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 | Acceso al texto completo restringido a Biblioteca INIA Las Brujas. Por información adicional contacte bibliolb@inia.org.uy. |
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Registro completo
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Biblioteca (s) : |
INIA Las Brujas. |
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Fecha : |
28/10/2019 |
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Actualizado : |
28/10/2019 |
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Tipo de producción científica : |
Artículos en Revistas Indexadas Internacionales |
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Autor : |
GEORGE, T.S.; GILES, C.D.; MENEZES-BLACKBURN, D.; CONDRON, L.M.; GAMA-RODRIGUES, A.C.; JAISI, D.; LANG, F.; NEAL, A.L.; STUTTER, M.I.; ALMEIDA, D.S.; BOL, R.; CABUGAO, K.G.; CELI, L.; COTNER, J.B.; FENG, G.; GOLL, D.S.; HALLAMA, M.; KRUEGER, J.; PLASSARD, C.; ROSLING, A.; DARCH, T.; FRASER, T.; GIESLER, R.; RICHARDSON, A.E.; TAMBURINI, F.; SHAND, C.A.; LUMSDON, D.G.; ZHANG, H.; BLACKWEL, M.S.A.; WEARING, C.; MEZELI, M.M.; ALMÅS, Å.R.; AUDETTE, Y.; BERTRAND, I.; BEYHAUT, E.; BOITT, G.; BRADSHAW, N.; BREARLEY, C.A.; BRUULSEMA, T.W.; CIAIS, P.; COZZOLINO, V.; DURAN, P.C.; MORA, M.L.; DE MENEZES, A.B.; DODD, R.J.; DUNFIELD, K.; ENGL, C.; FRAZÃO, J.J.; GARLAND, G.; GONZÁLEZ JIMÉNEZ, J.L.; GRACA, J.; GRANGER, S.J.; HARRISON, A.F.; HEUCK, C.; HOU, E.Q.; JOHNES, P.J.; KAISER, K.; KJÆR. H.A.; KLUMPP, E.; LAMB, A.L.; MACINTOSH, K.A.A; MACKAY, E.B.; MCGRATH, J.; MCINTYRE, C.; MCLAREN, T.; MÉSZÁROS, E.; MISSONG, A.; MOOSHAMMER, M.; NEGRÓN, C.P.; NELSON, L.A.; PFAHLER, V.; POBLETE-GRANT, P.; RANDALL, M.; SEGUEL, A.; SETH, K.; SMITH, A.C.; SMITS, M.M.; SOBARZO, J.A.; SPOHN, M.; TAWARAYA, K.; TIBBETT, M.; VORONEY, V.; WALLANDER, H.; WANG, L.; WASAKI, J.; HAYGARTH, P.M. |
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Afiliación : |
T. S. GEORGE, The James Hutton Institute, United Kingdom.; C. D. GILES, The James Hutton Institute, United Kingdom.; D. MENEZES-BLACKBURN, Lancaster Environment Centre, Lancaster University, United Kingdom.; L. M. CONDRON, Lincoln University, New Zealand.; A. C. GAMA-RODRIGUES, Universidade Estadual do Norte Fluminense Darcy Ribeiro (UENF - Laboratório de Solos), Brazil.; D. JAISI, Plant and Soil Sciences, University of Delaware, United States; F. LANG, Plant and Soil Sciences, University of Delaware, United States; A. L. NEAL, Rothamsted Research, West Common, United Kingdom; M. I. STUTTER, The James Hutton Institute, United Kingdom; D. S. ALMEIDA, College of Agricultural Sciences, Department of Crop Science, Sao Paulo State University (UNESP), Brazil; R. BOL, Institute of Bio- and Geosciences, IBG-3: Agrosphere, Germany; K. G. CABUGAO, Oak Ridge National Laboratory, United States; L. CELI, DISAFA, Soil Biogeochemistry, University of Turin, Italy; J. B. COTNER, University of Minnesota, United States; G. FENG, China Agricultural University, Beijing, China; D. S. GOLL, Le Laboratoire des Sciences du Climat et de l’Environnement, IPSL-LSCE CEA/CNRS/UVSQ Saclay, France; M. HALLAMA, Institute of Soil Science, University of Hohenheim, Germany; J. KRUEGER, Faculty of Environment and Natural Resources, Chair of Soil Ecology, University of Freiburg, Germany; C. PLASSARD, INRA