungarian Academy of Sciences (MTA), Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Columbia Mailman School of Public Health, University of California [Irvine] (UCI), University of California, The University of Texas Medical Branch (UTMB), College of Veterinary Medicine and Biomedical Sciences, Colorado State University [Fort Collins] (CSU), Albert Einstein College of Medicine [New York], Emergence des Pathologies Virales (EPV), Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Assistance Publique - Hôpitaux de Marseille (APHM), Institut Hospitalier Universitaire Méditerranée Infection (IHU Marseille), Les Mandinaux, National Institute of Allergy and Infectious Diseases [Bethesda] (NIAID-NIH), National Institutes of Health [Bethesda] (NIH), Department of Immunology and Microbial Science, Scripps Research Institute, Department of Medicine [San Francisco], University of California [San Francisco] (UCSF), University of California-University of California, Queensland Alliance for Agriculture and Food Innovation (QAAFI), University of Queensland [Brisbane], Philipps University of Marburg, IDT Biologika, School of Life Sciences, Warwick University, Unité de Virologie, Institut de Recherche Biomédicale des Armées (IRBA), Organisation Mondiale de la Santé / World Health Organization Office (OMS / WHO), Department of Viroscience [Rotterdam, The Netherlands], Erasmus University Medical Center [Rotterdam] (Erasmus MC), Center for Genomics and Systems Biology, Department of Biology [New York], New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU)-New York University [New York] (NYU), NYU System (NYU)-NYU System (NYU), Health for Development, Public Health England [Salisbury] (PHE), Kagoshima University, State Key Laboratory of Agricultural Microbiology, Huazhong Agricultural University, Research Centre in Infectious Diseases, CHUL Research Centre and Department of Microbiology and Immunology, Université Laval [Québec] (ULaval)-Faculty of Medicine, Institute of Plant Science and Resources, Okayama University, University of Guelph, Biologie Moléculaire du Gène chez les Extrêmophiles (BMGE), Institut Pasteur [Paris], US Geological Survey [Seattle], United States Geological Survey [Reston] (USGS), Northwestern University [Evanston], Centre International de Recherches Médicales de Franceville (CIRMF), Department of Pharmacology and Toxicology, University of Louisville, Department of Molecular Biosciences, Institute for Cellular and Molecular Biology, Center for Infectious Disease, University of Texas at Austin [Austin], Novosibirsk State University (NSU), University of Veterinary Medicine [Vienna] (Vetmeduni), Mohammed Bin Rashid University of Medicine and Health Sciences (MBRU), Texas Biomedical Research Institute [San Antonio, TX], Texas A&M University System, National Institute for Communicable Diseases [Johannesburg] (NICD), Queen's University [Belfast] (QUB), Instituto de Biotecnología y Biología Molecular [La Plata] (IBBM), Consejo Nacional de Investigaciones Científicas y Técnicas [Buenos Aires] (CONICET)-Facultad de Ciencias Exactas [La Plata], Universidad Nacional de la Plata [Argentine] (UNLP)-Universidad Nacional de la Plata [Argentine] (UNLP), University of Freiburg [Freiburg], Department of Biochemistry, Molecular Biology, Entomology and Plant Pathology [Mstate, USA] (BCH-EPP), Mississippi State University [Mississippi], Summerland Research and Development Centre, Agriculture and Agri-Food [Ottawa] (AAFC), University of Maryland School of Medicine, University of Maryland System, Defence Science and Technology Laboratory (Dstl), Ministry of Defence (UK) (MOD), Department of Microbiology, Immunology and Pathology, Centre for Environment, Fisheries and Aquaculture Science [Weymouth] (CEFAS), Hokkaido University [Sapporo, Japan], Institute for Virus Research, Kyoto University [Kyoto], Stratégies antivirales, Institut Pasteur de Guinée, Réseau International des Instituts Pasteur (RIIP), Viral Special Pathogens Branch, Centers for Disease Control and Prevention-WHO Collaborative Centre for Viral Hemorrhagic Fevers, Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity (BMPV), Centre International de Recherche en Infectiologie - UMR (CIRI), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), National Biodefense Analysis and Countermeasures Center [Frederick], U.S. Social Security Administration, CSIRO Health & Biosecurity, Department of Agriculture, Fisheries and Forestry, Ecoscience Precinct, GPO Box 267, Brisbane, Duke-NUS Medical School [Singapore], Center for Fundamental and Applied Microbiomics, Arizona State University [Tempe] (ASU)-Biodesign Institute, Kansas State University, Departamento de Fitopatologia [Viçosa, Brazil] (BIOAGRO), Universidade Federal de Vicosa (UFV), This work was supported in part through Battelle Memorial Institute’s prime contract with the US National Institute of Allergy and Infectious Diseases (NIAID) under Contract No. HHSN272200700016I. A subcontractor to Battelle Memorial Institute who performed this work is J.H.K., an employee of Tunnell Government Services, Inc. This work was also funded in part under National Institutes of Health (NIH) contract HHSN272201000040I/HHSN27200004/D04 and R24AI120942 (N.V., R.B.T.), and the National Science Foundation (NSF) Individual Research and Development (IR/D) program (A.R.M.)., We thank Laura Bollinger (NIH/NIAID Integrated Research Facility at Fort Detrick, Frederick, MD, USA) for critically editing the manuscript, Andrew J. Davison (MRC – University of Glasgow Centre for Virus Research, Glasgow, UK) and Michael J. Adams (Department of Plant Pathology and Microbiology, Rothamsted Research, Harpenden, Herts, UK) of the ICTV Executive Committee for suggestions on manuscript improvement, and Arya Ariël Kuhn for sustained vocal support and (dia)critical remarks, Albert Einstein College of Medicine, Institut Hospitalier Universitaire Méditerranée Infection (IHU AMU), Queensland Alliance for Agriculture and Food Innovation, University of Queensland (UQ), Public Health England [Porton Down, Salisbury], Faculty of Medicine-Laval University [Québec], Okayama University [Okayama], Centre International de Recherches Médicales de Franceville, Texas Biomedical Research Institute [San Antonio, Texas], A&M University, National Institute for Communicable Diseases (NICD), Centre for Experimental Medicine [Queen’s University of Belfast], Department of Biochemistry, Molecular Biology, Entomology and Plant Pathology, Hokkaido University, Bases moléculaires de la pathogénicité virale – Molecular Basis of Viral Pathogenicity, Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Duke NUS Medical School, Departamento de Fitopatologia/BIOAGRO, Virology, U.S. Army Medical Research Institute of Infectious Diseases (USAMRIID), Columbia University [New York], University of California [Irvine] (UC Irvine), University of California (UC), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Assistance Publique - Hôpitaux de Marseille (APHM)-Institut National de la Santé et de la Recherche Médicale (INSERM), The Scripps Research Institute [La Jolla, San Diego], University of California [San Francisco] (UC San Francisco), University of California (UC)-University of California (UC), Philipps Universität Marburg = Philipps University of Marburg, University of Warwick [Coventry], Institut de Recherche Biomédicale des Armées [Brétigny-sur-Orge] (IRBA), Huazhong Agricultural University [Wuhan] (HZAU), Institut Pasteur [Paris] (IP), Agriculture and Agri-Food (AAFC), Kyoto University, Centre International de Recherche en Infectiologie (CIRI), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), and Universidade Federal de Viçosa = Federal University of Viçosa (UFV)

Subjects

0301 basic medicine, MESH: Terminology as Topic, media_common.quotation_subject, Biología, 030106 microbiology, Binomials, Zoology, Biology, Points of View, 03 medical and health sciences, Genus, Terminology as Topic, Genetics, MESH: Classification, Epithet, Arenaviridae, Ecology, Evolution, Behavior and Systematics, Virus classification, media_common, Order Mononegavirales, Evolutionary Biology, Virus taxonomy, Classification, MESH: Viruses, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Virus nomenclature, Genealogy, Ictv, International committee on taxonomy of viruses, 030104 developmental biology, Homo sapiens, Viruses, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, [SDV.IMM]Life Sciences [q-bio]/Immunology, Mononegavirales

Abstract

Botanical, mycological, zoological, and prokaryotic species names follow the Linnaean format, consisting of an italicized Latinized binomen with a capitalized genus name and a lower case species epithet (e.g., Homo sapiens). Virus species names, however, do not follow a uniform format, and, even when binomial, are not Linnaean in style. In this thought exercise, we attempted toconvert all currently official names ofspecies included in the viru sfamily Arenaviridae and the virus order Mononegavirales to Linnaean binomials, and to identify and address associated challenges and concerns. Surprisingly, this endeavor was not as complicated or time-consuming as even the authors of this article expected when conceiving the experiment., La lista completa de autores que integran el documento puede consultarse en el archivo, Instituto de Biotecnologia y Biologia Molecular

11. Silicon transport and its "homeostasis" in rice.

Author

Huang S and Ma JF

Abstract

Silicon (Si), the most abundant mineral element in soil, functions as a beneficial element for plant growth. Higher Si accumulation in the shoots is required for high and stable production of rice, a typical Si-accumulating plant species. During the last two decades, great progresses has been made in the identification of Si transporters involved in uptake, xylem loading and unloading as well as preferential distribution and deposition of Si in rice. In addition to these transporters, simulation by mathematical models revealed several other key factors required for efficient uptake and distribution of Si. The expression of Lsi1 , Lsi2 and Lsi3 genes is down-regulated by Si deposition in the shoots rather than in the roots, but the exact mechanisms underlying this down-regulation are still unknown. In this short review, we focus on Si transporters identified in rice and discuss how rice optimizes Si accumulation ("homeostasis") through regulating Si transporters in response to the fluctuations of this element in the soil solution., Competing Interests: The author declares none., (© The Author(s) 2024.)

