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Registro Completo |
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Biblioteca(s): |
Embrapa Arroz e Feijão. |
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Data corrente: |
29/05/2022 |
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Data da última atualização: |
12/04/2024 |
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Tipo da produção científica: |
Capítulo em Livro Técnico-Científico |
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Autoria: |
CROSSA, J.; MONTESINOS-LÓPEZ, O. A.; PÉREZ-RODRÍGUEZ, P.; COSTA-NETO, G.; FRITSCHE-NETO, R.; ORTIZ, R.; MARTINI, J. W. R.; LILLEMO, M.; MONTESINOS-LÓPEZ, A.; JARQUIN, D.; BRESEGHELLO, F.; CUEVAS, J.; RINCENT, R. |
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Afiliação: |
JOSE CROSSA, CIMMYT; OSVAL ANTONIO MONTESINOS-LOPEZ, UNIVERSIDAD DE COLIMA, México; PAULINO PEREZ-RODRIGUEZ, COLEGIO DE POSTGRADUADOS, Montecillos-Mexico; GERMANO COSTA-NETO, ESALQ; ROBERTO FRITSCHE-NETO, ESALQ; RODOMIRO ORTIZ, SWEDISH UNIVERSITY OF AGRICULTURAL SCIENCES, Alnarp-Sweden; JOHANNES W. R. MARTINI, CIMMYT; MORTEN LILLEMO, NORWEGIAN UNIVERSITY OF LIFE SCIENCES, Norway; ABELARDO MONTESINOS-LOPEZ, CENTRO DE INVESTIGACIÓN EN MATEMÁTICAS, Guanajuato-Mexico; DIEGO JARQUIN, UNIVERSITY OF NEBRASKA, Lincoln-NE; FLAVIO BRESEGHELLO, CNPAF; JAIME CUEVAS, UNIVERSIDAD DE QUINTANA ROO, Quintana Roo-Mexico; RENAUD RINCENT, INRAE, Clermont-Ferrand-France. |
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Título: |
Genome and environment based prediction models and methods of complex traits incorporating genotype × environment interaction. |
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Ano de publicação: |
2022 |
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Fonte/Imprenta: |
In: AHMADI, N.; BARTHOLOME, J. (ed.). Genomic prediction of complex traits: methods and protocols. New York: Humana Press, 2022. |
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Páginas: |
p. 245-283. |
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Série: |
(Methods in Molecular Biology). |
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ISBN: |
978-1-0716-2205-6 |
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DOI: |
https://doi.org/10.1007/978-1-0716-2205-6_9 |
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Idioma: |
Inglês |
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Conteúdo: |
Genomic-enabled prediction models are of paramount importance for the successful implementation of genomic selection (GS) based on breeding values. As opposed to animal breeding, plant breeding includes extensive multienvironment and multiyear field trial data. Hence, genomic-enabled prediction models should include genotype × environment (G × E) interaction, which most of the time increases the prediction performance when the response of lines are different from environment to environment. In this chapter, we describe a historical timeline since 2012 related to advances of the GS models that take into account G × E interaction. We describe theoretical and practical aspects of those GS models, including the gains in prediction performance when including G × E structures for both complex continuous and categorical scale traits. Then, we detailed and explained the main G × E genomic prediction models for complex traits measured in continuous and noncontinuous (categorical) scale. Related to G × E interaction models this review also examine the analyses of the information generated with high-throughput phenotype data (phenomic) and the joint analyses of multitrait and multienvironment field trial data that is also employed in the general assessment of multitrait G × E interaction. The inclusion of nongenomic data in increasing the accuracy and biological reliability of the G × E approach is also outlined. We show the recent advances in large-scale envirotyping (enviromics), and how the use of mechanistic computational modeling can derive the crop growth and development aspects useful for predicting phenotypes and explaining G × E. MenosGenomic-enabled prediction models are of paramount importance for the successful implementation of genomic selection (GS) based on breeding values. As opposed to animal breeding, plant breeding includes extensive multienvironment and multiyear field trial data. Hence, genomic-enabled prediction models should include genotype × environment (G × E) interaction, which most of the time increases the prediction performance when the response of lines are different from environment to environment. In this chapter, we describe a historical timeline since 2012 related to advances of the GS models that take into account G × E interaction. We describe theoretical and practical aspects of those GS models, including the gains in prediction performance when including G × E structures for both complex continuous and categorical scale traits. Then, we detailed and explained the main G × E genomic prediction models for complex traits measured in continuous and noncontinuous (categorical) scale. Related to G × E interaction models this review also examine the analyses of the information generated with high-throughput phenotype data (phenomic) and the joint analyses of multitrait and multienvironment field trial data that is also employed in the general assessment of multitrait G × E interaction. The inclusion of nongenomic data in increasing the accuracy and biological reliability of the G × E approach is also outlined. We show the recent advances in large-scale envirotyping (enviromics), and... Mostrar Tudo |
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Palavras-Chave: |
Genome-enabled prediction; Genomic selection; Models with G x E interaction. |
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Thesagro: |
Genótipo; Interação Genética; Melhoramento Genético Vegetal. |
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Thesaurus Nal: |
Genome; Genomics; Genotype-environment interaction; Plant breeding. |
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Categoria do assunto: |
G Melhoramento Genético |
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URL: |
https://ainfo.cnptia.embrapa.br/digital/bitstream/doc/1143533/1/cap9-2022.pdf
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Marc: |
LEADER 03084naa a2200433 a 4500
001 2143533
005 2024-04-12
008 2022 bl uuuu u00u1 u #d
020 $a978-1-0716-2205-6
024 7 $ahttps://doi.org/10.1007/978-1-0716-2205-6_9$2DOI
100 1 $aCROSSA, J.