UMR ECO&SOLS, Montpellier, France; A. ROSLING, Evolutionary Biology Centre, EBC, Sweden; T. DARCH, Rothamsted Research, West Common, United Kingdom; T. FRASER, Centre for Agri-environmental Research, School of Agriculture Policy and Development, University of Reading, United Kingdom; R. GIESLER, Climate Impacts Research Centre, Dep. of Ecology and Environmental Science, Umeå University, Sweden; A. E. RICHARDSON, CSIRO Agriculture & Food, ACT, Australia; F. TAMBURINI, D-USYS, ETH Zurich, Switzerland; C. A. SHAND, The James Hutton Institute, United Kingdom; D. G. LUMSDON, The James Hutton Institute, United Kingdom; H. ZHANG, Lancaster Environment Centre, Lancaster University, United Kingdom; M. S. A. BLACKWEL, Rothamsted Research, West Common, United Kingdom; C. WEARING, Lancaster Environment Centre, Lancaster University, United Kingdom; M. M. MEZELI, The James Hutton Institute, United Kingdom; Å. R. ALMÅS, Department of Environmental Sciences, Norwegian University of Life Sciences, Norway; Y. AUDETTE, University of Guelph, Canada; I. BERTRAND, INRA UMR ECO&SOLS, Montpellier, France; ELENA BEYHAUT GUTIERREZ, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; G. BOITT, Lincoln University, New Zealand; N. BRADSHAW, Department of Chemical & Biological Engineering, The University of Sheffield, United Kingdom; C. A. BREARLEY, School of Biological Sciences, University of East Anglia, United Kingdom; T. W. BRUULSEMA, International Plant Nutrition Institute, Canada; P. CIAIS, Le Laboratoire des Sciences du Climat et de l’Environnement, IPSL-LSCE CEA/CNRS/UVSQ Saclay, France; V. COZZOLINO, Centro Interdipartimentale di Ricerca sulla Risonanza Magnetica Nucleare per l’Ambiente, l’Agro-Alimentare ed i Nuovi Materiali (CERMANU), Università di Napoli Federico II, Italy; P. C. DURAN, Universidad de La Frontera, Temuco, Chile; M. L. MORA, Centro Interdipartimentale di Ricerca sulla Risonanza Magnetica Nucleare per l’Ambiente, l’Agro-Alimentare ed i Nuovi Materiali (CERMANU), Università di Napoli Federico II, Italy; A. B. DE MENEZES, School of Environment and Life Sciences, University of Salford, United Kingdom; R. J. DODD, School of the Environment, Natural Resources and Geography, Bangor University, United Kingdom; K. DUNFIELD, University of Guelph, Canada; C. ENGL, School of Biological Sciences and Institute for Global Food Security, The Queen’s University of Belfast, United Kingdom; J. J. FRAZÃO, CENA, University of Sao Paulo, Brazil; G. GARLAND, D-USYS, ETH Zurich, Switzerland; J. L. GONZÁLEZ JIMÉNEZ, Teagasc, Environmental Research Centre, Ireland; J. GRACA, Teagasc, Environmental Research Centre, Ireland; S. J. GRANGER, Rothamsted Research, West Common, United Kingdom; A. F. HARRISON, Centre for Ecology & Hydrology, United Kingdom; C. HEUCK, Department of Soil Biogeochemistry, Bayreuth Center of Ecology and Environmental Research (BayCEER), University Bayreuth, Germany; E. Q. HOU, Guangdong Provincial Key Laboratory of Applied Botany, South China Botanical Garden, Chinese Academy of Sciences, China; P. J. JOHNES, School of Geographical Sciences & School of Chemistry, University of Bristol, United Kingdom; K. KAISER, Soil Science and Soil Protection, Martin Luther University Halle-Wittenberg, Germany; H. A. KJÆR, Centre for Ice and Climate, Niels Bohr Institute, University of