Published

2025

12. Uptake and Accumulation of Cobalt Is Mediated by OsNramp5 in Rice.

Author

Huang H, Yamaji N, Huang S, and Ma JF

Subjects

Cation Transport Proteins metabolism, Cation Transport Proteins genetics, Gene Expression Regulation, Plant, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae genetics, Biological Transport, Plants, Genetically Modified, Oryza metabolism, Oryza genetics, Cobalt metabolism, Plant Proteins metabolism, Plant Proteins genetics, Plant Roots metabolism

Abstract

Cobalt (Co) contamination in soils potentially affects human health through the food chain. Although rice (Oryza sativa) as a staple food is a major dietary source of human Co intake, it is poorly understood how Co is taken up by the roots and accumulated in rice grain. In this study, we physiologically characterized Co accumulation and identified the transporter for Co 2+ uptake in rice. A dose-dependent experiment showed that Co mainly accumulated in rice roots. Further analysis with LA-ICP-MS showed Co deposited in most tissue of the roots, including exodermis, endodermis and stele region. Co accumulation analysis using mutants defective in divalent cation uptake showed that Co 2+ uptake in rice is mediated by the Mn 2+ /Cd 2+ /Pb 2+ transporter OsNramp5, rather than OsIRT1 for Fe 2+ and OsZIP9 for Zn 2+ . Knockout of OsNramp5 enhanced tolerance to Co toxicity. Heterologous expression of OsNramp5 showed transport activity for Co 2+ in Saccharomyces cerevisiae. Co 2+ uptake was inhibited by either Mn 2+ or Cd 2+ supply. At the reproductive stage, the Co concentration in the straw and grains of the OsNramp5 knockout lines was decreased by 41%-48% and 28%-36%, respectively, compared with that of the wild-type rice. The expression level of OsNramp5 in the roots was not affected by Co 2+ . Taken together, our results indicate that OsNramp5 is a major transporter for Co 2+ uptake in rice, which ultimately mediates Co accumulation in the grains., (© 2024 The Author(s). Plant, Cell & Environment published by John Wiley & Sons Ltd.)

Published

2025

13. Evidence for the replication of a plant rhabdovirus in its arthropod mite vector.

Author

Kondo H, Fujita M, Telengech P, Maruyam K, Hyodo K, Tassi AD, Ochoa R, Andika IB, and Suzuki N

Subjects

Animals, Arthropod Vectors virology, RNA, Viral genetics, Genome, Viral, Plant Diseases virology, Plant Diseases parasitology, High-Throughput Nucleotide Sequencing, Rhabdoviridae genetics, Rhabdoviridae physiology, Virus Replication, Mites virology, Plant Viruses genetics, Plant Viruses physiology

Abstract

Transmission of plant viruses that replicate in the insect vector is known as persistent-propagative manner. However, it remains unclear whether such virus-vector relationships also occur between plant viruses and other biological vectors such as arthropod mites. In this study, we investigated the possible replication of orchid fleck virus (OFV), a segmented plant rhabdovirus, within its mite vector (Brevipalpus californicus s.l.) using quantitative RT-qPCR, western blotting and next-generation sequencing. Time-course RT-qPCR and western blot analyses showed an increasing OFV accumulation pattern in mites after virus acquisition. Since OFV genome expression requires the transcription of polyadenylated mRNAs, polyadenylated RNA fractions extracted from the viruliferous mite samples and OFV-infected plant leaves were used for RNA-seq analysis. In the mite and plant datasets, a large number of sequence reads were aligned to genomic regions of OFV RNA1 and RNA2 corresponding to transcribed viral gene mRNAs. This includes the short polyadenylated transcripts originating from the leader and trailer regions at the ends of the viral genome, which are believed to play a crucial role in viral transcription/replication. In contrast, a low number of reads were mapped to the non-transcribed regions (gene junctions). These results strongly suggested that OFV gene expression occurs both in mites and plants. Additionally, deep sequencing revealed the accumulation of OFV-derived small RNAs in mites, although their size profiles differ from those found in plants. Taken together, our results indicated that OFV replicates within a mite vector and is targeted by the RNA-silencing mechanism., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. Mention of trade names or commercial products in this publication is solely for providing specific information and does not imply recommendation or endorsement by the USDA; USDA is an equal opportunity provider and employer., (Copyright © 2024. Published by Elsevier B.V.)

Published

2025

14. Chitin-signaling-dependent responses to insect oral secretions in rice cells propose the involvement of chitooligosaccharides in plant defense against herbivores.

Author

Kanda Y, Shinya T, Wari D, Hojo Y, Fujiwara Y, Tsuchiya W, Fujimoto Z, Thomma BPHJ, Nishizawa Y, Kamakura T, Galis I, and Mori M

Subjects

Animals, Oxylipins metabolism, Plant Defense Against Herbivory, Signal Transduction, Cyclopentanes metabolism, Plant Immunity, Moths physiology, Chitosan, Herbivory, Oryza genetics, Oryza metabolism, Oryza physiology, Oryza parasitology, Chitin metabolism, Larva physiology, Plant Proteins metabolism, Plant Proteins genetics, Oligosaccharides metabolism

Abstract

Plants recognize molecules related to a variety of biotic stresses through pattern recognition receptors to activate plant immunity. In the interactions between plants and chewing herbivores, such as lepidopteran larvae, oral secretions (OS) are deposited on wounded sites, which results in the elicitation of plant immune responses. The widely conserved receptor-like kinase CHITIN ELICITOR RECEPTOR KINASE 1 (CERK1) has been broadly associated with the recognition of microbial components, such as fungal chitin, but its relevance to herbivory remained unclear. In this study, we used receptor-knockout rice (Oryza sativa) and larvae of the lepidopteran pest Mythimna loreyi to demonstrate that the induction of immune responses triggered by larval OS in rice cells largely depends on CERK1 (OsCERK1). CHITIN ELICITOR-BINDING PROTEIN (CEBiP), an OsCERK1-interacting receptor-like protein that was proposed as the main chitin receptor, also contributed to the responses of rice cells to OS collected from three different lepidopteran species. Furthermore, CEBiP knockout rice seedlings showed lower OS-triggered accumulation of jasmonic acid. These results strongly suggest that the OsCERK1 and CEBiP recognize a particular OS component in chewing lepidopteran herbivores, and point toward the presence of chitooligosaccharides in the OS. Targeted perturbation to chitin recognition, through the use of fungal effector proteins, confirmed the presence of chitooligosaccharides in the OS. Treatments of wounds on rice plants with chitooligosaccharides enhanced a set of immune responses, leading to resistance against an herbivorous insect. Our data show that rice recognizes chitooligosaccharides during larval herbivory to activate resistance, and identifies chitin as a novel herbivore-associated molecular pattern., (© 2024 Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2025

15. Centrophilic retrotransposon integration via CENH3 chromatin in Arabidopsis.

Author

Tsukahara S, Bousios A, Perez-Roman E, Yamaguchi S, Leduque B, Nakano A, Naish M, Osakabe A, Toyoda A, Ito H, Edera A, Tominaga S, Juliarni, Kato K, Oda S, Inagaki S, Lorković Z, Nagaki K, Berger F, Kawabe A, Quadrana L, Henderson I, and Kakutani T

Subjects

Terminal Repeat Sequences genetics, Tandem Repeat Sequences genetics, Evolution, Molecular, Arabidopsis genetics, Arabidopsis metabolism, Centromere metabolism, Centromere genetics, Retroelements genetics, Chromatin metabolism, Chromatin genetics, Chromatin chemistry, Histones metabolism, Histones chemistry, Histones genetics, Arabidopsis Proteins metabolism, Arabidopsis Proteins genetics

Abstract

In organisms ranging from vertebrates to plants, major components of centromeres are rapidly evolving repeat sequences, such as tandem repeats (TRs) and transposable elements (TEs), which harbour centromere-specific histone H3 (CENH3) 1,2 . Complete centromere structures recently determined in human and Arabidopsis suggest frequent integration and purging of retrotransposons within the TR regions of centromeres 3-5 . Despite the high impact of 'centrophilic' retrotransposons on the paradox of rapid centromere evolution, the mechanisms involved in centromere targeting remain poorly understood in any organism. Here we show that both Ty3 and Ty1 long terminal repeat retrotransposons rapidly turnover within the centromeric TRs of Arabidopsis species. We demonstrate that the Ty1/Copia element Tal1 (Transposon of Arabidopsis lyrata 1) integrates de novo into regions occupied by CENH3 in Arabidopsis thaliana, and that ectopic expansion of the CENH3 region results in spread of Tal1 integration regions. The integration spectra of chimeric TEs reveal the key structural variations responsible for contrasting chromatin-targeting specificities to centromeres versus gene-rich regions, which have recurrently converted during the evolution of these TEs. Our findings show the impact of centromeric chromatin on TE-mediated rapid centromere evolution, with relevance across eukaryotic genomes., Competing Interests: Competing interests: The authors declare no competing interests., (© 2025. The Author(s).)

Published

2025

16. Shoot-Silicon-Signal protein to regulate root silicon uptake in rice.

Author

Yamaji N, Mitani-Ueno N, Fujii T, Shinya T, Shao JF, Watanuki S, Saitoh Y, and Ma JF

Subjects

Mutation, Plants, Genetically Modified, Biological Transport, Oryza metabolism, Oryza genetics, Silicon metabolism, Plant Roots metabolism, Plant Proteins metabolism, Plant Proteins genetics, Plant Shoots metabolism, Plant Shoots genetics, Gene Expression Regulation, Plant, Phloem metabolism

Abstract

Plants accumulate silicon to protect them from biotic and abiotic stresses. Especially in rice (Oryza sativa), a typical Si-accumulator, tremendous Si accumulation is indispensable for healthy growth and productivity. Here, we report a shoot-expressed signaling protein, Shoot-Silicon-Signal (SSS), an exceptional homolog of the flowering hormone "florigen" differentiated in Poaceae. SSS transcript is only detected in the shoot, whereas the SSS protein is also detected in the root and phloem sap. When Si is supplied from the root, the SSS transcript rapidly decreases, and then the SSS protein disappears. In sss mutants, root Si uptake and expression of Si transporters are decreased to a basal level regardless of the Si supply. The grain yield of the mutants is decreased to 1/3 due to insufficient Si accumulation. Thus, SSS is a key phloem-mobile protein for integrating root Si uptake and shoot Si accumulation underlying the terrestrial adaptation strategy of grasses., Competing Interests: Competing interests: The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

17. Cyclic and pseudo-cyclic electron pathways play antagonistic roles during nitrogen deficiency in Chlamydomonas reinhardtii.

