TITLE

Molecular cloning and expression analysis of the MaASR1 gene in banana and functional characterization under salt stress

AUTHOR(S)
Hongxia Miao; Yuan Wang; Juhua Liu; Caihong Jia; Wei Hu; Peiguang Sun; Zhiqiang Jin; Biyu Xu
PUB. DATE
November 2014
SOURCE
Electronic Journal of Biotechnology;2014, Vol. 17 Issue 6, p287
SOURCE TYPE
Academic Journal
DOC. TYPE
Article
ABSTRACT
Background: Abscisic acid (ABA)-, stress- and ripening-induced protein (ASR) is plant-specific hydrophilic transcriptional regulators involved in sucrose stress andwounding in banana. However, it is not knownwhether banana ASRgenes confer salt stress tolerance. The contexts of the study was to analysis the sequence characterization of banana ASR1,andidentify its expression patterns and function under salt stress using quantitative real-time PCR (qPCR) and overexpression in Arabidopsis. The purpose was to evaluate the role of banana ASR1 to salt stress tolerance employed by plants. Results: A full-length cDNA isolated frombanana fruit was namedMaASR1, and it had a 432 bp open reading frame (ORF) encoding 143 amino acids.MaASR1was preferential expression in roots and leaves compared to low expression in fruits, rhizomes and flowers. Under salt stress, the expression of MaASR1 quickly increased and highest expression level was detected in roots and leaves at 4 h, and then gradually decreased. These results suggested that MaASR1 expression was induced under salt stress. MaASR1 protein was localized in the nucleus and plasma membrane. MaASR1 was transformed to Arabidopsis and verified by southern and northern analysis, transgenic lines L14 and L38 integrated one and two copies of MaASR1, respectively, while overexpression in transgenic lines provided evidence for the role of MaASR1 to salt stress tolerance. Conclusions: This study demonstrated that overexpression of MaASR1 in Arabidopsis confers salt stress tolerance by reducing the expression of ABA/stress-responsive genes, but does not affect the expression of the ABA-independent pathway and biosynthesis pathway genes.
ACCESSION #
99586657

 

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