245 $aGenome and environment based prediction models and methods of complex traits incorporating genotype × environment interaction.$h[electronic resource]
260 $c2022
300 $ap. 245-283.
490 $a(Methods in Molecular Biology).
520 $aGenomic-enabled prediction models are of paramount importance for the successful implementation of genomic selection (GS) based on breeding values. As opposed to animal breeding, plant breeding includes extensive multienvironment and multiyear field trial data. Hence, genomic-enabled prediction models should include genotype × environment (G × E) interaction, which most of the time increases the prediction performance when the response of lines are different from environment to environment. In this chapter, we describe a historical timeline since 2012 related to advances of the GS models that take into account G × E interaction. We describe theoretical and practical aspects of those GS models, including the gains in prediction performance when including G × E structures for both complex continuous and categorical scale traits. Then, we detailed and explained the main G × E genomic prediction models for complex traits measured in continuous and noncontinuous (categorical) scale. Related to G × E interaction models this review also examine the analyses of the information generated with high-throughput phenotype data (phenomic) and the joint analyses of multitrait and multienvironment field trial data that is also employed in the general assessment of multitrait G × E interaction. The inclusion of nongenomic data in increasing the accuracy and biological reliability of the G × E approach is also outlined. We show the recent advances in large-scale envirotyping (enviromics), and how the use of mechanistic computational modeling can derive the crop growth and development aspects useful for predicting phenotypes and explaining G × E.
650 $aGenome
650 $aGenomics
650 $aGenotype-environment interaction
650 $aPlant breeding
650 $aGenótipo
650 $aInteração Genética
650 $aMelhoramento Genético Vegetal
653 $aGenome-enabled prediction
653 $aGenomic selection
653 $aModels with G x E interaction
700 1 $aMONTESINOS-LÓPEZ, O. A.
700 1 $aPÉREZ-RODRÍGUEZ, P.
700 1 $aCOSTA-NETO, G.
700 1 $aFRITSCHE-NETO, R.
700 1 $aORTIZ, R.
700 1 $aMARTINI, J. W. R.
700 1 $aLILLEMO, M.
700 1 $aMONTESINOS-LÓPEZ, A.
700 1 $aJARQUIN, D.
700 1 $aBRESEGHELLO, F.
700 1 $aCUEVAS, J.
700 1 $aRINCENT, R.
773 $tIn: AHMADI, N.; BARTHOLOME, J. (ed.). Genomic prediction of complex traits: methods and protocols. New York: Humana Press, 2022.
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Registro original: |
Embrapa Arroz e Feijão (CNPAF) |
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Registro Completo
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Biblioteca(s): |
Embrapa Cerrados. |
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Data corrente: |
25/03/1992 |
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Data da última atualização: |
13/03/2014 |
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Autoria: |
AZEVEDO, L. G. de. |
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Título: |
Zoneamento do estado de Goias para o planejamento da pesquisa agropecuaria: 1a. aproximacao. |
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Ano de publicação: |
1978 |
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Fonte/Imprenta: |
Planaltina: EMBRAPA-CPAC, 1978. |
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Páginas: |
17p. |
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Série: |
(EMBRAPA-CPAC. Comunicado Tecnico, 5). |
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Idioma: |
Português |
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Conteúdo: |
Material e métodos; Resultados. |
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Palavras-Chave: |
Brasil; Goiás; Pesquisa Agropecuária; Zoneamento agropecuario. |
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Thesagro: |
Administração; Cerrado; Zoneamento Agrícola; Zoneamento Ecológico. |
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Categoria do assunto: |
-- |
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URL: |
https://ainfo.cnptia.embrapa.br/digital/bitstream/item/99106/1/comtec-05.pdf
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Marc: |
LEADER 00693nam a2200229 a 4500
001 1546914
005 2014-03-13
008 1978 bl uuuu u0uu1 u #d
100 1 $aAZEVEDO, L. G. de
245 $aZoneamento do estado de Goias para o planejamento da pesquisa agropecuaria$b1a. aproximacao.
260 $aPlanaltina: EMBRAPA-CPAC$c1978
300 $a17p.
490 $a(EMBRAPA-CPAC. Comunicado Tecnico, 5).
520 $aMaterial e métodos; Resultados.
650 $aAdministração
650 $aCerrado
650 $aZoneamento Agrícola
650 $aZoneamento Ecológico
653 $aBrasil
653 $aGoiás
653 $aPesquisa Agropecuária
653 $aZoneamento agropecuario
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Registro original: |
Embrapa Cerrados (CPAC) |
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ID |
Origem |
Tipo/Formato |
Classificação |
Cutter |
Registro |
Volume |
Status |
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Biblioteca(s): |
Catálogo Coletivo de Periódicos Embrapa; Embrapa Amazônia Oriental. |
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Identificador: |
1266 |
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Data corrente: |
09/05/2002 |
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Data da última atualização: |
20/10/2015 |
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Código do título: |
4700007 |
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ISSN: |
0373-7896 |
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Código CCN: |
098511-2 |
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Título e Subtítulo: |
BERICHTE DES GEOBOTANISCHEN INSTITUTES DER EIBGENOESSISCHEN HOCHSCHULE STIFTUNG RUEBEL |
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Título anterior: |
BERICHT UBER DAS GEOBOTANISCHE FORCHUNGSINSTITUL RUBEL IN ZURICH |
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Entidade: |
Institut der Eide Techn. Hochschule |
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Local de publicação: |
Zurich, Suica |
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Periodicidade: |
irregular |
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Inicio de publicação: |
1960 |
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Coleções da unidade: |
Embrapa Amazônia Oriental
1960 31; 1961 32; 1962 33; 1963 34; 1965 36; 1967 37; 1968 38; 1969 39; 1970 40; 1972 41
Classificação: 581.05B31 |
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