Author

Dao O, Burlacot A, Buchert F, Bertrand M, Auroy P, Stoffel C, Madireddi SK, Irby J, Hippler M, Peltier G, and Li-Beisson Y

Subjects

Electron Transport, Carbon metabolism, Plant Proteins metabolism, Plant Proteins genetics, Mutation genetics, Oxygen metabolism, Chlamydomonas reinhardtii metabolism, Chlamydomonas reinhardtii genetics, Chlamydomonas reinhardtii physiology, Nitrogen metabolism, Nitrogen deficiency, Photosynthesis

Abstract

Nitrogen (N) scarcity frequently constrains global biomass productivity. N deficiency halts cell division, downregulates photosynthetic electron transfer (PET), and enhances carbon storage. However, the molecular mechanism downregulating photosynthesis during N deficiency and its relationship with carbon storage are not fully understood. Proton gradient regulator-like 1 (PGRL1) controlling cyclic electron flow (CEF) and flavodiiron proteins (FLV) involved in pseudo-CEF (PCEF) are major players in the acclimation of photosynthesis. To determine the role of PGRL1 or FLV in photosynthesis under N deficiency, we measured PET, oxygen gas exchange, and carbon storage in Chlamydomonas reinhardtii pgrl1 and flvB knockout mutants. Under N deficiency, pgrl1 maintained higher net photosynthesis and O2 photoreduction rates and higher levels of cytochrome b6f and PSI compared with the control and flvB. The photosynthetic activity of flvB and pgrl1 flvB double mutants decreased in response to N deficiency, similar to the control strains. Furthermore, the preservation of photosynthetic activity in pgrl1 was accompanied by an increased accumulation of triacylglycerol in certain genetic backgrounds but not all, highlighting the importance of gene-environment interaction in determining traits such as oil content. Our results suggest that in the absence of PGRL1-controlled CEF, FLV-mediated PCEF maintains net photosynthesis at a high level and that CEF and PCEF play antagonistic roles during N deficiency. This study further illustrate how a strain's nutrient status and genetic makeup can affect the regulation of photosynthetic energy conversion in relation to carbon storage and provide additional strategies for improving lipid productivity in algae., Competing Interests: Conflict of interest statement: There are no conflicts of interest., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

18. SHORT AND CROOKED AWN, Encoding an Epigenetic Regulator EMF1, Promotes Barley Awn Development.

Author

Nakamura K, Kikuchi Y, Shiraga M, Kotake T, Hyodo K, Taketa S, and Ikeda Y

Abstract

The awn is a bristle-like extension from the lemma of grass spikelets. In barley, the predominant cultivars possess long awns that contribute to grain yield and quality through photosynthesis. Barley is a useful cereal crop to investigate the mechanism of awn development as various awn morphological mutants are available. Here, we identified the gene causative of the short and crooked awn (sca) mutant, which exhibits a short and curved awn phenotype. Intercrossing experiments revealed that the sca mutant induced in the Japanese cultivar (cv.) 'Akashinriki' is allelic to independently isolated moderately short-awn mutant breviaristatum-a (ari-a). Map-based cloning and sequencing revealed that SCA encodes the Polycomb group-associated protein EMBRYONIC FLOWER 1 (EMF1). We found that SCA affects awn development through the promotion of cell proliferation, elongation, and cell wall synthesis. RNA sequencing of cv. Bowman (BW) backcross-derived near-isogenic lines of sca and ari-a6 alleles showed that SCA is directly or indirectly involved in promoting the expression of genes related to awn development. Additionally, SCA represses various transcription factors essential for floral organ development and plant architecture, such as MADS-box and KNOX1 genes. Notably, the repression of the C-class MADS-box gene HvMADS58 by SCA in awns is associated with the accumulation of the repressive histone modification H3K27me3. These findings highlight the potential role of SCA-mediated gene regulation, including histone modification, as a novel pathway in barley awn development., (© The Author(s) 2024. Published by Oxford University Press on behalf of Japanese Society of Plant Physiologists.)

Published

2024

19. The importin α proteins IMPA1, IMPA2, and IMPA4 play redundant roles in suppressing autoimmunity in Arabidopsis thaliana.

Author

Mori A, Nakagawa S, Suzuki T, Suzuki T, Gaudin V, Matsuura T, Ikeda Y, and Tamura K

Abstract

Proteins in the importin α (IMPA) family play pivotal roles in intracellular nucleocytoplasmic transport. Arabidopsis thaliana possesses nine IMPA members, with diverse tissue-specific expression patterns. Among these nine IMPAs, IMPA1, IMPA2, and IMPA4 cluster together phylogenetically, suggesting potential functional redundancy. To explore this redundancy, we analyzed single and multiple T-DNA mutants for these genes and discovered severe growth defects in the impa1 impa2 impa4 triple knockout mutant but not in the single or double mutants. Complementation with IMPA1, IMPA2, or IMPA4 fused to green fluorescent protein (GFP) rescued the growth defects observed in the impa1 impa2 impa4 mutant, indicating the functional redundancy of these three IMPAs. The IMPA-GFP fusion proteins were localized in the nucleus and nuclear envelope, suggesting their involvement in nucleocytoplasmic transport processes. Comparative transcriptomics revealed that salicylic acid (SA)-responsive genes were significantly upregulated in the impa1 impa2 impa4 triple mutant. Consistent with this observation, impa1 impa2 impa4 mutant plants accumulated SA and reactive oxygen species to high levels compared with wild-type plants. We also found enhanced resistance to the anthracnose pathogen Colletotrichum higginsianum in the impa1 impa2 impa4 mutants, suggesting that defense responses were constitutively activated in the impa1 impa2 impa4 mutant. Our findings shed light on the redundant roles of IMPA1, IMPA2, and IMPA4 in suppressing the autoimmune responses and suggest avenues of research to clarify their potentially unique roles., (© 2024 Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

20. A PRA-Rab trafficking machinery modulates NLR immune receptor plasma membrane microdomain anchoring and blast resistance in rice.

Author

Liang D, Yang D, Li T, Zhu Z, Yan B, He Y, Li X, Zhai K, Liu J, Kawano Y, Deng Y, Wu XN, Liu J, and He Z

Abstract

Nucleotide-binding leucine-rich repeat (NLR) receptors mediate pathogen effector-triggered immunity (ETI) in plants, and a subclass of NLRs are hypothesized to function at the plasma membrane (PM). However, how NLR traffic and PM delivery are regulated during immune responses remains largely unknown. The rice NLR PigmR confers broad-spectrum resistance to the blast fungus Magnaporthe oryzae. Here, we report that a PRA (Prenylated Rab acceptor) protein, PIBP4 (PigmR-INTERACTING and BLAST RESISTANCE PROTEIN 4), interacts with both PigmR and the active form of the Rab GTPase, OsRab5a, thereby loads a portion of PigmR on trafficking vesicles that target to PM microdomains. Microdomain-localized PigmR interacts with and activates the small GTPase OsRac1, which triggers reactive oxygen species signaling and hypersensitive response, leading to immune responses against blast infection. Thus, our study discovers a previously unknown mechanism that deploys a PRA-Rab protein delivering hub to ensure ETI, linking the membrane trafficking machinery with NLR function and immune activation in plants., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

21. Virus Research: 40 years and still going strong.

Author

Berkhout B, Domingo E, and Suzuki N

Published

2024

22. Plant growth-promoting abilities of Methylobacterium sp. 2A involve auxin-mediated regulation of the root architecture.

Author

Grossi CEM, Tani A, Mori IC, Matsuura T, and Ulloa RM

Subjects

Volatile Organic Compounds metabolism, Solanum lycopersicum microbiology, Solanum lycopersicum growth & development, Plant Growth Regulators metabolism, Chemotaxis, Methylobacterium physiology, Indoleacetic Acids metabolism, Plant Roots microbiology, Plant Roots growth & development, Plant Roots metabolism, Arabidopsis microbiology, Arabidopsis growth & development, Arabidopsis genetics

Abstract

Methylobacterium sp. 2A, a plant growth-promoting rhizobacteria (PGPR) able to produce indole-3-acetic acid (IAA), significantly promoted the growth of Arabidopsis thaliana plants in vitro. We aimed to understand the determinants of Methylobacterium sp. 2A-A. thaliana interaction, the factors underlying plant growth-promotion and the host range. Methylobacterium sp. 2A displayed chemotaxis to methanol and formaldehyde and was able to utilise 1-aminocyclopropane carboxylate as a nitrogen source. Confocal microscopy confirmed that fluorescent protein-labelled Methylobacterium sp. 2A colonises the apoplast of A. thaliana primary root cells and its inoculation increased jasmonic and salicylic acid in A. thaliana, while IAA levels remained constant. However, inoculation increased DR5 promoter activity in root tips of A. thaliana and tomato plants. Inoculation of this PGPR partially restored the agravitropic response in yucQ mutants and lateral root density was enhanced in iaa19, arf7, and arf19 mutant seedlings. Furthermore, Methylobacterium sp. 2A volatile organic compounds (VOCs) had a dose-dependent effect on the growth of A. thaliana. This PGPR is also able to interact with monocots eliciting positive responses upon inoculation. Methylobacterium sp. 2A plant growth-promoting effects can be achieved through the regulation of plant hormone levels and the emission of VOCs that act either locally or at a distance., (© 2024 John Wiley & Sons Ltd.)