Copenhagen, Denmark; E. KLUMPP, Evolutionary Biology Centre, EBC, Sweden; A. L. LAMB, NERC Isotope Geosciences Facility, British Geological Survey, United Kingdom; K. A. MACINTOSH, School of Biological Sciences and Institute for Global Food Security, The Queen’s University of Belfast, Medical Biology Centre, United Kingdom; E. B. MACKAY, Centre for Ecology & Hydrology, Library Avenue, Bailrigg, United Kingdom; J. MCGRATH, School of Biological Sciences and Institute for Global Food Security, The Queen’s University of Belfast, Medical Biology Centre, United Kingdom; C. MCINTYRE, School of Geographical Sciences & School of Chemistry, University of Bristol, United Kingdom; T. MCLAREN, D-USYS, ETH Zurich, Switzerland; E. MÉSZÁROS, D-USYS, ETH Zurich, Switzerland; A. MISSONG, Institute of Bio- and Geosciences, IBG-3: Agrosphere, Germany; M. MOOSHAMMER, Department of Microbiology and Ecosystem Science, University of Vienna, Austria; C. P. NEGRÓN, Universidad de La Frontera, Temuco, Chile; L. A. NELSON, University of Northern British Columbia, Canada; V. PFAHLER, Rothamsted Research, West Common, United Kingdom; P. POBLETE-GRANT, Universidad de La Frontera, Temuco, Chile; M. RANDALL, Brigham Young University, United States; A. SEGUEL, Universidad de La Frontera, Temuco, Chile; K. SETH, Lincoln University, New Zealand; A. C. SMITH, NERC Isotope Geosciences Facility, British Geological Survey, United Kingdom; M. M. SMITS, Centre for Environmental Sciences, Hasselt University Building D, Belgium; J. A. SOBARZO, Universidad de La Frontera, Temuco, Chile; M. SPOHN, Department of Soil Biogeochemistry, Bayreuth Center of Ecology and Environmental Research (BayCEER), University Bayreuth, Germany; K. TAWARAYA, Yamagata University, Japan; M. TIBBETT, Centre for Agri-environmental Research, School of Agriculture Policy and Development, University of Reading, United Kingdom; V. VORONEY, University of Guelph, Canada; H. WALLANDER, Department of Biology, Lund University, Sweden; L. WANG, Institute of Bio- and Geosciences, IBG-3: Agrosphere, Germany; J. WASAKI, Assessment of Microbial Environment, Graduate School of Biosphere Science, Hiroshima University, Japan; P. M. HAYGARTH, Lancaster Environment Centre, Lancaster University, United Kingdom. |
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Título : |
Organic phosphorus in the terrestrial environment: a perspective on the state of the art and future priorities. |
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Fecha de publicación : |
2018 |
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Fuente / Imprenta : |
Plant and Soil, 1 June 2018, Volume 427, Issue 1-2, Pages 191-208. |
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ISSN : |
0032-079X |
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DOI : |
10.1007/s11104-017-3391-x |
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Idioma : |
Inglés |
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Notas : |
Article history: Received: 28 April 2017 /Accepted: 17 August 2017 / Published online: 6 October 2017.
Update notice: Correction to: Organic phosphorus in the terrestrial environment: a perspective on the state of the art and future priorities (Plant and Soil, (2018), 427, 1-2, (191-208), 10.1007/s11104-017-3391-x) (2018) Plant and Soil, 427 (1-2), pp. 209-211.
