Pattern of CsICE1 expression under cold or drought treatment and functional verification through analysis of transgenic Arabidopsis

Ding, Zhaotang; Li, C; Hong, Shi; Wang, H; Wang, Y

doi:10.4238/2015.september.22.20

Cited by 12 publications

(2 citation statements)

References 28 publications

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“…У чайного растения определено несколько ключевых генов, участвующих в процессах адаптации к низкотемпературному стрессу: CsICE1 (FE861156), CsCBF1 (EU563238), CsCBF2 (KC702795) (Wang et al, 2012;Yuan et al, 2013). При сравнении ответных реакций контрастных по устойчивости к холоду сортов чая была установлена экспрессия различных генов: CsCBF1 -у устой чивого к холоду сорта чая, CsCBF2 -у неустойчивого (Wang et al, 2012;Ding et al, 2015). При этом высокий уровень экспрессии гена CsCBF1 отмечен в результате подавления экспрессии CsCBF2, что свидетельствовало об антагонизме действия этих генов.…”

Section: генетические механизмы устойчивости растений чая к холодовомunclassified

Genes underlying cold acclimation in the tea plant (<i>Camellia sinensis</i> (L.) Kuntze)

et al. 2020

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The article reviews the latest studies showing the diversity of genetic mechanisms and gene families underlying the increased cold and frost tolerance of tea and other plant species. It has been shown that cell responses to chilling (0…+15°C) and freezing (< 0°C) are not the same and gene expression under cold stress is genotype-specific. In recent decades, progress has been made in understanding the genetic mechanisms underlying the cold response of plants – ICE1 (inducer of CBF expression 1), CBF (C-repeat-binding factor), COR (cold-regulated genes) pathways and signaling have been discovered. The ICE, CBF and DHN gene groups play a key role in the cold acclimation of the tea plant. The accumulation of CBF transcripts occurs after 15 min of chilling induction, and longer cold stress leads to accumulation of CBF transcripts. It is shown that the transcripts of the CsDHN1, CsDHN2 and CsDHN3 genes accumulate at a higher level in resistant genotypes of tea in comparison with susceptible cultivars during freezing. CBF-independent pathways include genes involved in metabolism and transcription factors such as HSFC1, ZAT12, CZF1, PLD (phospholipase D), WRKY, HD-Zip, CsLEA, LOX, NAC, HSP, which are widely distributed in plants and are involved in the basic mechanisms of tea resistance to cold and frost. The most recent studies show an important role of miRNA in the mechanisms of response to chilling and freezing in tea. The data obtained on different plant species may correlate with the mechanisms of frost tolerance of tea and are the basis for future studies of the signaling pathways of response to cold in the tea plant. The results of the research emphasize the need to further explore the ways in which various genes regulate the tolerance of tea to cold stress to find the molecular markers of frost tolerance.

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Section: генетические механизмы устойчивости растений чая к холодовомunclassified

Genes underlying cold acclimation in the tea plant (<i>Camellia sinensis</i> (L.) Kuntze)

et al. 2020

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“…Arabidopsis los5 and los6 [ 11 ] mutants with a decreased ABA level are more sensitive to low temperatures than wild types. At present, the role of ABA in plant cold resistance has been confirmed in many kinds of plants [ 12 – 19 ]. Research on the effect of membrane phosphatidylglycerol fatty acids on plasma composition, as well as on the relationship with cold hardiness, in 74 plant species showed that plasma membrane unsaturated fatty acid has a great influence on cold hardiness.…”

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confidence: 99%

Genome-wide transcriptome profiling provides overwintering mechanism of Agropyron mongolicum

et al. 2017

BMC Plant Biol

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BackgroundThe mechanism of winter survival for perennials involves multiple levels of gene regulation, especially cold resistance. Agropyron mongolicum is one important perennial grass species, but there is little information regarding its overwintering mechanism. We performed a comprehensive transcriptomics study to evaluate global gene expression profiles regarding the winter survival of Agropyron mongolicum. A genome-wide gene expression analysis involving four different periods was identified. Twenty-eight coexpression modules with distinct patterns were performed for transcriptome profiling. Furthermore, differentially expressed genes (DEGs) and their functional characterization were defined using a genome database such as NT, NR, COG, and KEGG.ResultA total of 79.6% of the unigenes were characterized to be involved in 136 metabolic pathways. In addition, the expression level of ABA receptor genes, regulation of transcription factors, and a coexpression network analysis were conducted using transcriptome data. We found that ABA receptors regulated downstream gene expression by activating bZIP and NAC transcription factors to improve cold resistance and winter survival.ConclusionThis study provides comprehensive transcriptome data for the characterization of overwintering-related gene expression profiles in A. mongolicum. Genomics resources can help provide a better understanding of the overwintering mechanism for perennial gramineae species. By analyzing genome-wide expression patterns for the four key stages of tiller bud development, the functional characteristics of the DEGs were identified that participated in various metabolic pathways and have been shown to be strongly associated with cold tolerance. These results can be further exploited to determine the mechanism of overwintering in perennial gramineae species.Electronic supplementary materialThe online version of this article (doi:10.1186/s12870-017-1086-3) contains supplementary material, which is available to authorized users.

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Response and Adaptation Mechanisms of Tea Plant to Low-Temperature Stress

Hao

Wang

Zeng

et al. 2018

Stress Physiology of Tea in the Face of Climate Change

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Pattern of CsICE1 expression under cold or drought treatment and functional verification through analysis of transgenic Arabidopsis

Cited by 12 publications

References 28 publications

Genes underlying cold acclimation in the tea plant (<i>Camellia sinensis</i> (L.) Kuntze)

Genes underlying cold acclimation in the tea plant (<i>Camellia sinensis</i> (L.) Kuntze)

Genome-wide transcriptome profiling provides overwintering mechanism of Agropyron mongolicum

Response and Adaptation Mechanisms of Tea Plant to Low-Temperature Stress

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