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Registros recuperados : 71 | |
61. | | GUIMARAES, C. T.; MAGALHAES, J. V. D.; JARDIM, S. N.; ALMEIDA, R. V.; MARON, L. G.; PAIVA, E.; ALVES, V. M. C.; VIANA, J. M. S.; HOEKENGA, O.; PARENTONI, S. N.; KOCHIAN, L. V. Validation of aluminum tolerance QTL in maize. In: CONGRESSO BRASILEIRO DE GENÉTICA, 55., 2009, Águas de Lindóia, SP. Resumos... Ribeirão Preto: Sociedade Brasileira de Genética, 2009. p. 155. Biblioteca(s): Embrapa Milho e Sorgo. |
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62. | | MARON, L. G.; GUIMARAES, C. T.; KIRST, M.; ALBERT, P. S.; BIRCHLER, J. A.; BRADBURY, P. J.; BUCKLER, E. S.; COLUCCIO, A. E.; DANILOVA, T. V.; KUDMA, D.; MAGALHAES, J. V.; PIÑEROS, M. A.; SCHATZ, M. C.; WING, R. A.; KOCHIAN, L. V. Aluminum tolerance in maize is associated with higher MATE 1 gene copy number. Proceedings of the National Academy of Sciences of the United States of America, Washington,v. 110, n. 13, p. 5241-5246, Mar. 2013. Biblioteca(s): Embrapa Milho e Sorgo. |
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63. | | HUFNAGEL, B.; KOCHIAN, L.; AZEVEDO, G. C.; GUIMARAES, C. T.; SOUSA, S. M.; SCHAFFERT, R. E.; ASSIS, L.; NEGRI, B.; LEISER, W.; WEILTZIEN, E.; RATTUNDE, F.; VIANA, J. H.; GARCIA, A. A. F.; GAZAFFI, R.; WISSUWA, M.; HEUER, S.; MAGALHAES, J. V. Improving phosphorus efficiency in sorghum by the identification and validation of sorghum. In: CONFERENCE INTERNATIONAL PLANT & ANIMAL GENOME, 22., 2014, San Diego, CA. [Abstracts]. San Diego: [s.n], 2014. Biblioteca(s): Embrapa Milho e Sorgo. |
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64. | | KOCHIAN, L. V.; MAGALHAES, J.; GUIMARÃES, C.; ALVES, V.; CARNEIRO, N.; CARNEIRO, A.; SCHAFFERT, R.; BRAMMER, S.; CONSOLI, L.; SILVA JUNIOR, J. P. da; MINELLA, E.; CAIERÃO, E.; NASCIMENTO JUNIOR, A.; BRESEGHELLO, F.; NEVES, P.; GUDU, S.; MARON, L.; HOEKENGA, O.; LIU, J.; BUCKLER, E. Isolation and characterisation of aluminum tolerance genes in the cereals: an integrated functional genomic, molecular genetic and physiological analysis. In: GENERATION CHALLENGE PROGRAMME CULTIVATING PLANT DIVERSITY FOR THE RESOURCE-POOR, 2008, Mexico. Project abstracts... Mexico: Generation Challenge programme, 2008. p. 23-25. Biblioteca(s): Embrapa Arroz e Feijão. |
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65. | | KOCHIAN, L. V.; MAGALHAES, J.; GUIMARAES, C.; ALVES, V.; CARNEIRO, N.; CARNEIRO, A.; SCHAFFERT, R.; BRAMMER, S.; CONSOLI, L.; SILVA JUNIOR, J. P. da; MINELLA, E.; CAIERAO, E.; NASCIMENTO JUNIOR, A. do; BRESEGHELLO, F.; NEVES, P.; GUDU, S.; MARON, L.; HOEKENGA, O.; LIU, J.; BUCKLER, E. Isolation and characterisation of aluminum tolerance genes in the cereals: an integrated functional genomic, molecular genetic and physiological analysis. In: GENERATION CHALLENGE PROGRAMME CULTIVATING PLANT DIVERSITY FOR THE RESOURCE-POOR, 2008, Mexico. Project abstracts... Mexico: Generation Challenge programme, 2008. p. 23-25. Biblioteca(s): Embrapa Trigo. |
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66. | | HUFNAGEL, B.; SOUSA, S. M. de; ASSIS, L.; GUIMARAES, C. T.; LEISER, W.; AZEVEDO, G. C.; NEGRI, B.; LARSON, B. G.; SHAFF, J. E.; PASTINA, M. M.; BARROS, B. A.; WELTZIEN, E.; RATTUNDE, H. F. W.; VIANA, J. H.; CLARK, R. T.; FALCÃO, A.; GAZAFFI, R.; GARCIA, A. A. F.; SCHAFFERT, R. E.; KOCHIAN, L. V.; MAGALHAES, J. V. Duplicate and conquer: multiple homologs of PHOSPHORUS-STARVATION TOLERANCE1 enhance phosphorus acquisition and sorghum performance on low-phosphorus soils. Plant Physiology, Bethesda, v. 166, p. 659-677, Oct. 2014. Biblioteca(s): Embrapa Milho e Sorgo. |