Funding text: Acknowledgements This work was performed with the financial support of the Organic Phosphorus Utilisation in Soils (OPUS) project, funded by Biotechnology and Biological Sciences Research Council (BBSRC – BBSRC - BB/K018167/1) in the UK and the Rural & Environment Science & Analytical Services Division of the Scottish Government. Fraser and Tibbett acknowledge the support of BBSRC SARISA programme BB/L025671/2. We also acknowledge the contribution to the output of the OP2016 workshop of all the attendees of the meeting who chose not be named as an author on this paper. In particular, the authors would like to thank Barbara Cade-Menun and Ben Turner and acknowledge there contribution to drafts of this manuscript. |
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Contenido : |
ABSTRACT.
Background: The dynamics of phosphorus (P) in the environment is important for regulating nutrient cycles in natural and managed ecosystems and an integral part in assessing biological resilience against environmental change. Organic P (Po) compounds play key roles in biological and ecosystems function in the terrestrial environment being critical to cell function, growth and reproduction. Scope: We asked a group of experts to consider the global issues associated with Po in the terrestrial environment, methodological strengths and weaknesses, benefits to be gained from understanding the Po cycle, and to set priorities for Po research. Conclusions: We identified seven key opportunities for Po research including: the need for integrated, quality controlled and functionally based methodologies; assessment of stoichiometry with other elements in organic matter; understanding the dynamics of Po in natural and managed systems; the role of microorganisms in controlling Po cycles; the implications of nanoparticles in the environment and the need for better modelling and communication of the research. Each priority is discussed and a statement of intent for the Po research community is made that highlights there are key contributions to be made toward understanding biogeochemical cycles, dynamics and function of natural ecosystems and the management of agricultural systems.
© 2017, Springer International Publishing AG. |
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Palabras claves : |
Ecosystems services; Method development; Microbiome; Modelling; Organic phosphorus; Stoichiometry. |
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Asunto categoría : |
P01 Conservación de la naturaleza y recursos de La tierra |
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Marc : |
LEADER 05693naa a2201249 a 4500
001 1060354
005 2019-10-28
008 2018 bl uuuu u00u1 u #d
022 $a0032-079X
024 7 $a10.1007/s11104-017-3391-x$2DOI
100 1 $aGEORGE, T.S.
245 $aOrganic phosphorus in the terrestrial environment$ba perspective on the state of the art and future priorities.$h[electronic resource]
260 $c2018
500 $aArticle history: Received: 28 April 2017 /Accepted: 17 August 2017 / Published online: 6 October 2017. Update notice: Correction to: Organic phosphorus in the terrestrial environment: a perspective on the state of the art and future priorities (Plant and Soil, (2018), 427, 1-2, (191-208), 10.1007/s11104-017-3391-x) (2018) Plant and Soil, 427 (1-2), pp. 209-211. Funding text: Acknowledgements This work was performed with the financial support of the Organic Phosphorus Utilisation in Soils (OPUS) project, funded by Biotechnology and Biological Sciences Research Council (BBSRC – BBSRC - BB/K018167/1) in the UK and the Rural & Environment Science & Analytical Services Division of the Scottish Government. Fraser and Tibbett acknowledge the support of BBSRC SARISA programme BB/L025671/2. We also acknowledge the contribution to the output of the OP2016 workshop of all the attendees of the meeting who chose not be named as an author on this paper. In particular, the authors would like to thank Barbara Cade-Menun and Ben Turner and acknowledge there contribution to drafts of this manuscript.