Published

2024

23. Structural variation in the pangenome of wild and domesticated barley.

Author

Jayakodi M, Lu Q, Pidon H, Rabanus-Wallace MT, Bayer M, Lux T, Guo Y, Jaegle B, Badea A, Bekele W, Brar GS, Braune K, Bunk B, Chalmers KJ, Chapman B, Jørgensen ME, Feng JW, Feser M, Fiebig A, Gundlach H, Guo W, Haberer G, Hansson M, Himmelbach A, Hoffie I, Hoffie RE, Hu H, Isobe S, König P, Kale SM, Kamal N, Keeble-Gagnère G, Keller B, Knauft M, Koppolu R, Krattinger SG, Kumlehn J, Langridge P, Li C, Marone MP, Maurer A, Mayer KFX, Melzer M, Muehlbauer GJ, Murozuka E, Padmarasu S, Perovic D, Pillen K, Pin PA, Pozniak CJ, Ramsay L, Pedas PR, Rutten T, Sakuma S, Sato K, Schüler D, Schmutzer T, Scholz U, Schreiber M, Shirasawa K, Simpson C, Skadhauge B, Spannagl M, Steffenson BJ, Thomsen HC, Tibbits JF, Nielsen MTS, Trautewig C, Vequaud D, Voss C, Wang P, Waugh R, Westcott S, Rasmussen MW, Zhang R, Zhang XQ, Wicker T, Dockter C, Mascher M, and Stein N

Subjects

Alleles, Crops, Agricultural genetics, Genetic Loci, Genetic Variation, Genomic Structural Variation, Genotype, Plant Diseases microbiology, Plant Diseases genetics, Disease Resistance genetics, DNA Copy Number Variations, Domestication, Genome, Plant, Hordeum genetics

Abstract

Pangenomes are collections of annotated genome sequences of multiple individuals of a species 1 . The structural variants uncovered by these datasets are a major asset to genetic analysis in crop plants 2 . Here we report a pangenome of barley comprising long-read sequence assemblies of 76 wild and domesticated genomes and short-read sequence data of 1,315 genotypes. An expanded catalogue of sequence variation in the crop includes structurally complex loci that are rich in gene copy number variation. To demonstrate the utility of the pangenome, we focus on four loci involved in disease resistance, plant architecture, nutrient release and trichome development. Novel allelic variation at a powdery mildew resistance locus and population-specific copy number gains in a regulator of vegetative branching were found. Expansion of a family of starch-cleaving enzymes in elite malting barleys was linked to shifts in enzymatic activity in micro-malting trials. Deletion of an enhancer motif is likely to change the developmental trajectory of the hairy appendages on barley grains. Our findings indicate that allelic diversity at structurally complex loci may have helped crop plants to adapt to new selective regimes in agricultural ecosystems., Competing Interests: Competing interests: K.B., C.D., M.E.J., S.M.K., Q.L., E.M., P.R.P., B.S., H.C.T., M.T.S.N., C.V. and M.W.R. are current or previous Carlsberg A/S employees. P.A.P. and D.V. are SECOBRA Recherches employees. The other authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

24. Changes to virus taxonomy and the ICTV Statutes ratified by the International Committee on Taxonomy of Viruses (2024).

Author

Simmonds P, Adriaenssens EM, Lefkowitz EJ, Oksanen HM, Siddell SG, Zerbini FM, Alfenas-Zerbini P, Aylward FO, Dempsey DM, Dutilh BE, Freitas-Astúa J, García ML, Hendrickson RC, Hughes HR, Junglen S, Krupovic M, Kuhn JH, Lambert AJ, Łobocka M, Mushegian AR, Penzes J, Muñoz AR, Robertson DL, Roux S, Rubino L, Sabanadzovic S, Smith DB, Suzuki N, Turner D, Van Doorslaer K, Vandamme AM, and Varsani A

Subjects

Classification methods, Phylogeny, Virology methods, Viruses classification, Viruses genetics, Viruses isolation & purification, Terminology as Topic

Abstract

This article reports changes to virus taxonomy and taxon nomenclature that were approved and ratified by the International Committee on Taxonomy of Viruses (ICTV) in April 2024. The entire ICTV membership was invited to vote on 203 taxonomic proposals that had been approved by the ICTV Executive Committee (EC) in July 2023 at the 55th EC meeting in Jena, Germany, or in the second EC vote in November 2023. All proposals were ratified by online vote. Taxonomic additions include one new phylum (Ambiviricota), one new class, nine new orders, three new suborders, 51 new families, 18 new subfamilies, 820 new genera, and 3547 new species (excluding taxa that have been abolished). Proposals to complete the process of species name replacement to the binomial (genus + species epithet) format were ratified. Currently, a total of 14,690 virus species have been established., (© 2024. The Author(s).)

Published

2024

25. Geranylgeranylated-chlorophyll-protein complexes in lhl3 mutant of the green alga Chlamydomonas reinhardtii.

Author

Kodru S, Nellaepalli S, Ozawa SI, Satoh C, Kuroda H, Tanaka R, Guan K, Kobayashi M, Tran P, McCarthy S, Wakao S, Niyogi KK, and Takahashi Y

Subjects

Photosystem II Protein Complex metabolism, Photosystem II Protein Complex genetics, Photosystem I Protein Complex metabolism, Photosystem I Protein Complex genetics, Chlorophyll A metabolism, Oxidoreductases, Chlamydomonas reinhardtii genetics, Chlamydomonas reinhardtii metabolism, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes genetics, Chlorophyll metabolism, Mutation

Abstract

Chlorophylls a and b (Chl a and b) are involved in light harvesting, photochemical reactions, and electron transfer reactions in plants and green algae. The core complexes of the photosystems (PSI and PSII) associate with Chl a, while the peripheral antenna complexes (LHCI and LHCII) bind Chls a and b. One of the final steps of Chl biosynthesis is the conversion of geranylgeranylated Chls (Chls GG ) to phytylated Chls by geranylgeranyl reductase (GGR). Here, we isolated and characterized a pale green mutant of the green alga Chlamydomonas reinhardtii that was very photosensitive and was unable to grow photoautotrophically. This mutant has a 16-bp deletion in the LHL3 gene, which resulted in the loss of LHL3 and GGR and accumulated only Chls GG . The lhl3 mutant cells grown in the dark accumulated PSII and PSI proteins at 25-50% of WT levels, lacked PSII activity, and retained a decreased PSI activity. The PSII and PSI proteins were depleted to trace amounts in the mutant cells grown in light. In contrast, the accumulation of LHCI and LHCII was unaffected except for LHCA3. Our results suggest that the replacement of Chls with Chls GG strongly affects the structural and functional integrity of PSII and PSI complexes but their associating LHC complexes to a lesser extent. Affinity purification of HA-tagged LHL3 confirmed the formation of a stable LHL3-GGR complex, which is vital for GGR stability. The LHL3-GGR complex contained a small amount of PSI complex assembly factors, suggesting a putative coupling between Chl synthesis and PSI complex assembly., (© 2024 The Author(s). The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

26. The Plastidial Protein Acetyltransferase GNAT1 Forms a Complex With GNAT2, yet Their Interaction Is Dispensable for State Transitions.

Author

Brünje A, Füßl M, Eirich J, Boyer JB, Heinkow P, Neumann U, Konert M, Ivanauskaite A, Seidel J, Ozawa SI, Sakamoto W, Meinnel T, Schwarzer D, Mulo P, Giglione C, and Finkemeier I

Subjects

Acetylation, Acetyltransferases metabolism, Acetyltransferases genetics, Protein Processing, Post-Translational, Mutation, Thylakoids metabolism, Chloroplasts metabolism, Arabidopsis metabolism, Arabidopsis genetics, Arabidopsis Proteins metabolism, Arabidopsis Proteins genetics

Abstract

Protein N-acetylation is one of the most abundant co- and post-translational modifications in eukaryotes, extending its occurrence to chloroplasts within vascular plants. Recently, a novel plastidial enzyme family comprising eight acetyltransferases that exhibit dual lysine and N-terminus acetylation activities was unveiled in Arabidopsis. Among these, GNAT1, GNAT2, and GNAT3 reveal notable phylogenetic proximity, forming a subgroup termed NAA90. Our study focused on characterizing GNAT1, closely related to the state transition acetyltransferase GNAT2. In contrast to GNAT2, GNAT1 did not prove essential for state transitions and displayed no discernible phenotypic difference compared to the wild type under high light conditions, while gnat2 mutants were severely affected. However, gnat1 mutants exhibited a tighter packing of the thylakoid membranes akin to gnat2 mutants. In vitro studies with recombinant GNAT1 demonstrated robust N-terminus acetylation activity on synthetic substrate peptides. This activity was confirmed in vivo through N-terminal acetylome profiling in two independent gnat1 knockout lines. This attributed several acetylation sites on plastidial proteins to GNAT1, reflecting a subset of GNAT2's substrate spectrum. Moreover, co-immunoprecipitation coupled with mass spectrometry revealed a robust interaction between GNAT1 and GNAT2, as well as a significant association of GNAT2 with GNAT3 - the third acetyltransferase within the NAA90 subfamily. This study unveils the existence of at least two acetyltransferase complexes within chloroplasts, whereby complex formation might have a critical effect on the fine-tuning of the overall acetyltransferase activities. These findings introduce a novel layer of regulation in acetylation-dependent adjustments in plastidial metabolism., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

27. Cryptic cytoplasmic male sterility-causing gene in the mitochondrial genome of common japonica rice.

Author

Toriyama K, Iwai Y, Takeda S, Takatsuka A, Igarashi K, Furuta T, Chen S, Kanaoka Y, Kishima Y, Arimura SI, and Kazama T

Subjects

Pollen genetics, Cytoplasm genetics, Genes, Plant genetics, Oryza genetics, Plant Infertility genetics, Genome, Mitochondrial genetics

Abstract

Cytoplasmic male sterility (CMS) is an agronomically significant trait that causes dysfunction in pollen and anther development. It is often observed during successive backcrossing between distantly related species. Here, we show that Asian japonica cultivars (Oryza sativa) exhibit CMS when the nucleus is replaced with that of the African rice Oryza glaberrima. The CMS line produced stunted anthers and did not set any seeds. Mitochondrial orf288 RNA was detected in the anthers of CMS lines but not in fertility restorer lines. The mitochondrial genome-edited japonica rice that was depleted of orf288 did not exhibit male sterility when backcrossed with O. glaberrima. These results demonstrate that orf288 is a CMS-causing gene. As orf288 commonly occurs in the mitochondrial genomes of japonica rice, these results indicate that common japonica rice cultivars possess a cryptic CMS-causing gene hidden in their mitochondrial genomes., (© 2024 The Author(s). The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

28. Ancient environmental microbiomes and the cryosphere.

Author

Williams AD, Leung VW, Tang JW, Hidekazu N, Suzuki N, Clarke AC, Pearce DA, and Lam TT

Abstract

In this review, we delineate the unique set of characteristics associated with cryosphere environments (namely, ice and permafrost) which present both challenges and opportunities for studying ancient environmental microbiomes (AEMs). In a field currently reliant on several assumptions, we discuss the theoretical and empirical feasibility of recovering microbial nucleic acids (NAs) from ice and permafrost with varying degrees of antiquity. We also summarize contamination control best practices and highlight considerations for the latest approaches, including shotgun metagenomics, and downstream bioinformatic authentication approaches. We review the adoption of existing software and provide an overview of more recently published programs, with reference to their suitability for AEM studies. Finally, we summarize outstanding challenges and likely future directions for AEM research., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

29. The mutual regulation between the pattern recognition receptor OsCERK1 and the E3 ubiquitin ligase OsCIE1 controls induction and homeostasis of immunity.