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67. | | BERNARDINO, K. C.; PASTINA, M. M.; MENEZES, C. B. de; SOUSA, S. M. de; MACIEL, L. S.; CARVALHO JÚNIOR, G.; GUIMARÃES, C. T.; BARROS, B. de A.; SILVA, L. da C. e; CARNEIRO, P. C. S.; SCHAFFERT, R. E.; KOCHIAN, L. V.; MAGALHAES, J. V. de. The genetic architecture of phosphorus efficiency in sorghum involves pleiotropic QTL for root morphology and grain yield under low phosphorus availability in the soil. BMC Plant Biology, v. 19, n. 87, p. 1-15, 2019. Biblioteca(s): Embrapa Milho e Sorgo. |
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68. | | GUIMARAES, C. T.; SIMOES, C. C.; PASTINA, M. M.; MARON, L. G.; MAGALHAES, J. V.; VASCONCELLOS, R. C. C.; GUIMARAES, L. J. M.; LANA, U. G. de P.; TINOCO, C. F. S.; NODA, R. W.; BELICUAS, S. N. J.; KOCHIAN, L. V.; ALVES, V. M. C.; PARENTONI, S. N. Genetic dissection of Al tolerance QTLs in the maize genome by high density SNP scan. BMC Genomics, v. 15, n. 153, p. 1-14, 2014. Biblioteca(s): Embrapa Milho e Sorgo. |
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69. | | MAGALHAES, J. V. de; LIU, J.; GUIMARAES, C. T.; LANA, U. G. de P.; ALVES, V. M. C.; WANG, Y-H.; SCHAFFERT, R. E.; HOEKENGA, O. A.; PINEROS, M. A.; SHAFF, J. E.; KLEIN, P. E.; CARNEIRO, N. P.; COELHO, C. M.; TRICK, H. N.; KOCHIAN, L. V. A gene in the multidrug and toxic compound extrusion (MATE) family confers aluminum tolerance in sorghum. Nature Genetics, New York, v. 39, n. 9, p. 1156-1161, 2007. Biblioteca(s): Embrapa Milho e Sorgo. |
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70. | | MELO, J. O.; MARTINS, L. G. C.; BARROS, B. de A.; PIMENTA, M. R.; LANA, U. G. de P.; DUARTE, C. E. M.; PASTINA, M. M.; GUIMARÃES, C. T.; SCHAFFERT, R. E.; KOCHIAN, L. V.; FONTES, E. P. B.; MAGALHAES, J. V. de. Repeat variants for the SbMATE transporter protect sorghum roots from aluminum toxicity by transcriptional interplay in cis and trans. Proceedings of the National Academy of Sciences of the United States of America, Washington, v. 116, n. 1, p. 313-318, 2019. Publicado online em 13 dez. 2018. Biblioteca(s): Embrapa Milho e Sorgo. |
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71. | | CANIATO, F. F.; GUIMARAES, C. T.; HAMBLIN, M.; BILLOT, C.; RAMI, J.-F.; HUFNAGEL, B.; KOCHIAN, L. V.; LIU, J.; GARCIA, A. A. F.; HASH, C. T.; RAMU, P.; MITCHELL, S.; KRESIVICH, S.; OLIVEIRA, A. C. de; AVELLAR, G. de; BORÉM, A.; GLASZMANN, J.-C.; SCHAFFERT, R. E.; MAGALHAES, J. V. The relationship between population structure and aluminum tolerance in cultivated sorghum. Plos One, San Francisco, v. 6, n. 6, Jun. 2011. Biblioteca(s): Embrapa Milho e Sorgo. |
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Registros recuperados : 71 | |
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| Acesso ao texto completo restrito à biblioteca da Embrapa Milho e Sorgo. Para informações adicionais entre em contato com cnpms.biblioteca@embrapa.br. |
Registro Completo
Biblioteca(s): |
Embrapa Milho e Sorgo. |
Data corrente: |
04/09/2014 |
Data da última atualização: |
23/05/2017 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Circulação/Nível: |
A - 1 |
Autoria: |
GUIMARAES, C. T.; SIMOES, C. C.; PASTINA, M. M.; MARON, L. G.; MAGALHAES, J. V.; VASCONCELLOS, R. C. C.; GUIMARAES, L. J. M.; LANA, U. G. de P.; TINOCO, C. F. S.; NODA, R. W.; BELICUAS, S. N. J.; KOCHIAN, L. V.; ALVES, V. M. C.; PARENTONI, S. N. |
Afiliação: |
CLAUDIA TEIXEIRA GUIMARAES, CNPMS; MARIA MARTA PASTINA, CNPMS; JURANDIR VIEIRA DE MAGALHAES, CNPMS; LAURO JOSE MOREIRA GUIMARAES, CNPMS; UBIRACI GOMES DE PAULA LANA, CNPMS; ROBERTO WILLIANS NODA, CNPMS; SILVIA NETO JARDIM BELICUAS, CNPMS; VERA MARIA CARVALHO ALVES, CNPMS; SIDNEY NETTO PARENTONI, CNPMS. |
