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2. | | GRISI, M. C. M.; BLAIR, M. W.; GEPTS, P.; BRONDANI, C.; PEREIRA, P. A. A.; BRONDANI, R. P. V. Genetic mapping of a new set of microsatellite markers in a reference common bean (Phaseolus vulgaris) population BAT93 x Jalo EEP558. Genetics and Molecular Research, v. 6, n. 3, p. 691-706, Sept. 2007. Biblioteca(s): Embrapa Arroz e Feijão. |
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3. | | DWIVEDI, S. L.; SAHRAWAT, K. L.; UPADHYAYA, H. D.; MENGONI, A.; GALARDINI, M.; BAZZICALUPO, M.; BIONDI, E. G.; HUNGRIA, M.; KASCHUK, G.; BLAIR, M. W.; ORTIZ, R. Advances in host plant and rhizobium genomics to enhance symbiotic nitrogen fixation in grain legumes. Advances in Agronomy, v. 129, p. 1-116, 2014. Biblioteca(s): Embrapa Soja. |
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4. | | BASSI, D.; BRIÑEZ, B.; ROSA, J. S.; OBLESSUC, P. R.; ALMEIDA, C. P. de; NUCCI, S. M.; SILVA, L. C. D. da; CHIORATO, A. F.; VIANELLO, R. P.; CAMARGO, L. E. A.; BLAIR, M. W.; BENCHIMOL-REIS, L. L. Linkage and mapping of quantitative trait loci associated with angular leaf spot and powdery mildew resistance in common beans. Genetics and Molecular Biology, Ribeirão Preto, v. 40, n. 1, p. 109-122, jan./mar. 2017. Biblioteca(s): Embrapa Arroz e Feijão. |
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5. | | GEPTS, P.; ARAGÃO, F. J. L.; BARROS, E. de; BLAIR, M. W.; BRONDANI, R.; BROWGHTON, W.; GALASSO, I.; HERNÁNDEZ, G.; KAMI, J.; LARIGUET, P.; MCCLEAN, P.; MELOTTO, M.; MIKLAS, P.; PAULS, P.; PEDROSA HARAND, A.; PORCH, T.; SÁNCHEZ, F.; SPARVOLI, F.; YU, K. Genomics of Phaseolus beans, a major source of dietary protein and micronutrients in the tropics. In: MOORE, P. H.; MING, R. Ed.). Genomics of tropical crop plants. New York: Springer Sciences, 2008. )Plant genetics and genomics: crops and models, 1). p. 113-143. Biblioteca(s): Embrapa Arroz e Feijão; Embrapa Recursos Genéticos e Biotecnologia. |
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6. | | BRIÑEZ, B.; PERSEGUINI, J. M. K. C.; ROSA, J. S.; BASSI, D.; GONÇALVES, J. G. R.; ALMEIDA, C.; PAULINO, J. F. de C.; BLAIR, M. W.; CHIORATTO, A. F.; CARBONELL, S. A. M.; VALDISSER, P. A. M. R.; VIANELLO, R. P.; BENCHIMOL-REIS, L. L. Mapping QTLs for drought tolerance in a SEA 5 x AND 277 common bean cross with SSRs and SNP markers. Genetics and Molecular Biology, Ribeirão Preto, v. 40, n. 4, p. 803-813, Oct./Dec. 2017. Biblioteca(s): Embrapa Arroz e Feijão. |
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7. | | BLAIR, M. W.; BUENDIA, H. F.; DIAZ, L.; DIAZ, J. M.; GIRALDO, M. C.; MORENO, N.; GONZALEZ, L.; DUQUE, M. C.; DEBOUCK, D.; ZHANG, X.; WANG, S.; PELOSO, M. J.; BRONDANI, R.; BORBA, T. O.; KRESOVICH, S.; MITCHELL, S. E.; ASFAW, A.; KIMANI, P.; CHIRWA, R.; AVILA, T.; ROJAS, X.; DAVILA, A.; GIL, H.; PÉREZ, N. M.; ACOSTA, J.; LORIGADOS, S. World-wide common bean (Phaseolus vulgaris L.) diversity and race structure. Cali: CIAT, 2008. 1 p. Poster. Biblioteca(s): Embrapa Arroz e Feijão. |
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Registro Completo
Biblioteca(s): |
Embrapa Soja. |
Data corrente: |
23/07/2015 |
Data da última atualização: |
03/11/2017 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Circulação/Nível: |
A - 1 |
Autoria: |
DWIVEDI, S. L.; SAHRAWAT, K. L.; UPADHYAYA, H. D.; MENGONI, A.; GALARDINI, M.; BAZZICALUPO, M.; BIONDI, E. G.; HUNGRIA, M.; KASCHUK, G.; BLAIR, M. W.; ORTIZ, R. |
Afiliação: |