Author

Wang Q and Kawano Y

Published

2024

30. Analysis of the effect of permeant solutes on the hydraulic resistance of the plasma membrane in cells of Chara corallina.

Author

Tazawa M, Wayne R, and Katsuhara M

Abstract

In the cells of Chara corallina, permeant monohydric alcohols including methanol, ethanol and 1-propanol increased the hydraulic resistance of the membrane (Lp m ). We found that the relative value of the hydraulic resistance ( -1 ). We found that the relative value of the hydraulic resistance ( r Lp m ) of the alcohol. The relationship is expressed in the equation: -1 ) was linearly dependent on the concentration (C s ) of the alcohol. The relationship is expressed in the equation: r Lp m -1 is the hydraulic resistance modifier coefficient of the membrane. Ye et al. (2004) showed that membrane-permeant glycol ethers also increased Lp m C s and m is the hydraulic resistance modifier coefficient of the membrane. Ye et al. (2004) showed that membrane-permeant glycol ethers also increased Lp -1 . The values of m -1 and r values of all the permeant alcohols and glycol ethers against their molecular weights (MW), we obtained a linear curve with a slope of 0.014 M m /MW and with a correlation coefficient of 0.99. We analyzed the influence of the permeant solutes on the relative hydraulic resistance of the membrane ( -1 . The values of r ) as a function of the external (π m ) and internal (π -1 fit the above relation we found for alcohols. When we plotted the ρ m ) were linearly related to the MW of the permeant solutes with a slope of 0.012 M -1 /MW and with a correlation coefficient of 0.84. The linear relationship between the effects of permeating solutes on the hydraulic resistance modifier coefficient (ρ r ) and the MW can be explained in terms of the effect of the effective osmotic pressure on the hydraulic conductivity of water channels. The result of the analysis suggests that the osmotic pressure and not the size of the permeant solute as proposed by (Ye et al., J Exp Bot 55:449-461, 2004) is the decisive factor in a solute's influence on hydraulic conductivity. Thus, characean water channels (aquaporins) respond to permeant solutes with essentially the same mechanism as to impermeant solutes.m -1 ) as a function of the external (π 0 ) and internal (π i ) osmotic pressures. The analysis showed that the hydraulic resistance modifier coefficients (ρ m ) were linearly related to the MW of the permeant solutes with a slope of 0.012 M -1 /MW and with a correlation coefficient of 0.84. The linear relationship between the effects of permeating solutes on the hydraulic resistance modifier coefficient (ρ m ) and the MW can be explained in terms of the effect of the effective osmotic pressure on the hydraulic conductivity of water channels. The result of the analysis suggests that the osmotic pressure and not the size of the permeant solute as proposed by (Ye et al., J Exp Bot 55:449-461, 2004) is the decisive factor in a solute's influence on hydraulic conductivity. Thus, characean water channels (aquaporins) respond to permeant solutes with essentially the same mechanism as to impermeant solutes., (© 2024. The Author(s).)

Published

2024

31. OsHAK4 functions in retrieving sodium from the phloem at the reproductive stage of rice.

Author

Che J, Yamaji N, Wang SF, Xia Y, Yang SY, Su YH, Shen RF, and Ma JF

Subjects

Reproduction, Cation Transport Proteins metabolism, Cation Transport Proteins genetics, Oryza genetics, Oryza metabolism, Oryza growth & development, Phloem metabolism, Phloem genetics, Plant Proteins metabolism, Plant Proteins genetics, Sodium metabolism, Gene Expression Regulation, Plant

Abstract

Soil salinity significantly limits rice productivity, but it is poorly understood how excess sodium (Na + ) is delivered to the grains at the reproductive stage. Here, we functionally characterized OsHAK4, a member of the clade IV HAK/KUP/KT transporter subfamily in rice. OsHAK4 was localized to the plasma membrane and exhibited influx transport activity for Na + , but not for K + . Analysis of organ- and growth stage-dependent expression patterns showed that very low expression levels of OsHAK4 were detected at the vegetative growth stage, but its high expression in uppermost node I, peduncle, and rachis was found at the reproductive stage. Immunostaining indicated OsHAK4 localization in the phloem region of node I, peduncle, and rachis. Knockout of OsHAK4 did not affect the growth and Na + accumulation at the vegetative stage. However, at the reproductive stage, the hak4 mutants accumulated higher Na + in the peduncle, rachis, husk, and brown rice compared to the wild-type rice. Element imaging revealed higher Na + accumulation at the phloem region of the peduncle in the mutants. These results indicate that OsHAK4 plays a crucial role in retrieving Na + from the phloem in the upper nodes, peduncle, and rachis, thereby preventing Na + distribution to the grains at the reproductive stage of rice., (© 2024 The Author(s). The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

32. Chromosome-specific barcode system with centromeric repeat in cultivated soybean and wild progenitor.

Author

Tek AL, Nagaki K, Yıldız Akkamış H, Tanaka K, and Kobayashi H

Subjects

DNA Barcoding, Taxonomic methods, Domestication, Genome, Plant genetics, Histones genetics, Histones metabolism, Plant Breeding methods, DNA, Plant genetics, Glycine max genetics, Centromere genetics, Chromosomes, Plant genetics

Abstract

Wild soybean Glycine soja is the progenitor of cultivated soybean Glycine max Information on soybean functional centromeres is limited despite extensive genome analysis. These species are an ideal model for studying centromere dynamics for domestication and breeding. We performed a detailed chromatin immunoprecipitation analysis using centromere-specific histone H3 protein to delineate two distinct centromeric DNA sequences with unusual repeating units with monomer sizes of 90-92 bp (CentGm-1) and 413-bp (CentGm-4) shorter and longer than standard nucleosomes. These two unrelated DNA sequences with no sequence similarity are part of functional centromeres in both species. Our results provide a comparison of centromere properties between a cultivated and a wild species under the effect of the same kinetochore protein. Possible sequence homogenization specific to each chromosome could highlight the mechanism for evolutionary conservation of centromeric properties independent of domestication and breeding. Moreover, a unique barcode system to track each chromosome is developed using CentGm-4 units. Our results with a unifying centromere composition model using CentGm-1 and CentGm-4 superfamilies could have far-reaching implications for comparative and evolutionary genome research., (© 2024 Tek et al.)

Published

2024

33. Breeding for an elite malting barley cultivar with acid soil tolerance.

Author

Huang S, Sato K, and Ma JF

Subjects

Plant Breeding, Plant Proteins genetics, Plant Proteins metabolism, Gene Expression Regulation, Plant, Plant Roots genetics, Plant Roots metabolism, Plant Roots growth & development, Acids metabolism, Carrier Proteins, Hordeum genetics, Hordeum drug effects, Hordeum metabolism, Hordeum growth & development, Soil chemistry, Aluminum toxicity, Aluminum metabolism

Abstract

Barley (Hordeum vulgare L.) is the fourth most produced cereal crop in the world, but its productivity on acid soil has been restricted due to its high sensitivity to aluminum (Al) toxicity. The major gene controlling Al tolerance in barley is HvAACT1 (Al-activated citrate transporter 1), which is involved in citrate secretion from the roots for Al detoxification. Here we bred a malting barley cultivar with enhanced acid soil tolerance by introgression of a 1-kb transposon regulating the expression of HvAACT1 into an elite malting cultivar through multiple backcrossing and marker-assisted selection. The line selected showed increased expression of HvAACT1, enhanced citrate secretion from the roots and decreased Al binding to the roots. This line produced more than two to three times the grain yield compared with the original cultivar when grown on acidic soil, providing a potentially sustainable and economic way to boost productivity of malting barley cultivars in areas with acidic soil., (© 2024. The Author(s).)

Published

2024

34. Cytosolic acidification and oxidation are the toxic mechanisms of SO2 in Arabidopsis guard cells.

Author

Mozhgani M, Ooi L, Espagne C, Filleur S, and Mori IC

Subjects

Hydrogen-Ion Concentration, Mesophyll Cells metabolism, Mesophyll Cells drug effects, Arabidopsis Proteins metabolism, Arabidopsis Proteins genetics, Chloride Channels metabolism, Chloride Channels genetics, Gene Expression Regulation, Plant drug effects, Arabidopsis metabolism, Arabidopsis genetics, Arabidopsis drug effects, Cytosol metabolism, Oxidation-Reduction, Sulfur Dioxide toxicity, Sulfur Dioxide metabolism

Abstract

SO2/H2SO3 can damage plants. However, its toxic mechanism has still been controversial. Two models have been proposed, cytosolic acidification model and cellular oxidation model. Here, we assessed the toxic mechanism of H2SO3 in three cell types of Arabidopsis thaliana, mesophyll cells, guard cells (GCs), and petal cells. The sensitivity of GCs of Chloride channel a (CLCa)-knockout mutants to H2SO3 was significantly lower than those of wildtype plants. Expression of other CLC genes in mesophyll cells and petal cells were different from GCs. Treatment with antioxidant, disodium 4,5-dihydroxy-1,3-benzenedisulfonate (tiron), increased the median lethal concentration (LC50) of H2SO3 in GCs indicating the involvement of cellular oxidation, while the effect was negligible in mesophyll cells and petal cells. These results indicate that there are two toxic mechanisms of SO2 to Arabidopsis cells: cytosolic acidification and cellular oxidation, and the toxic mechanism may vary among cell types., (© The Author(s) 2024. Published by Oxford University Press on behalf of Japan Society for Bioscience, Biotechnology, and Agrochemistry.)