Título: |
Genetic dissection of Al tolerance QTLs in the maize genome by high density SNP scan. |
Ano de publicação: |
2014 |
Fonte/Imprenta: |
BMC Genomics, v. 15, n. 153, p. 1-14, 2014. |
DOI: |
10.1186/1471-2164-15-153 |
Idioma: |
Inglês |
Conteúdo: |
Background: Aluminum (Al) toxicity is an important limitation to food security in tropical and subtropical regions.High Al saturation on acid soils limits root development, reducing water and nutrient uptake. In addition to naturally occurring acid soils, agricultural practices may decrease soil pH, leading to yield losses due to Al toxicity. Elucidating the genetic and molecular mechanisms underlying maize Al tolerance is expected to accelerate the development of Al-tolerant cultivars. Results: Five genomic regions were significantly associated with Al tolerance, using 54,455 SNP markers in are combinant inbred line population derived from Cateto Al237. Candidate genes co-localized with Al tolerance QTLs were further investigated. Near-isogenic lines (NILs) developed for ZmMATE2 were as Al-sensitive as the recurrent line, indicating that this candidate gene was not responsible for the Al tolerance QTL on chromosome 5, qALT5. However, ZmNrat1, a maize homolog to OsNrat1, which encodes an Al3+ specific transporter previously implicated in rice Al tolerance, was mapped at ~40 Mbp from qALT5. We demonstrate for the first time that ZmNrat1 is preferentially expressed in maize root tips and is up-regulated by Al, similarly to OsNrat1 in rice, suggesting a role of this gene in maize Al tolerance. The strongest-effect QTL was mapped on chromosome 6 (qALT6), within a 0.5 Mbp region where three copies of the Al tolerance gene, ZmMATE1, were found in tandem configuration. qALT6 was shown to increase Al tolerance in maize; the qALT6-NILs carrying three copies of ZmMATE1 exhibited a two-fold increase in Al tolerance, and higher expression of ZmMATE1 compared to the Al sensitive recurrent parent. Interestingly, a new source of Al tolerance via ZmMATE1 was identified in a Brazilian elite line that showed high expression of ZmMATE1 but carries a single copy of ZmMATE1. Conclusions: High ZmMATE1 expression, controlled either by three copies of the target gene or by an unknown molecular mechanism, is responsible for Al tolerance mediated by qALT6 . As Al tolerant alleles at qALT6 are rare in maize, marker-assisted introgression of this QTL is an important strategy to improve maize adaptation to acid soils worldwide. MenosBackground: Aluminum (Al) toxicity is an important limitation to food security in tropical and subtropical regions.High Al saturation on acid soils limits root development, reducing water and nutrient uptake. In addition to naturally occurring acid soils, agricultural practices may decrease soil pH, leading to yield losses due to Al toxicity. Elucidating the genetic and molecular mechanisms underlying maize Al tolerance is expected to accelerate the development of Al-tolerant cultivars. Results: Five genomic regions were significantly associated with Al tolerance, using 54,455 SNP markers in are combinant inbred line population derived from Cateto Al237. Candidate genes co-localized with Al tolerance QTLs were further investigated. Near-isogenic lines (NILs) developed for ZmMATE2 were as Al-sensitive as the recurrent line, indicating that this candidate gene was not responsible for the Al tolerance QTL on chromosome 5, qALT5. However, ZmNrat1, a maize homolog to OsNrat1, which encodes an Al3+ specific transporter previously implicated in rice Al tolerance, was mapped at ~40 Mbp from qALT5. We demonstrate for the first time that ZmNrat1 is preferentially expressed in maize root tips and is up-regulated by Al, similarly to OsNrat1 in rice, suggesting a role of this gene in maize Al tolerance. The strongest-effect QTL was mapped on chromosome 6 (qALT6), within a 0.5 Mbp region where three copies of the Al tolerance gene, ZmMATE1, were found in tandem configuration. qALT6 was sh... Mostrar Tudo |