520 $aABSTRACT. Background: The dynamics of phosphorus (P) in the environment is important for regulating nutrient cycles in natural and managed ecosystems and an integral part in assessing biological resilience against environmental change. Organic P (Po) compounds play key roles in biological and ecosystems function in the terrestrial environment being critical to cell function, growth and reproduction. Scope: We asked a group of experts to consider the global issues associated with Po in the terrestrial environment, methodological strengths and weaknesses, benefits to be gained from understanding the Po cycle, and to set priorities for Po research. Conclusions: We identified seven key opportunities for Po research including: the need for integrated, quality controlled and functionally based methodologies; assessment of stoichiometry with other elements in organic matter; understanding the dynamics of Po in natural and managed systems; the role of microorganisms in controlling Po cycles; the implications of nanoparticles in the environment and the need for better modelling and communication of the research. Each priority is discussed and a statement of intent for the Po research community is made that highlights there are key contributions to be made toward understanding biogeochemical cycles, dynamics and function of natural ecosystems and the management of agricultural systems. © 2017, Springer International Publishing AG.
653 $aEcosystems services
653 $aMethod development
653 $aMicrobiome
653 $aModelling
653 $aOrganic phosphorus
653 $aStoichiometry
700 1 $aGILES, C.D.
700 1 $aMENEZES-BLACKBURN, D.
700 1 $aCONDRON, L.M.
700 1 $aGAMA-RODRIGUES, A.C.
700 1 $aJAISI, D.
700 1 $aLANG, F.
700 1 $aNEAL, A.L.
700 1 $aSTUTTER, M.I.
700 1 $aALMEIDA, D.S.
700 1 $aBOL, R.
700 1 $aCABUGAO, K.G.
700 1 $aCELI, L.
700 1 $aCOTNER, J.B.
700 1 $aFENG, G.
700 1 $aGOLL, D.S.
700 1 $aHALLAMA, M.
700 1 $aKRUEGER, J.
700 1 $aPLASSARD, C.
700 1 $aROSLING, A.
700 1 $aDARCH, T.
700 1 $aFRASER, T.
700 1 $aGIESLER, R.
700 1 $aRICHARDSON, A.E.
700 1 $aTAMBURINI, F.
700 1 $aSHAND, C.A.
700 1 $aLUMSDON, D.G.
700 1 $aZHANG, H.
700 1 $aBLACKWEL, M.S.A.
700 1 $aWEARING, C.
700 1 $aMEZELI, M.M.
700 1 $aALMÅS, Å.R.
700 1 $aAUDETTE, Y.
700 1 $aBERTRAND, I.
700 1 $aBEYHAUT, E.
700 1 $aBOITT, G.
700 1 $aBRADSHAW, N.
700 1 $aBREARLEY, C.A.
700 1 $aBRUULSEMA, T.W.
700 1 $aCIAIS, P.
700 1 $aCOZZOLINO, V.
700 1 $aDURAN, P.C.
700 1 $aMORA, M.L.
700 1 $aDE MENEZES, A.B.
700 1 $aDODD, R.J.
700 1 $aDUNFIELD, K.
700 1 $aENGL, C.
700 1 $aFRAZÃO, J.J.
700 1 $aGARLAND, G.
700 1 $aGONZÁLEZ JIMÉNEZ, J.L.
700 1 $aGRACA, J.
700 1 $aGRANGER, S.J.
700 1 $aHARRISON, A.F.
700 1 $aHEUCK, C.
700 1 $aHOU, E.Q.
700 1 $aJOHNES, P.J.
700 1 $aKAISER, K.
700 1 $aKJÆR. H.A.
700 1 $aKLUMPP, E.
700 1 $aLAMB, A.L.
700 1 $aMACINTOSH, K.A.A
700 1 $aMACKAY, E.B.
700 1 $aMCGRATH, J.
700 1 $aMCINTYRE, C.
700 1 $aMCLAREN, T.
700 1 $aMÉSZÁROS, E.
700 1 $aMISSONG, A.
700 1 $aMOOSHAMMER, M.
700 1 $aNEGRÓN, C.P.
700 1 $aNELSON, L.A.
700 1 $aPFAHLER, V.
700 1 $aPOBLETE-GRANT, P.
700 1 $aRANDALL, M.
700 1 $aSEGUEL, A.
700 1 $aSETH, K.
700 1 $aSMITH, A.C.
700 1 $aSMITS, M.M.
700 1 $aSOBARZO, J.A.