Published

2024

35. Dormancy regulator Prunus mume DAM6 promotes ethylene-mediated leaf senescence and abscission.

Author

Hsiang TF, Chen YY, Nakano R, Oikawa A, Matsuura T, Ikeda Y, and Yamane H

Subjects

MADS Domain Proteins genetics, MADS Domain Proteins metabolism, Plant Dormancy genetics, Plant Growth Regulators metabolism, Plant Senescence, Plants, Genetically Modified, Prunus persica genetics, Prunus persica growth & development, Prunus persica metabolism, Seasons, Ethylenes metabolism, Gene Expression Regulation, Plant, Plant Leaves genetics, Plant Leaves growth & development, Plant Proteins genetics, Plant Proteins metabolism, Prunus genetics, Prunus growth & development, Prunus physiology

Abstract

Leaf senescence and abscission in autumn are critical phenological events in deciduous woody perennials. After leaf fall, dormant buds remain on deciduous woody perennials, which then enter a winter dormancy phase. Thus, leaf fall is widely believed to be linked to the onset of dormancy. In Rosaceae fruit trees, DORMANCY-ASSOCIATED MADS-box (DAM) transcription factors control bud dormancy. However, apart from their regulatory effects on bud dormancy, the biological functions of DAMs have not been thoroughly characterized. In this study, we revealed a novel DAM function influencing leaf senescence and abscission in autumn. In Prunus mume, PmDAM6 expression was gradually up-regulated in leaves during autumn toward leaf fall. Our comparative transcriptome analysis using two RNA-seq datasets for the leaves of transgenic plants overexpressing PmDAM6 and peach (Prunus persica) DAM6 (PpeDAM6) indicated Prunus DAM6 may up-regulate the expression of genes involved in ethylene biosynthesis and signaling as well as leaf abscission. Significant increases in 1-aminocyclopropane-1-carboxylate accumulation and ethylene emission in DEX-treated 35S:PmDAM6-GR leaves reflect the inductive effect of PmDAM6 on ethylene biosynthesis. Additionally, ethephon treatments promoted autumn leaf senescence and abscission in apple and P. mume, mirroring the changes due to PmDAM6 overexpression. Collectively, these findings suggest that PmDAM6 may induce ethylene emission from leaves, thereby promoting leaf senescence and abscission. This study clarified the effects of Prunus DAM6 on autumn leaf fall, which is associated with bud dormancy onset. Accordingly, in Rosaceae, DAMs may play multiple important roles affecting whole plant growth during the tree dormancy induction phase., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

36. Mutations in starch BRANCHING ENZYME 2a suppress the traits caused by the loss of ISOAMYLASE1 in barley.

Author

Matsushima R, Hisano H, Kim JS, McNelly R, Oitome NF, Seung D, Fujita N, and Sato K

Subjects

Plant Proteins genetics, Plant Proteins metabolism, Hordeum genetics, Hordeum enzymology, Hordeum growth & development, Phenotype, Starch metabolism, Endosperm genetics, 1,4-alpha-Glucan Branching Enzyme genetics, 1,4-alpha-Glucan Branching Enzyme metabolism, Mutation, Isoamylase genetics, Isoamylase metabolism

Abstract

Key Message: The hvbe2a mutations restore the starch-deficient phenotype caused by the hvisa1 and hvflo6 mutations in barley endosperm. The genetic interactions among starch biosynthesis genes can be exploited to alter starch properties, but they remain poorly understood due to the various combinations of mutations to be tested. Here, we isolated two novel barley mutants defective in starch BRANCHING ENZYME 2a (hvbe2a-1 and hvbe2a-2) based on the starch granule (SG) morphology. Both hvbe2a mutants showed elongated SGs in the endosperm and increased resistant starch content. hvbe2a-1 had a base change in HvBE2a gene, substituting the amino acid essential for its enzyme activity, while hvbe2a-2 is completely missing HvBE2a due to a chromosomal deletion. Further genetic crosses with barley isoamylase1 mutants (hvisa1) revealed that both hvbe2a mutations could suppress defects in endosperm caused by hvisa1, such as reduction in starch, increase in phytoglycogen, and changes in the glucan chain length distribution. Remarkably, hvbe2a mutations also transformed the endosperm SG morphology from the compound SG caused by hvisa1 to bimodal simple SGs, resembling that of wild-type barley. The suppressive impact was in competition with floury endosperm 6 mutation (hvflo6), which could enhance the phenotype of hvisa1 in the endosperm. In contrast, the compound SG formation induced by the hvflo6 hvisa1 mutation in pollen was not suppressed by hvbe2a mutations. Our findings provide new insights into genetic interactions in the starch biosynthetic pathway, demonstrating how specific genetic alterations can influence starch properties and SG morphology, with potential applications in cereal breeding for desired starch properties., (© 2024. The Author(s).)

Published

2024

37. New lineages of RNA viruses from clinical isolates of Rhizopus microsporus revealed by fragmented and primer-ligated dsRNA sequencing (FLDS) analysis.

Author

Sa'diyah W, Zhao Y-J, Chiba Y, Kondo H, Suzuki N, Ban S, Yaguchi T, Urayama S-i, and Hagiwara D

Subjects

Humans, Sequence Analysis, RNA, Rhizopus genetics, Rhizopus classification, RNA Viruses genetics, RNA Viruses classification, RNA Viruses isolation & purification, Mucormycosis microbiology, Mucormycosis virology, Genome, Viral, RNA, Double-Stranded genetics, Phylogeny, RNA, Viral genetics

Abstract

Rhizopus microsporus is a species in the order Mucorales that is known to cause mucormycosis, but it is poorly understood as a host of viruses. Here, we examined 25 clinical strains of R. microsporus for viral infection with a conventional double-stranded RNA (dsRNA) assay using agarose gel electrophoresis (AGE) and the recently established fragmented and primer-ligated dsRNA sequencing (FLDS) protocol. By AGE, five virus-infected strains were detected. Then, full-length genomic sequences of 12 novel RNA viruses were revealed by FLDS, which were related to the families Mitoviridae, Narnaviridae, and Endornaviridae, ill-defined groups of single-stranded RNA (ssRNA) viruses with similarity to the established families Virgaviridae and Phasmaviridae, and the proposed family "Ambiguiviridae." All the characterized viruses, except a potential phasmavirid with a negative-sense RNA genome, had positive-sense RNA genomes. One virus belonged to a previously established species within the family Mitoviridae , whereas the other 11 viruses represented new species or even new genera. These results show that the fungal pathogen R. microsporus harbors diverse RNA viruses and extend our understanding of the diversity of RNA viruses in the fungal order Mucorales, division Mucoromycota. Identifying RNA viruses from clinical isolates of R. microsporus may expand the repertoire of natural therapeutic agents for mucormycosis in the future.IMPORTANCEThe diversity of mycoviruses in fungal hosts in the division Mucoromycota has been underestimated, mainly within the species Rhizopus microsporus . Only five positive-sense RNA genomes had previously been discovered in this species. Because current sequencing methods poorly complete the termini of genomes, we used fragmented and primer-ligated double-stranded RNA sequencing to acquire the full-length genomes. Eleven novel mycoviruses were detected in this study, including the first negative-sense RNA genome reported in R. microsporus . Our findings extend the understanding of the viral diversity in clinical strains of Mucoromycota, may provide insights into the pathogenesis and ecology of this fungus, and may offer therapeutic options., Competing Interests: The authors declare no conflict of interest.

Published

2024

38. Tissue-specific deposition, speciation and transport of antimony in rice.

Author

Huang H, Yamaji N, and Ma JF

Subjects

Biological Transport, Plant Proteins metabolism, Plant Proteins genetics, Plant Shoots metabolism, Plant Shoots genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae genetics, Oryza metabolism, Oryza genetics, Antimony metabolism, Plant Roots metabolism

Abstract

Rice (Oryza sativa) as a staple food is a potential intake source of antimony (Sb), a toxic metalloid. However, how rice accumulates this element is still poorly understood. Here, we investigated tissue-specific deposition, speciation, and transport of Sb in rice. We found that Sb(III) is the preferential form of Sb uptake in rice, but most Sb accumulates in the roots, resulting in a very low root-to-shoot translocation (less than 2%). Analysis of Sb deposition with laser ablation-inductively coupled plasma-mass spectrometry showed that most Sb deposits at the root exodermis. Furthermore, we found that Sb is mainly present as Sb(III) in the root cell sap after uptake. Further characterization showed that Sb(III) uptake is mediated by Low silicon rice 1 (Lsi1), a Si permeable transporter. Lsi1 showed transport activity for Sb(III) rather than Sb(V) in yeast (Saccharomyces cerevisiae). Knockout of Lsi1 resulted in a significant decrease in Sb accumulation in both roots and shoots. Sb concentration in the root cell sap of two independent lsi1 mutants decreased to less than 3% of that in wild-type rice, indicating that Lsi1 is a major transporter for Sb(III) uptake. Knockout of Lsi1 also enhanced rice tolerance to Sb toxicity. However, knockout of Si efflux transporter genes, including Lsi2 and Lsi3, did not affect Sb accumulation. Taken together, our results showed that Sb(III) is taken up by Lsi1 localized at the root exodermis and is deposited at this cell layer due to lack of Sb efflux transporters in rice., Competing Interests: Conflict of interest statement. None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists.)

Published

2024

39. Light-Driven H 2 Production in Chlamydomonas reinhardtii : Lessons from Engineering of Photosynthesis.

Author

Hippler M and Khosravitabar F

Abstract

In the green alga Chlamydomonas reinhardtii , hydrogen production is catalyzed via the [FeFe]-hydrogenases HydA1 and HydA2. The electrons required for the catalysis are transferred from ferredoxin (FDX) towards the hydrogenases. In the light, ferredoxin receives its electrons from photosystem I (PSI) so that H 2 production becomes a fully light-driven process. HydA1 and HydA2 are highly O 2 sensitive; consequently, the formation of H 2 occurs mainly under anoxic conditions. Yet, photo-H 2 production is tightly coupled to the efficiency of photosynthetic electron transport and linked to the photosynthetic control via the Cyt b complex, the control of electron transfer at the level of photosystem II (PSII) and the structural remodeling of photosystem I (PSI). These processes also determine the efficiency of linear (LEF) and cyclic electron flow (CEF). The latter is competitive with H 6 f photoproduction. Consequently, an in-depth understanding of light-driven H 2 production via photosynthetic electron transfer and its competition with CO 2 photoproduction. Consequently, an in-depth understanding of light-driven H 2 production. At the same time, the smart design of photo-H 2 production schemes and photo-H 2 bioreactors are challenges for efficient up-scaling of light-driven photo-H 2 production schemes and photo-H 2 bioreactors are challenges for efficient up-scaling of light-driven photo-H 2 production.

Published

2024

40. An investigation of the pigments, antioxidants and free radical scavenging potential of twenty medicinal weeds found in the southern part of Bangladesh.