Palavras-Chave: |
Genotipagem; Sequenciamento. |
Thesagro: |
Genética; Mate; Milho; Zea mays. |
Categoria do assunto: |
-- |
Marc: |
LEADER 03239naa a2200361 a 4500 001 1994210 005 2017-05-23 008 2014 bl uuuu u00u1 u #d 024 7 $a10.1186/1471-2164-15-153$2DOI 100 1 $aGUIMARAES, C. T. 245 $aGenetic dissection of Al tolerance QTLs in the maize genome by high density SNP scan.$h[electronic resource] 260 $c2014 520 $aBackground: Aluminum (Al) toxicity is an important limitation to food security in tropical and subtropical regions.High Al saturation on acid soils limits root development, reducing water and nutrient uptake. In addition to naturally occurring acid soils, agricultural practices may decrease soil pH, leading to yield losses due to Al toxicity. Elucidating the genetic and molecular mechanisms underlying maize Al tolerance is expected to accelerate the development of Al-tolerant cultivars. Results: Five genomic regions were significantly associated with Al tolerance, using 54,455 SNP markers in are combinant inbred line population derived from Cateto Al237. Candidate genes co-localized with Al tolerance QTLs were further investigated. Near-isogenic lines (NILs) developed for ZmMATE2 were as Al-sensitive as the recurrent line, indicating that this candidate gene was not responsible for the Al tolerance QTL on chromosome 5, qALT5. However, ZmNrat1, a maize homolog to OsNrat1, which encodes an Al3+ specific transporter previously implicated in rice Al tolerance, was mapped at ~40 Mbp from qALT5. We demonstrate for the first time that ZmNrat1 is preferentially expressed in maize root tips and is up-regulated by Al, similarly to OsNrat1 in rice, suggesting a role of this gene in maize Al tolerance. The strongest-effect QTL was mapped on chromosome 6 (qALT6), within a 0.5 Mbp region where three copies of the Al tolerance gene, ZmMATE1, were found in tandem configuration. qALT6 was shown to increase Al tolerance in maize; the qALT6-NILs carrying three copies of ZmMATE1 exhibited a two-fold increase in Al tolerance, and higher expression of ZmMATE1 compared to the Al sensitive recurrent parent. Interestingly, a new source of Al tolerance via ZmMATE1 was identified in a Brazilian elite line that showed high expression of ZmMATE1 but carries a single copy of ZmMATE1. Conclusions: High ZmMATE1 expression, controlled either by three copies of the target gene or by an unknown molecular mechanism, is responsible for Al tolerance mediated by qALT6 . As Al tolerant alleles at qALT6 are rare in maize, marker-assisted introgression of this QTL is an important strategy to improve maize adaptation to acid soils worldwide. 650 $aGenética 650 $aMate 650 $aMilho 650 $aZea mays 653 $aGenotipagem 653 $aSequenciamento 700 1 $aSIMOES, C. C. 700 1 $aPASTINA, M. M. 700 1 $aMARON, L. G. 700 1 $aMAGALHAES, J. V. 700 1 $aVASCONCELLOS, R. C. C. 700 1 $aGUIMARAES, L. J. M. 700 1 $aLANA, U. G. de P. 700 1 $aTINOCO, C. F. S. 700 1 $aNODA, R. W. 700 1 $aBELICUAS, S. N. J. 700 1 $aKOCHIAN, L. V. 700 1 $aALVES, V. M. C. 700 1 $aPARENTONI, S. N. 773 $tBMC Genomics$gv. 15, n. 153, p. 1-14, 2014.
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