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Author: search.filters.author.Sharma, RitaSubject: search.filters.subject.Abiotic stress

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    2 - Signaling cross talk between biotic and abiotic stress responses in soybean
    (Academic Press, 2016) Sharma, Rita
    Biotic and abiotic stresses take a heavy toll on crop productivity in soybean (Glycine max (L.) Merr.). To deal with this problem, considerable efforts have been made to understand the molecular mechanism underlying stress perception and tolerance in response to both biotic and abiotic stresses. Recent advances have highlighted several candidate genes that are involved in tolerance to more than one type of stress and, therefore, affect the outcome of the stress response. In this chapter, we summarize the current knowledge about the key transcription factors and signaling components known to regulate stress cross talk in soybean. In total, twenty genes have been demonstrated to confer tolerance to multiple stresses using transgenic approaches. However, to date, only three genes including GmERF3, GmERF057, and GmCAM4 are known to confer tolerance to both biotic and abiotic stresses. Further, in addition to the key genes, the potential of microRNAs and mycorrhiza in engineering broad spectrum stress-tolerant soybean varieties has been discussed.
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    Identification, phylogeny, and transcript profiling of ERF family genes during development and abiotic stress treatments in tomato
    (Springer, 2010-10-05) Sharma, Rita
    Ethylene responsive transcription factors have been shown to be intimately connected to plant development, defense responses and stress signaling pathways and in order to use them for plant improvement, we need to have better understanding of these proteins. In this study, 85 ERF genes have been identified from tomato using raw EST data in various public repositories. Phylogenetic analysis with tomato ERF domains revealed their distribution in all the groups, previously identified in model systems. MEME motif analysis resulted in identification of conserved domains, characteristic to member of each clade, in addition to ERF domain. Expression analysis during vegetative and reproductive stages of development using QPCR and tomato GeneChip® arrays, revealed their tissue-specific/preferential accumulation. In total, 57 genes were found to be differentially expressed during temporal stages of tomato fruit development. The expression analysis of 23 ERF family genes representing each clade in response to seven abiotic stress treatments revealed their differential expression in response to more than one abiotic stress treatments. Results suggest that ERF genes play diverse roles in plant’s life and comprehensive data generated will be helpful in conducting functional genomics studies to understand their precise role during plant development and stress response.