700 1 $aSPOHN, M.
700 1 $aTAWARAYA, K.
700 1 $aTIBBETT, M.
700 1 $aVORONEY, V.
700 1 $aWALLANDER, H.
700 1 $aWANG, L.
700 1 $aWASAKI, J.
700 1 $aHAYGARTH, P.M.
773 $tPlant and Soil, 1 June 2018, Volume 427, Issue 1-2, Pages 191-208.
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INIA Las Brujas (LB) |
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Registro completo
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Biblioteca (s) : |
INIA Tacuarembó; INIA Treinta y Tres. |
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Fecha actual : |
18/11/2016 |
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Actualizado : |
11/10/2019 |
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Tipo de producción científica : |
Artículos en Revistas Indexadas Internacionales |
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Circulación / Nivel : |
Internacional - -- |
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Autor : |
MARTÍNEZ, C.P.; TORRES, E.A.; CHATEL, M.; MOSQUERA, G.; DUITAMA, J.; ISHITANI, M.; SELVARAJ, M.; DEDICOVA, B.; TOHME, J.; GRENIER, C.; LORIEUX, M.; CRUZ, M.; BERRÍO, L.; CORREDOR, E.; ZORRILLA DE SAN MARTÍN, G.; BRESEGHELLO, F.; PEIXOTO, O.; COLOMBARI FILHO, J.M.; CASTRO, A. PEREIRA DE; LOPES, S.I. GINDRI; BARBOSA, M.; FUNCK, G.R. DALTROZZO; BLANCO, P.H.; PÉREZ DE VIDA, F.; MOLINA, F.; ROSAS, J.E.; MARTÍNEZ, S.; BONNECARRERE, V.; CARRACELAS, G.; MARIN, A.; CORREA-VICTORIA, F.; CAMARGO, I.; BRUZZONE, C.B . |
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Afiliación : |
CESAR P. MARTÍNEZ, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; EDGAR A. TORRES, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; MARC CHATEL, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; GLORIA MOSQUERA, INTERNACIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; JORGE DUITAMA, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; MANABU ISHITANI, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; MICHAEL SILVARAJ, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; BEATA DEDICOVA, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; JOE TOHME, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; CÉCILE GRENIER, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; MATHIAS LORIEUX, INTERNATIONAL CENTER FOR TROPICAL AGRICULTURE (CIAT).; MARIBEL CRUZ, LATIN AMERICAN FUND FOR IRRIGATED RICE (FLAR).; LUIS BERRÍO, LATIN AMERICAN FUND FOR IRRIGATED RICE (FLAR).; EDGAR CORREDOR, LATIN AMERICAN FUND FOR IRRIGATED RICE (FLAR).; GONZALO ZORRILLA DE SAN MARTÍN, LATIN AMERICAN FUND FOR IRRIGATED RICE (FLAR).; FLAVIO BRESEGHELLO, BRAZILIAN ENTERPRISE FOR AGRICULTURAL RESEARCH (EMBRAPA RICE AND BEANS).; ORLANDO PEIXOTO, BRAZILIAN ENTERPRISE FOR AGRICULTURAL RESEARCH (EMBRAPA RICE AND BEANS).; JOSE MANOEL COLOMBARI FILHO, BRAZILIAN ENTERPRISE FOR AGRICULTURAL RESEARCH (EMBRAPA RICE AND BEANS).; ADRIANO PEREIRA DE CASTRO., BRAZILIAN ENTERPRISE FOR AGRICULTURAL RESEARCH (EMBRAPA RICE AND BEANS).; SERGIO IRACU GINDRI LOPES, RIO GRANDE DO SUL STATE RICE INSTITUTE (IRGA).; MARA BARBOSA, RIO GRANDE DO SUL STATE RICE INSTITUTE (IRGA).; GUSTAVO RODRIGO DALTROZZO FUNCK, RIO GRANDE DO SUL STATE RICE INSTITUTE (IRGA).; PEDRO HORACIO BLANCO BARRAL, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; FERNANDO BLAS PEREZ DE VIDA, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; FEDERICO MOLINA CASELLA, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; JUAN EDUARDO ROSAS CAISSIOLS, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; SEBASTIÁN MARTÍNEZ KOPP, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; MARIA VICTORIA BONNECARRERE MARTINEZ, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; JULIO GONZALO CARRACELAS GARRIDO, INIA (Instituto Nacional de Investigación Agropecuaria), Uruguay; ALFREDO MARIN, ARGENTINIAN INSTITUTE FOR AGRICULTURAL RESEARCH (INTA).; FERNANDO CORREA-VICTORIA, RICE TEC SOLUTION; ISMAEL CAMARGO, PANAMANIAN INSTITUTE FOR AGRICULTURAL RESEARCH (IDIAP).; CARLOS BERNARDO BRUZZONE, SEEDS EL POTRERO FARM. |
