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Registro Completo |
Biblioteca(s): |
Biblioteca Rui Tendinha. |
Data corrente: |
19/01/2021 |
Data da última atualização: |
19/01/2021 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Autoria: |
SÁ ANTUNES, T. F.; MAURASTONI, M. L.; MADROÑERO, J.; FUENTES, G.; SANTAMARÍA, J. M.; VENTURA, J. A.; ABREU, E. F.; FERNANDES, A. R.; FERNANDES, P. M. B. |
Afiliação: |
Tathiana F. Sá Antunes, UFES; Marlonni Maurastoni L., UFES; Johana Madroñero, UFES/UNIVERSIDAD EL BOSQUE; Gabriela Fuentes, Centro de Investigación Científica de Yucatán; Jorge M. Santamaría, Centro de Investigación Científica de Yucatán; Jose Aires Ventura, Incaper; Emauel F. Abreu, Embrapa Recursos Genéticos e Biotecnologia; Alberto R. Fernandes, UFES; Patricia M. B. Fernandes, UFES. |
Título: |
Battle of three: the curious case of papaya sticky disease. |
Ano de publicação: |
2020 |
Fonte/Imprenta: |
Plant Disease, v. 104, n. 11, p. 2754-2763, 2020. |
Idioma: |
Português |
Conteúdo: |
Among the most serious problems in papaya production are the viruses associated with papaya ringspot and papaya sticky disease (PSD). PSD concerns producers worldwide because its symptoms are extremely aggressive and appear only after flowering. As no resistant cultivar is available, several disease management strategies have been used in affected countries, such as the use of healthy seeds, exclusion of the pathogen, and roguing. In the 1990s, a dsRNA virus, papaya meleira virus (PMeV), was identified in Brazil as the causal agent of PSD. However, in 2016 a second virus, papaya meleira virus 2 (PMeV2), with an ssRNA genome, was also identified in PSD plants. Only PMeV is detected in asymptomatic plants, whereas all symptomatic plants contain both viral RNAs separately packaged in particles formed by the PMeV capsid protein. PSD also affects papaya plants in Mexico, Ecuador, and Australia. PMeV2-like viruses have been identified in the affected plants, but the partner virus(es) in these countries are still unknown. In Brazil, PMeV and PMeV2 reside in laticifers that promote spontaneous latex exudation, resulting in the affected papaya fruit?s sticky appearance. Genes modulated in plants affected by PSD include those involved in reactive oxygen species and salicylic acid signaling, proteasomal degradation, and photosynthesis, which are key plant defenses against PMeV complex infection. However, the complete activation of the defense response is impaired by the expression of negative effectors modulated by the virus. This review presents a summary of the current knowledge of the Carica papaya-PMeV complex interaction and management strategies. MenosAmong the most serious problems in papaya production are the viruses associated with papaya ringspot and papaya sticky disease (PSD). PSD concerns producers worldwide because its symptoms are extremely aggressive and appear only after flowering. As no resistant cultivar is available, several disease management strategies have been used in affected countries, such as the use of healthy seeds, exclusion of the pathogen, and roguing. In the 1990s, a dsRNA virus, papaya meleira virus (PMeV), was identified in Brazil as the causal agent of PSD. However, in 2016 a second virus, papaya meleira virus 2 (PMeV2), with an ssRNA genome, was also identified in PSD plants. Only PMeV is detected in asymptomatic plants, whereas all symptomatic plants contain both viral RNAs separately packaged in particles formed by the PMeV capsid protein. PSD also affects papaya plants in