SANGAM L. DWIVEDI, ICRISAT; KANWAR L. SAHRAWAT, ICRISAT; HARI D. UPADHYAYA, ICRISAT; ALESSIO MENGONI, UNIVERSITY OF FLORENCE; MARCO GALARDINI, UNIVERSITY OF FLORENCE; MARCO BAZZICALUPO, UNIVERSITY OF FLORENCE; EMANUELE G. BIONDI, IRI; MARIANGELA HUNGRIA DA CUNHA, CNPSO; GLACIELA KASCHUK, UNIPAR; MATTHEW W. BLAIR, Agricultural Biotechnology Center; RODOMIRO ORTIZ, Swedish University of Agricultural Sciences. |
Título: |
Advances in host plant and rhizobium genomics to enhance symbiotic nitrogen fixation in grain legumes. |
Ano de publicação: |
2014 |
Fonte/Imprenta: |
Advances in Agronomy, v. 129, p. 1-116, 2014. |
ISSN: |
0065-2113 |
DOI: |
10.1016/bs.agron.2014.09.001 |
Idioma: |
Português |
Conteúdo: |
Legumes form symbiotic relationship with root-nodule, rhizobia. The nitrogen (N2) ?xed by legumes is a renewable source and of great importance to agriculture. Symbi- otic nitrogen ?xation (SNF) is constrained by multiple stresses and alleviating them would improve SNF contribution to agroecosystems. Genetic differences in adaptation tolerance to various stresses are known in both host plant and rhizobium. The discovery and use of promiscuous germplasm in soybean led to the release of high-yielding cul- tivars in Africa. High N2-?xing soybean cultivars are commercially grown in Australia and some countries in Africa and South America and those of pea in Russia. SNF is a com- plex trait, governed by multigenes with varying effects. Few major quantitative trait loci (QTL) and candidate genes underlying QTL are reported in grain and model legumes. Nodulating genes in model legumes are cloned and orthologs determined in grain le- gumes. Single nucleotide polymorphism (SNP) markers from nodulation genes are available in common bean and soybean. Genomes of chickpea, pigeonpea, and soy- bean; and genomes of several rhizobium species are decoded. Expression studies revealed few genes associated with SNF in model and grain legumes. Advances in host plant and rhizobium genomics are helping identify DNA markers to aid breeding of legume cultivars with high symbiotic ef?ciency. A paradigm shift is needed by breeding programs to simultaneously improve host plant and rhizobium to harness the strength of positive symbiotic interactions in cultivar development. Computation models based on metabolic reconstruction pathways are providing greater insights to explore genotype?phenotype relationships in SNF. Models to simulate the response of N2 ?xation to a range of environmental variables and crop growth are assisting re- searchers to quantify SNF for ef?cient and sustainable agricultural production systems. Such knowledge helps identifying bottlenecks in speci?c legume?rhizobia systems that could be overcome by legume breeding to enhance SNF. This review discusses the recent developments to improve SNF and productivity of grain legumes. MenosLegumes form symbiotic relationship with root-nodule, rhizobia. The nitrogen (N2) ?xed by legumes is a renewable source and of great importance to agriculture. Symbi- otic nitrogen ?xation (SNF) is constrained by multiple stresses and alleviating them would improve SNF contribution to agroecosystems. Genetic differences in adaptation tolerance to various stresses are known in both host plant and rhizobium. The discovery and use of promiscuous germplasm in soybean led to the release of high-yielding cul- tivars in Africa. High N2-?xing soybean cultivars are commercially grown in Australia and some countries in Africa and South America and those of pea in Russia. SNF is a com- plex trait, governed by multigenes with varying effects. Few major quantitative trait loci (QTL) and candidate genes underlying QTL are