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Título : |
Rice breeding in Latin America. |
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Fecha de publicación : |
2014 |
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Fuente / Imprenta : |
Plant Breeding Reviews, 2014 v.38, p. 187-277., 2014 |
|
DOI : |
10.1002/9781118916865.ch05 |
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Idioma : |
Inglés |
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Contenido : |
Rice breeding has made important contributions to Latin America. More than 400 cultivars were released from 1975 to 2012, which helped to raise total production to >27 million tonnes obtained from 5.7 million hectares (average for 2010-2012). Rice production provides ~US$8.8 billion for thousands of farmers in Latin America and the Caribbean (LAC). The result of higher yields in the irrigated sector was to triple rice production in LAC while area did not grow, thus preserving more fragile environments. Several estimates on genetic gains for grain yield have been carried out in LAC. In temperate irrigated rice, the estimates are around 1.5-2.6% per year. In the tropical irrigated, it is ~1% and in the upland rice the estimate is ~1.4% per year.
Different breeding strategies, including pedigree, modified bulk, recurrent selection methods, anther culture, interspecific crosses, composite populations, quantitative trait loci (QTL) introgression, and recombinant inbred lines, accompanied by shuttle breeding schemes, direct seeding, and evaluation/selection in hot spots for main diseases are being used by CIAT and NARES in the region. In this process, methods for screening for diseases and other stresses were established. Networking has been a cornerstone for success and several networks such as INGER, FLAR, and HIAAL were created.
Looking forward, as farmers' yields are approaching the genetic yield potential exhibited by current cultivars, as a result of improved agronomic management, a new breakthrough is needed in terms of more productive cultivars. To achieve this goal, a strategy is needed that includes strong pipelines focused on specific environments and markets; better product profiling; integration between discovery, development, and delivery; and new breeding strategies using cutting-edge technologies and new breeding methods to accelerate genetic gains. MenosRice breeding has made important contributions to Latin America. More than 400 cultivars were released from 1975 to 2012, which helped to raise total production to >27 million tonnes obtained from 5.7 million hectares (average for 2010-2012). Rice production provides ~US$8.8 billion for thousands of farmers in Latin America and the Caribbean (LAC). The result of higher yields in the irrigated sector was to triple rice production in LAC while area did not grow, thus preserving more fragile environments. Several estimates on genetic gains for grain yield have been carried out in LAC. In temperate irrigated rice, the estimates are around 1.5-2.6% per year. In the tropical irrigated, it is ~1% and in the upland rice the estimate is ~1.4% per year.
Different breeding strategies, including pedigree, modified bulk, recurrent selection methods, anther culture, interspecific crosses, composite populations, quantitative trait loci (QTL) introgression, and recombinant inbred lines, accompanied by shuttle breeding schemes, direct seeding, and evaluation/selection in hot spots for main diseases are being used by CIAT and NARES in the region. In this process, methods for screening for diseases and other stresses were established. Networking has been a cornerstone for success and several networks such as INGER, FLAR, and HIAAL were created.