Mexico, Ecuador, and Australia. PMeV2-like viruses have been identified in the affected plants, but the partner virus(es) in these countries are still unknown. In Brazil, PMeV and PMeV2 reside in laticifers that promote spontaneous latex exudation, resulting in the affected papaya fruit?s sticky appearance. Genes modulated in plants affected by PSD include those involved in reactive oxygen species and salicylic acid signaling, proteasomal degradation, and photosynthesis, which are key plant defenses against PMeV complex infection. However, the complete activation of the defense response is impaired by the expression of n... Mostrar Tudo |
Palavras-Chave: |
Meleira. |
Thesagro: |
Carica Papaya; Doença; Mamão; Praga. |
Categoria do assunto: |
H Saúde e Patologia |
URL: |
https://biblioteca.incaper.es.gov.br/digital/bitstream/123456789/4168/1/Battle-of-Three-Papaya-Sticky-Disease-2020.pdf
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Marc: |
LEADER 02409naa a2200277 a 4500 001 1023094 005 2021-01-19 008 2020 bl uuuu u00u1 u #d 100 1 $aSÁ ANTUNES, T. F. 245 $aBattle of three$bthe curious case of papaya sticky disease.$h[electronic resource] 260 $c2020 520 $aAmong the most serious problems in papaya production are the viruses associated with papaya ringspot and papaya sticky disease (PSD). PSD concerns producers worldwide because its symptoms are extremely aggressive and appear only after flowering. As no resistant cultivar is available, several disease management strategies have been used in affected countries, such as the use of healthy seeds, exclusion of the pathogen, and roguing. In the 1990s, a dsRNA virus, papaya meleira virus (PMeV), was identified in Brazil as the causal agent of PSD. However, in 2016 a second virus, papaya meleira virus 2 (PMeV2), with an ssRNA genome, was also identified in PSD plants. Only PMeV is detected in asymptomatic plants, whereas all symptomatic plants contain both viral RNAs separately packaged in particles formed by the PMeV capsid protein. PSD also affects papaya plants in Mexico, Ecuador, and Australia. PMeV2-like viruses have been identified in the affected plants, but the partner virus(es) in these countries are still unknown. In Brazil, PMeV and PMeV2 reside in laticifers that promote spontaneous latex exudation, resulting in the affected papaya fruit?s sticky appearance. Genes modulated in plants affected by PSD include those involved in reactive oxygen species and salicylic acid signaling, proteasomal degradation, and photosynthesis, which are key plant defenses against PMeV complex infection. However, the complete activation of the defense response is impaired by the expression of negative effectors modulated by the virus. This review presents a summary of the current knowledge of the Carica papaya-PMeV complex interaction and management strategies. 650 $aCarica Papaya 650 $aDoença 650 $aMamão 650 $aPraga 653 $aMeleira 700 1 $aMAURASTONI, M. L. 700 1 $aMADROÑERO, J. 700 1 $aFUENTES, G. 700 1 $aSANTAMARÍA, J. M. 700 1 $aVENTURA, J. A. 700 1 $aABREU, E. F. 700 1 $aFERNANDES, A. R. 700 1 $aFERNANDES, P. M. B. 773 $tPlant Disease$gv. 104, n. 11, p. 2754-2763, 2020.
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42. | | PINHEIRO, A. C. M.; ZANÚNCIO JUNIOR, J. S.; GUARÇONI, R. G.; COSTA, H.; FORNAZIER, M. J.; FORNAZIER, M. L.; BOTACIM, L. A.; RIVA-SOUZA, E. M.; FERRÃO, M. A. G. Incidência de bicho mineiro (leucoptera coffeella) em diversos genótipos de café arábica. In: SIMPÓSIO INCAPER PESQUISA, 2., 2022, Vitória, ES. Incidência de bicho mineiro (leucoptera coffeella) em diversos genótipos de café arábica. Editores, Andréa Ferreira da Costa... [et al]., Vitória, ES : Incaper, 2023. Anais... Vitória, ES : Incaper, p. 13, 2023. p. 13Tipo: Publicação em Anais de Congresso |