reported in grain and model legumes. Nodulating genes in model legumes are cloned and orthologs determined in grain le- gumes. Single nucleotide polymorphism (SNP) markers from nodulation genes are available in common bean and soybean. Genomes of chickpea, pigeonpea, and soy- bean; and genomes of several rhizobium species are decoded. Expression studies revealed few genes associated with SNF in model and grain legumes. Advances in host plant and rhizobium genomics are helping identify DNA markers to aid breeding of legume cultivars with high symbiotic ef?ciency. A paradigm shift is needed by breeding programs to simultaneously improve host plant and rhizobium to harness ... Mostrar Tudo |
Thesaurus NAL: |
nitrogen fixation. |
Categoria do assunto: |
-- |
Marc: |
LEADER 02957naa a2200277 a 4500 001 2020360 005 2017-11-03 008 2014 bl uuuu u00u1 u #d 022 $a0065-2113 024 7 $a10.1016/bs.agron.2014.09.001$2DOI 100 1 $aDWIVEDI, S. L. 245 $aAdvances in host plant and rhizobium genomics to enhance symbiotic nitrogen fixation in grain legumes.$h[electronic resource] 260 $c2014 520 $aLegumes form symbiotic relationship with root-nodule, rhizobia. The nitrogen (N2) ?xed by legumes is a renewable source and of great importance to agriculture. Symbi- otic nitrogen ?xation (SNF) is constrained by multiple stresses and alleviating them would improve SNF contribution to agroecosystems. Genetic differences in adaptation tolerance to various stresses are known in both host plant and rhizobium. The discovery and use of promiscuous germplasm in soybean led to the release of high-yielding cul- tivars in Africa. High N2-?xing soybean cultivars are commercially grown in Australia and some countries in Africa and South America and those of pea in Russia. SNF is a com- plex trait, governed by multigenes with varying effects. Few major quantitative trait loci (QTL) and candidate genes underlying QTL are reported in grain and model legumes. Nodulating genes in model legumes are cloned and orthologs determined in grain le- gumes. Single nucleotide polymorphism (SNP) markers from nodulation genes are available in common bean and soybean. Genomes of chickpea, pigeonpea, and soy- bean; and genomes of several rhizobium species are decoded. Expression studies revealed few genes associated with SNF in model and grain legumes. Advances in host plant and rhizobium genomics are helping identify DNA markers to aid breeding of legume cultivars with high symbiotic ef?ciency. A paradigm shift is needed by breeding programs to simultaneously improve host plant and rhizobium to harness the strength of positive symbiotic interactions in cultivar development. Computation models based on metabolic reconstruction pathways are providing greater insights to explore genotype?phenotype relationships in SNF. Models to simulate the response of N2 ?xation to a range of environmental variables and crop growth are assisting re- searchers to quantify SNF for ef?cient and sustainable agricultural production systems. Such knowledge helps identifying bottlenecks in speci?c legume?rhizobia systems that could be overcome by legume breeding to enhance SNF. This review discusses the recent developments to improve SNF and productivity of grain legumes. 650 $anitrogen fixation 700 1 $aSAHRAWAT, K. L. 700 1 $aUPADHYAYA, H. D. 700 1 $aMENGONI, A. 700 1 $aGALARDINI, M. 700 1 $aBAZZICALUPO, M. 700 1 $aBIONDI, E. G. 700 1 $aHUNGRIA, M. 700 1 $aKASCHUK, G. 700 1 $aBLAIR, M. W. 700 1 $aORTIZ, R. 773 $tAdvances in Agronomy$gv. 129, p. 1-116, 2014.
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