Author

Sumi MJ, Zaman SB, Imran S, Sarker P, Rhaman MS, Gaber A, Skalicky M, Moulick D, and Hossain A

Subjects

Bangladesh, Plant Leaves chemistry, Flavonoids analysis, Flavonoids chemistry, Phenols analysis, Phenols chemistry, Plant Extracts chemistry, Pigments, Biological chemistry, Pigments, Biological analysis, Chlorophyll analysis, Antioxidants chemistry, Antioxidants analysis, Antioxidants pharmacology, Plant Weeds chemistry, Free Radical Scavengers chemistry, Plants, Medicinal chemistry

Abstract

Despite their overlooked status, weeds are increasingly recognized for their therapeutic value, aligning with historical reliance on plants for medicine and nutrition. This study investigates the medicinal potential of native weed species in Bangladesh, specifically pigments, antioxidants, and free radical scavenging abilities. Twenty different medicinal weed species were collected from the vicinity of Khulna Agricultural University and processed in the Crop Botany Department Laboratory. Pigment levels were determined using spectrophotometer analysis, and phenolics, flavonoids, and DPPH were quantified accordingly. Chlorophyll levels in leaves ranged from 216.70 ± 9.41 to 371.14 ± 28.67 µg g -1 FW, and in stems from 51.98 ± 3.21 to 315.89 ± 17.19 µg g -1 FW. Flavonoid content also varied widely, from 1,624.62 ± 102.03 to 410.00 ± 115.58 mg CE 100 g -1 FW in leaves, and from 653.08 ± 32.42 to 80.00 ± 18.86 mg CE 100 g -1 FW in stems. In case of phenolics content Euphorbia hirta L. displaying the highest total phenolic content in leaves (1,722.33 ± 417.89 mg GAE 100 g -1 FW) and Ruellia tuberosa L. in stems (977.70 ± 145.58 mg GAE 100 g -1 FW). The lowest DPPH 2.505 ± 1.028 mg mL -1 was found in Heliotropium indicum L. leaves. Hierarchical clustering links species with pigment, phenolic/flavonoid content, and antioxidant activity. PCA, involving 20 species and seven traits, explained 70.07% variability, with significant PC1 (14.82%) and PC2 (55.25%). Leaves were shown to be superior, and high-performing plants such as E. hirta and H. indicum stood out for their chemical composition and antioxidant activity. Thus, this research emphasizes the value of efficient selection while concentrating on the therapeutic potential of native weed species., Competing Interests: The authors declare that there is no conflict of interest in the article., (©2024 Sumi et al.)

Published

2024

41. Metatranscriptomic Sequencing of Sheath Blight-Associated Isolates of Rhizoctonia solani Revealed Multi-Infection by Diverse Groups of RNA Viruses.

Author

Urzo MLR, Guinto TD, Eusebio-Cope A, Budot BO, Yanoria MJT, Jonson GB, Arakawa M, Kondo H, and Suzuki N

Subjects

Genome, Viral, RNA, Viral genetics, High-Throughput Nucleotide Sequencing, RNA, Double-Stranded genetics, Fungal Viruses genetics, Fungal Viruses classification, Fungal Viruses isolation & purification, Philippines, Transcriptome, Rhizoctonia virology, Rhizoctonia genetics, Plant Diseases microbiology, Plant Diseases virology, Oryza microbiology, Oryza virology, RNA Viruses genetics, RNA Viruses isolation & purification, RNA Viruses classification, Phylogeny

Abstract

Rice sheath blight, caused by the soil-borne fungus Rhizoctonia solani (teleomorph: Thanatephorus cucumeris, Basidiomycota), is one of the most devastating phytopathogenic fungal diseases and causes yield loss. Here, we report on a very high prevalence (100%) of potential virus-associated double-stranded RNA (dsRNA) elements for a collection of 39 fungal strains of R. solani from the rice sheath blight samples from at least four major rice-growing areas in the Philippines and a reference isolate from the International Rice Research Institute, showing different colony phenotypes. Their dsRNA profiles suggested the presence of multiple viral infections among these Philippine R. solani populations. Using next-generation sequencing, the viral sequences of the three representative R. solani strains (Ilo-Rs-6, Tar-Rs-3, and Tar-Rs-5) from different rice-growing areas revealed the presence of at least 36 viruses or virus-like agents, with the Tar-Rs-3 strain harboring the largest number of viruses (at least 20 in total). These mycoviruses or their candidates are believed to have single-stranded RNA or dsRNA genomes and they belong to or are associated with the orders Martellivirales , Hepelivirales , Durnavirales , Cryppavirales , Ourlivirales , and Ghabrivirales based on their coding-complete RNA-dependent RNA polymerase sequences. The complete genome sequences of two novel RNA viruses belonging to the proposed family Phlegiviridae and family Mitoviridae were determined.

Published

2024

42. Identification of a novel member of the genus Laulavirus (family Phenuiviridae) from the entomopathogenic ascomycete fungus Cordyceps javanica.

Author

Cao X, Liu B, Wang Z, Pang T, Sun L, Kondo H, Li J, Andika IB, and Chi S

Subjects

Fungal Viruses classification, Fungal Viruses genetics, Fungal Viruses isolation & purification, Viral Proteins genetics, Negative-Sense RNA Viruses genetics, Negative-Sense RNA Viruses classification, RNA-Dependent RNA Polymerase genetics, RNA Viruses genetics, RNA Viruses classification, RNA Viruses isolation & purification, Amino Acid Sequence, Open Reading Frames, Phylogeny, Genome, Viral, Cordyceps genetics, RNA, Viral genetics

Abstract

The virus family Phenuiviridae (order Hareavirales, comprising segmented negative-sense single stranded RNA viruses) has highly diverse members that are known to infect animals, plants, protozoans, and fungi. In this study, we identified a novel phenuivirus infecting a strain of the entomopathogenic fungus Cordyceps javanica isolated from a small brown plant hopper (Laodelphax striatellus), and this virus was tentatively named "Cordyceps javanica negative-strand RNA virus 1" (CjNRSV1). The CjNRSV1 genome consists of three negative-sense single stranded RNA segments (RNA1-3) with lengths of 7252, 2401, and 1117 nt, respectively. The 3'- and 5'-terminal regions of the RNA1, 2, and 3 segments have identical sequences, and the termini of the RNA segments are complementary to each other, reflecting a common characteristic of viruses in the order Hareavirales. RNA1 encodes a large protein (∼274 kDa) containing a conserved domain for the bunyavirus RNA-dependent RNA polymerase (RdRP) superfamily, with 57-80% identity to the RdRP encoded by phenuiviruses in the genus Laulavirus. RNA2 encodes a protein (∼79 kDa) showing sequence similarity (47-63% identity) to the movement protein (MP, a plant viral cell-to-cell movement protein)-like protein (MP-L) encoded by RNA2 of laulaviruses. RNA3 encodes a protein (∼28 kDa) with a conserved domain of the phenuivirid nucleocapsid protein superfamily. Phylogenetic analysis using the RdRPs of various phenuiviruses and other unclassified phenuiviruses showed CjNRSV1 to be grouped with established members of the genus Laulavirus. Our results suggest that CjNRSV1 is a novel fungus-infecting member of the genus Laulavirus in the family Phenuiviridae., (© 2024. The Author(s), under exclusive licence to Springer-Verlag GmbH Austria, part of Springer Nature.)

Published

2024

43. Genetic background influences mineral accumulation in rice straw and grains under different soil pH conditions.

Author

Yamamoto T, Kashihara K, Furuta T, Zhang Q, Yu E, and Ma JF

Subjects

Hydrogen-Ion Concentration, Genetic Background, Edible Grain metabolism, Edible Grain genetics, Oryza genetics, Oryza metabolism, Soil chemistry, Minerals metabolism, Minerals analysis

Abstract

Mineral element accumulation in plants is influenced by soil conditions and varietal factors. We investigated the dynamic accumulation of 12 elements in straw at the flowering stage and in grains at the mature stage in eight rice varieties with different genetic backgrounds (Japonica, Indica, and admixture) and flowering times (early, middle, and late) grown in soil with various pH levels. In straw, Cd, As, Mn, Zn, Ca, Mg, and Cu accumulation was influenced by both soil pH and varietal factors, whereas P, Mo, and K accumulation was influenced by pH, and Fe and Ni accumulation was affected by varietal factors. In grains, Cd, As, Mn, Cu, Ni, Mo, Ca, and Mg accumulation was influenced by both pH and varietal factors, whereas Zn, Fe, and P accumulation was affected by varietal factors, and K accumulation was not altered. Only As, Mn, Ca and Mg showed similar trends in the straw and grains, whereas the pH responses of Zn, P, K, and Ni differed between them. pH and flowering time had synergistic effects on Cd, Zn, and Mn in straw and on Cd, Ni, Mo, and Mn in grains. Soil pH is a major factor influencing mineral uptake in rice straw and grains, and genetic factors, flowering stage factors, and their interaction with soil pH contribute in a combined manner., (© 2024. The Author(s).)

Published

2024

44. Metal Transport Systems in Plants.

Author

Huang S, Yamaji N, and Ma JF

Subjects

Biological Transport, Plant Proteins metabolism, Plant Proteins genetics, Membrane Transport Proteins metabolism, Cadmium metabolism, Gene Expression Regulation, Plant, Plants metabolism, Metals metabolism

Abstract

Plants take up metals, including essential micronutrients [iron (Fe), copper (Cu), zinc (Zn), and manganese (Mn)] and the toxic heavy metal cadmium (Cd), from soil and accumulate these metals in their edible parts, which are direct and indirect intake sources for humans. Multiple transporters belonging to different families are required to transport a metal from the soil to different organs and tissues, but only a few of them have been fully functionally characterized. The transport systems (the transporters required for uptake, translocation, distribution, redistribution, and their regulation) differ with metals and plant species, depending on the physiological roles, requirements of each metal, and anatomies of different organs and tissues. To maintain metal homeostasis in response to spatiotemporal fluctuations of metals in soil, plants have developed sophisticated and tightly regulated mechanisms through the regulation of transporters at the transcriptional and/or posttranscriptional levels. The manipulation of some transporters has succeeded in generating crops rich in essential metals but low in Cd accumulation. A better understanding of metal transport systems will contribute to better and safer crop production.