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44. | | ARLEU, R. J. A.; PISSARRA, T. B.; MUNIZ, J. M.; SOUZA, I. A. de.; BRAVIM, A. J. B. Controle quimico do acaro do abacaxizeiro (Dolichotetranychus floridanus Banks, 1900). INDICAÇÃO EMCAPA, Cariacica, n. 2, p. 1-6, 1978. 07p. (EMCAPA. Indicação EMCAPA, 02/78).Biblioteca(s): Biblioteca Rui Tendinha. |
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46. | | ZANÚNCIO JUNIOR, J. S.; FORNAZIER, M. J.; MARTINS, D. dos S.; CHAMORRO-RENGIFO, J.; QUEIROZ, R. B.; LAZZARINI, A. L.; FERREIRA, P. S. F. Meroncidius intermedius (Orthoptera: Tettigoniidae): A threat to brazilian banana. Florida Entomologist, v. 100(3), p. 669-671, 2017.Tipo: Artigo em Periódico Indexado | Circulação/Nível: B - 1 |
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48. | | DORZENONI, R. R.; ZANÚNCIO JUNIOR, J. S.; FORNAZIER, M. J.; MARTINS, D. dos S.; FORNAZIER, M. L.; FORNAZIER, D. L.; GOMES, W.R.; SCALFONI, A.; GUARÇONI, R. G. Ocorrência de cochonilhas em café conilon. In: SEMINÁRIO DE INICIAÇÃO CIENTÍFICA E TECNOLÓGICA (SICT) DO INCAPER, 2., 2017. JORNADA DE INICIAÇÃO CIENTÍFICA, DESENVOLVIMENTO TECNOLÓGICO E INOVAÇÃO DO IFES, 12., 2017. Colatina, ES : IFES; Incaper, 2017.Tipo: Publicação em Anais de Congresso |
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51. | | BINDA FILHO, B.; SOUZA, C. A. S.; PULSCHEN, E. P.; SANTANA, E. N. de.; COSTA, F. de P. D.; COSTA, H.; LIMA, I. de M.; VENTURA, J. A.; LANI, J. A.; CONCEIÇÃO, L. R.; AGUILAR, M. A. G.; MARTINS, M. V. V.; SIQUEIRA, P. R.; LOURENÇO, R. S. A vassoura-de-bruxa no estado do Espírito Santo. 2 ed. Vitória, ES: Incaper, 2008. (Incaper. Documentos, 153).Biblioteca(s): Biblioteca Rui Tendinha. |
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52. | | QUEIROZ, R. B.; LOPES, M. C.; COSTA, T. L.; SILVA, R. S. da; GALDINO, T. V. S.; GONTIJO, P. da C.; MARTINEZ, H. E. P.; PICANÇO, M. C. Influence of tomato plants nutritional status on the fitness and damage of Tuta absoluta (Lepidoptera: Gelechiidae). Agricultural and Forest Entomology, p. 1-7, 2022.Tipo: Artigo em Periódico Indexado |
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53. | | CRESPO, A. M.; GONÇALVES, D. da C.; SOUZA, M. N.; ZANÚNCIO JUNIOR, J. S.; COSTA, H.; FAVARATO, L. F.; RANGEL, O. J. P.; ARAÚJO, J. B. S. Manejo da lagarta-do-cartucho do milho (Spodoptera frugiperda): panorama geral das atualizações no controle alternativo. Alegre, ES : IFES Alegre, 2021. 20 p. (IFES Alegre. Boletim Técnico, 06).Tipo: Boletim de Pesquisa e Desenvolvimento |
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56. | | COSTA, H.; VENTURA, J. A.; BARBOSA, J. C.; REZENDE, J. A. M. Amarelão do tomateiro. 1 ed. Vitória, ES: Incaper, 2009. (Incaper. Documentos, 175). Publicado também na Revista AgroMinas, ano 4, n. 28, 2013.Biblioteca(s): Biblioteca Rui Tendinha; São Gabriel da Palha. |
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57. | | FERRÃO, R. G.; FERRÃO, M. A. G.; FONSECA, A. F. A. da.; BRAGANÇA, S. M.; LANI, J. A.; COSTA, A. N. da.; SILVA, J. G. F. da.; BENASSI, V. L. R. M.; VENTURA, J. A. Como produzir café Conilon. Viçosa, MG : CPT; Incaper, 2001. 102 p. (CPT; Incaper. Série Cafeicultura, n. 313). Curso, contém fita VHS.Biblioteca(s): Biblioteca Rui Tendinha. |
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