Looking forward, as farmers' yields are approaching the genetic yield potential exhibited by current cultivars, as a result of improved agronomic man... Presentar Todo |
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Palabras claves : |
RICE. |
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Thesagro : |
ARROZ; FITOMEJORAMIENTO; LATINOAMERICA. |
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Asunto categoría : |
F30 Genética vegetal y fitomejoramiento |
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Marc : |
LEADER 03360naa a2200565 a 4500
001 1056100
005 2019-10-11
008 2014 bl uuuu u00u1 u #d
024 7 $a10.1002/9781118916865.ch05$2DOI
100 1 $aMARTÍNEZ, C.P.
245 $aRice breeding in Latin America.$h[electronic resource]
260 $c2014
520 $aRice breeding has made important contributions to Latin America. More than 400 cultivars were released from 1975 to 2012, which helped to raise total production to >27 million tonnes obtained from 5.7 million hectares (average for 2010-2012). Rice production provides ~US$8.8 billion for thousands of farmers in Latin America and the Caribbean (LAC). The result of higher yields in the irrigated sector was to triple rice production in LAC while area did not grow, thus preserving more fragile environments. Several estimates on genetic gains for grain yield have been carried out in LAC. In temperate irrigated rice, the estimates are around 1.5-2.6% per year. In the tropical irrigated, it is ~1% and in the upland rice the estimate is ~1.4% per year. Different breeding strategies, including pedigree, modified bulk, recurrent selection methods, anther culture, interspecific crosses, composite populations, quantitative trait loci (QTL) introgression, and recombinant inbred lines, accompanied by shuttle breeding schemes, direct seeding, and evaluation/selection in hot spots for main diseases are being used by CIAT and NARES in the region. In this process, methods for screening for diseases and other stresses were established. Networking has been a cornerstone for success and several networks such as INGER, FLAR, and HIAAL were created. Looking forward, as farmers' yields are approaching the genetic yield potential exhibited by current cultivars, as a result of improved agronomic management, a new breakthrough is needed in terms of more productive cultivars. To achieve this goal, a strategy is needed that includes strong pipelines focused on specific environments and markets; better product profiling; integration between discovery, development, and delivery; and new breeding strategies using cutting-edge technologies and new breeding methods to accelerate genetic gains.
650 $aARROZ
650 $aFITOMEJORAMIENTO
650 $aLATINOAMERICA
653 $aRICE
700 1 $aTORRES, E.A.
700 1 $aCHATEL, M.
700 1 $aMOSQUERA, G.
700 1 $aDUITAMA, J.
700 1 $aISHITANI, M.
700 1 $aSELVARAJ, M.
700 1 $aDEDICOVA, B.
700 1 $aTOHME, J.
700 1 $aGRENIER, C.
700 1 $aLORIEUX, M.
700 1 $aCRUZ, M.
700 1 $aBERRÍO, L.
700 1 $aCORREDOR, E.
700 1 $aZORRILLA DE SAN MARTÍN, G.
700 1 $aBRESEGHELLO, F.
700 1 $aPEIXOTO, O.
700 1 $aCOLOMBARI FILHO, J.M.
700 1 $aCASTRO, A. PEREIRA DE
700 1 $aLOPES, S.I. GINDRI
700 1 $aBARBOSA, M.
700 1 $aFUNCK, G.R. DALTROZZO
700 1 $aBLANCO, P.H.
700 1 $aPÉREZ DE VIDA, F.
700 1 $aMOLINA, F.
700 1 $aROSAS, J.E.
700 1 $aMARTÍNEZ, S.
700 1 $aBONNECARRERE, V.
700 1 $aCARRACELAS, G.
700 1 $aMARIN, A.
700 1 $aCORREA-VICTORIA, F.
700 1 $aCAMARGO, I.
700 1 $aBRUZZONE, C.B .
773 $tPlant Breeding Reviews, 2014$gv.38, p. 187-277., 2014
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