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dc.creatorBerchembrock, Yasmin Vasques-
dc.creatorPathak, Bhuvan-
dc.creatorMaurya, Chandan-
dc.creatorBotelho, Flávia Barbosa Silva-
dc.creatorSrivastava, Vibha-
dc.date.accessioned2023-12-05T21:43:08Z-
dc.date.available2023-12-05T21:43:08Z-
dc.date.issued2022-10-
dc.identifier.citationBERCHEMBROCK, Y. V. et al. Phenotypic and transcriptomic analysis reveals early stress responses in transgenic rice expressing Arabidopsis DREB1a. Plant Direct, Oxford, v. 6, n. 10, e456, Oct. 2022. DOI: https://doi.org/10.1002/pld3.456.pt_BR
dc.identifier.urihttp://repositorio.ufla.br/jspui/handle/1/58653-
dc.description.abstractOverexpression of Arabidopsis dehydration response element binding 1a (DREB1a) is a well-known approach for developing salinity, cold and/or drought stress tolerance. However, understanding of the genetic mechanisms associated with DREB1a expression in rice is generally limited. In this study, DREB1a-associated early responses were investigated in a transgenic rice line harboring cold-inducible DREB1a at a gene stacked locus. Although the function of other genes in the stacked locus was not relevant to stress tolerance, this study demonstrates DREB1a can be co-localized with other genes for multigenic trait enhancement. As expected, the transgenic lines displayed improved tolerance to salinity stress and water withholding as compared with non-transgenic controls. RNA sequencing and transcriptome analysis showed upregulation of complex transcriptional networks and metabolic reprogramming as DREB1a expression led to the upregulation of multiple transcription factor gene families, suppression of photosynthesis, and induction of secondary metabolism. In addition to the detection of previously described mechanisms such as production of protective molecules, potentially novel pathways were also revealed. These include jasmonate, auxin, and ethylene signaling, induction of JAZ and WRKY regulons, trehalose synthesis, and polyamine catabolism. These genes regulate various stress responses and ensure timely attenuation of the stress signal. Furthermore, genes associated with heat stress response were downregulated in DREB1a expressing lines, suggesting antagonism between heat and dehydration stress response pathways. In summary, through a complex transcriptional network, multiple stress signaling pathways are induced by DREB1a that presumably lead to early perception and prompt response toward stress tolerance as well as attenuation of the stress signal to prevent deleterious effects of the runoff response.pt_BR
dc.languageenpt_BR
dc.publisherJohn Wiley & Sons / American Society of Plant Biologists and Society for Experimental Biologypt_BR
dc.rightsacesso abertopt_BR
dc.rightsAttribution 4.0 International*
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/*
dc.sourcePlant Directpt_BR
dc.subjectAbiotic stresspt_BR
dc.subjectArabidopsis DREB1apt_BR
dc.subjectDrought stresspt_BR
dc.subjectOryza sativapt_BR
dc.subjectSalinity stresspt_BR
dc.subjectStress tolerancept_BR
dc.subjectTranscriptomept_BR
dc.subjectEstresse abióticopt_BR
dc.subjectDéficit hídricopt_BR
dc.subjectArroz - Tolerância ao estressept_BR
dc.subjectEstresse salinopt_BR
dc.subjectTranscriptomapt_BR
dc.subjectArroz transgênicopt_BR
dc.titlePhenotypic and transcriptomic analysis reveals early stress responses in transgenic rice expressing Arabidopsis DREB1apt_BR
dc.typeArtigopt_BR
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