An Amur grape VaHsfC1 is involved in multiple abiotic stresses

•A class c heat stress transcription factor (Hsf),was isolated from cold-tolerant vitis amurensis Rupr.designated as VaHsfC1, and its functional roles in multiple abiotic stress were further validated.•Unusually, VaHsfC1 was preferentially localized in nucleus, but less in the cytosol. Also, no tran...

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Published in:Scientia horticulturae 2022-03, Vol.295, p.110785, Article 110785
Main Authors: Jiao, Shu-Zhen, Guo, Chao, Yao, Wen-Kong, Zhang, Ning-Bo, Zhang, Ji-Yuan, Xu, Wei-Rong
Format: Article
Language:English
Subjects:
Abiotic stress
Arabidopsis
VaHsfC1
Vitis amurensis
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Summary:•A class c heat stress transcription factor (Hsf),was isolated from cold-tolerant vitis amurensis Rupr.designated as VaHsfC1, and its functional roles in multiple abiotic stress were further validated.•Unusually, VaHsfC1 was preferentially localized in nucleus, but less in the cytosol. Also, no transcriptional activation was detected for the protein in yeast cells.•Overexpression of VaHsfC1 in arabidopsis enhanced heat- and cold-tolerance, but decreased salt-tolerance and increased ABA hypersensitivity.•This work provided a deeper understanding of the complex nature of VaHsfC1 in mediating multiple abiotic stress responses, as a key component to further understanding of the ‘crosstalk’ mechanism of multiple abiotic stress response in plants. Plant heat stress transcription factors (Hsfs) belong to a very large gene family and play dominant roles in response to heat stress. Here, we report the functional analysis of VaHsfC1, a class C Hsf gene from Vitis amurensis, and involved in multiple abiotic stresses. The structure of VaHsfC1 contains a typical HSF domain for DNA-binding at N terminus. Phylogenetic analysis revealed that VaHsfC1 belongs to the C1 family of Hsfs. VaHsfC1 was highly induced by heat, cold, exogenous abscisic acid (ABA) and salinity, respectively. Unusually, VaHsfC1was preferentially localized in nucleus, but less in the cytosol. Also, no transcriptional activation was detected for the protein in yeast cells. Ectopic VaHsfC1 expression in Arabidopsis enhanced heat tolerance characterized by the increased survival rate, higher chlorophyll content, reduced electrolyte leakage, and activated expressions of ascorbate peroxidase (Apx2) and heat shock protein (HSP) expression compared to the WT. Interestingly, overexpression of VaHsfC1 in Arabidopsis could also increase the cold tolerance, as reveled from a series changes at the physiological and biochemical steps, as well as at the transcript levels of CORs in the CBF-dependent responsive pathway. Additionally, the growth of VaHsfC1-overexpressing Arabidopsis showed enhanced seed ABA hypersensitivity during germination and cotyledon development, and a significant reduction in stomatal aperture was also observed in overexpression lines. Furthermore, VaHsfC1-overexpressing lines displayed salt-hypersensitive phenotype with a lower rates both in germination and cotyledon greening, and the inhibition of root growth. Our findings demonstrated that the complex nature of VaHsfC1 in mediating multiple
ISSN:0304-4238
1879-1018
DOI:10.1016/j.scienta.2021.110785