Published

2024

45. Argonaute-independent, Dicer-dependent antiviral defense against RNA viruses.

Author

Sato Y, Kondo H, and Suzuki N

Subjects

Argonaute Proteins metabolism, Argonaute Proteins genetics, Ascomycota virology, RNA Interference, Virus Replication genetics, RNA, Viral metabolism, RNA, Viral genetics, Fungal Proteins metabolism, Fungal Proteins genetics, RNA, Double-Stranded metabolism, Ribonuclease III metabolism, Ribonuclease III genetics, RNA Viruses immunology, RNA Viruses genetics

Abstract

Antiviral RNA interference (RNAi) is conserved from yeasts to mammals. Dicer recognizes and cleaves virus-derived double-stranded RNA (dsRNA) and/or structured single-stranded RNA (ssRNA) into small-interfering RNAs, which guide effector Argonaute to homologous viral RNAs for digestion and inhibit virus replication. Thus, Argonaute is believed to be essential for antiviral RNAi. Here, we show Argonaute-independent, Dicer-dependent antiviral defense against dsRNA viruses using Cryphonectria parasitica (chestnut blight fungus), which is a model filamentous ascomycetous fungus and hosts a variety of viruses. The fungus has two dicer-like genes ( dcl1 and dcl2 ) and four argonaute-like genes ( agl1 to agl4 ). We prepared a suite of single to quadruple agl knockout mutants with or without dcl disruption. We tested these mutants for antiviral activities against diverse dsRNA viruses and ssRNA viruses. Although both DCL2 and AGL2 worked as antiviral players against some RNA viruses, DCL2 without argonaute was sufficient to block the replication of other RNA viruses. Overall, these results indicate the existence of a Dicer-alone defense and different degrees of susceptibility to it among RNA viruses. We discuss what determines the great difference in susceptibility to the Dicer-only defense., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

46. Replication of single viruses across the kingdoms, Fungi, Plantae, and Animalia.

Author

Telengech P, Hyodo K, Ichikawa H, Kuwata R, Kondo H, and Suzuki N

Subjects

Animals, RNA Viruses genetics, RNA Viruses physiology, Fungal Viruses genetics, Fungal Viruses classification, Fungal Viruses physiology, Phylogeny, Protoplasts virology, Plant Diseases virology, Plant Diseases microbiology, Spodoptera virology, Spodoptera microbiology, Nicotiana virology, Nicotiana microbiology, Virus Replication, Daucus carota virology, Daucus carota microbiology

Abstract

It is extremely rare that a single virus crosses host barriers across multiple kingdoms. Based on phylogenetic and paleovirological analyses, it has previously been hypothesized that single members of the family Partitiviridae could cross multiple kingdoms. Partitiviridae accommodates members characterized by their simple bisegmented double-stranded RNA genome; asymptomatic infections of host organisms; the absence of an extracellular route for entry in nature; and collectively broad host range. Herein, we show the replicability of single fungal partitiviruses in three kingdoms of host organisms: Fungi, Plantae, and Animalia. Betapartitiviruses of the phytopathogenic fungus Rosellinia necatrix could replicate in protoplasts of the carrot ( Daucus carota ), Nicotiana benthamiana and Nicotiana tabacum , in some cases reaching a level detectable by agarose gel electrophoresis. Moreover, betapartitiviruses showed more robust replication than the tested alphapartitiviruses. One of the fungal betapartitiviruses, RnPV18, could persistently and stably infect carrot plants regenerated from virion-transfected protoplasts. Both alpha- and betapartitiviruses, although with different host preference, could replicate in two insect cell lines derived from the fall armyworm Spodoptera frugiperda and the fruit fly Drosophila melanogaster . Our results indicate the replicability of single partitiviruses in members of three kingdoms and provide insights into virus adaptation, host jumping, and evolution., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

47. Chemical Protein Crosslinking-Coupled Mass Spectrometry Reveals Interaction of LHCI with LHCII and LHCSR3 in Chlamydomonas reinhardtii .

Author

Mosebach L, Ozawa SI, Younas M, Xue H, Scholz M, Takahashi Y, and Hippler M

Abstract

The photosystem I (PSI) of the green alga Chlamydomonas reinhardtii associates with 10 light-harvesting proteins (LHCIs) to form the PSI-LHCI complex. In the context of state transitions, two LHCII trimers bind to the PSAL, PSAH and PSAO side of PSI to produce the PSI-LHCI-LHCII complex. In this work, we took advantage of chemical crosslinking of proteins in conjunction with mass spectrometry to identify protein-protein interactions between the light-harvesting proteins of PSI and PSII. We detected crosslinks suggesting the binding of LHCBM proteins to the LHCA1-PSAG side of PSI as well as protein-protein interactions of LHCSR3 with LHCA5 and LHCA3. Our data indicate that the binding of LHCII to PSI is more versatile than anticipated and imply that LHCSR3 might be involved in the regulation of excitation energy transfer to the PSI core via LHCA5/LHCA3.

Published

2024

48. The red alga Porphyridium as a host for molecular farming: Efficient production of immunologically active hepatitis C virus glycoprotein.

Author

Hammel A, Cucos LM, Caras I, Ionescu I, Tucureanu C, Tofan V, Costache A, Onu A, Hoepfner L, Hippler M, Neupert J, Popescu CI, Stavaru C, Branza-Nichita N, and Bock R

Subjects

Glycosylation, Viral Envelope Proteins immunology, Viral Envelope Proteins genetics, Viral Envelope Proteins metabolism, Recombinant Proteins genetics, Recombinant Proteins immunology, Recombinant Proteins metabolism, Animals, Porphyridium metabolism, Porphyridium immunology, Porphyridium genetics, Hepacivirus immunology, Hepacivirus genetics

Abstract

Microalgae are promising production platforms for the cost-effective production of recombinant proteins. We have recently established that the red alga Porphyridium purpureum provides superior transgene expression properties, due to the episomal maintenance of transformation vectors as multicopy plasmids in the nucleus. Here, we have explored the potential of Porphyridium to synthesize complex pharmaceutical proteins to high levels. Testing expression constructs for a candidate subunit vaccine against the hepatitis C virus (HCV), we show that the soluble HCV E2 glycoprotein can be produced in transgenic algal cultures to high levels. The antigen undergoes faithful posttranslational modification by N-glycosylation and is recognized by conformationally selective antibodies, suggesting that it adopts a proper antigenic conformation in the endoplasmic reticulum of red algal cells. We also report the experimental determination of the structure of the N-glycan moiety that is attached to glycosylated proteins in Porphyridium . Finally, we demonstrate the immunogenicity of the HCV antigen produced in red algae when administered by injection as pure protein or by feeding of algal biomass., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

49. Characterization of organelle DNA degradation mediated by DPD1 exonuclease in the rice genome-edited line.

Author

Islam MF, Yamatani H, Takami T, Kusaba M, and Sakamoto W

Subjects

Plant Proteins genetics, Plant Proteins metabolism, Exonucleases metabolism, Exonucleases genetics, Gene Editing, Gene Expression Regulation, Plant, DNA, Plant genetics, DNA, Plant metabolism, Pollen genetics, Pollen metabolism, Pollen growth & development, Plant Leaves genetics, Plant Leaves metabolism, Genome, Plant, Mutation, Oryza genetics, Oryza metabolism, Oryza enzymology, Oryza growth & development

Abstract

Mitochondria and plastids, originated as ancestral endosymbiotic bacteria, contain their own DNA sequences. These organelle DNAs (orgDNAs) are, despite the limited genetic information they contain, an indispensable part of the genetic systems but exist as multiple copies, making up a substantial amount of total cellular DNA. Given this abundance, orgDNA is known to undergo tissue-specific degradation in plants. Previous studies have shown that the exonuclease DPD1, conserved among seed plants, degrades orgDNAs during pollen maturation and leaf senescence in Arabidopsis. However, tissue-specific orgDNA degradation was shown to differ among species. To extend our knowledge, we characterized DPD1 in rice in this study. We created a genome-edited (GE) mutant in which OsDPD1 and OsDPD1-like were inactivated. Characterization of this GE plant demonstrated that DPD1 was involved in pollen orgDNA degradation, whereas it had no significant effect on orgDNA degradation during leaf senescence. Comparison of transcriptomes from wild-type and GE plants with different phosphate supply levels indicated that orgDNA had little impact on the phosphate starvation response, but instead had a global impact in plant growth. In fact, the GE plant showed lower fitness with reduced grain filling rate and grain weight in natural light conditions. Taken together, the presented data reinforce the important physiological roles of orgDNA degradation mediated by DPD1., (© 2024. The Author(s).)

Published

2024

50. Characterization of the far-red light absorbing light-harvesting chlorophyll a / b binding complex, a derivative of the distinctive Lhca gene family in green algae.

Author

Kosugi M, Ohtani S, Hara K, Toyoda A, Nishide H, Ozawa SI, Takahashi Y, Kashino Y, Kudoh S, Koike H, and Minagawa J

Abstract

Prasiola crispa , an aerial green alga, exhibits remarkable adaptability to the extreme conditions of Antarctica by forming layered colonies capable of utilizing far-red light for photosynthesis. Despite a recent report on the structure of P. crispa 's unique light-harvesting chlorophyll (Chl)-binding protein complex (Pc-frLHC), which facilitates far-red light absorption and uphill excitation energy transfer to photosystem II, the specific genes encoding the subunits of Pc-frLHC have not yet been identified. Here, we report a draft genome sequence of P. crispa strain 4113, originally isolated from soil samples on Ongul Island, Antarctica. We obtained a 92 Mbp sequence distributed in 1,045 scaffolds comprising 10,244 genes, reflecting 87.1% of the core eukaryotic gene set. Notably, 26 genes associated with the light-harvesting Chl a / b binding complex (LHC) were identified, including four Pc-frLHC genes, with similarity to a noncanonical Lhca gene with four transmembrane helices, such as Ot_Lhca6 in Ostreococcus tauri and Cr_LHCA2 in Chlamydomonas reinhardtii . A comparative analysis revealed that Pc-frLHC shares homology with certain Lhca genes found in Coccomyxa and Trebouxia species. This similarity indicates that Pc-frLHC has evolved from an ancestral Lhca gene with four transmembrane helices and branched out within the Trebouxiaceae family. Furthermore, RNA-seq analysis conducted during the initiation of Pc-frLHC gene induction under red light illumination indicated that Pc-frLHC genes were induced independently from other genes associated with photosystems or LHCs. Instead, the genes of transcription factors, helicases, chaperones, heat shock proteins, and components of blue light receptors were identified to coexpress with Pc-frLHC. Those kinds of information could provide insights into the expression mechanisms of Pc-frLHC and its evolutional development., Competing Interests: The 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. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Kosugi, Ohtani, Hara, Toyoda, Nishide, Ozawa, Takahashi, Kashino, Kudoh, Koike and Minagawa.)

Published

2024