草海桐DEAD-box基因家族鉴定及盐胁迫下StRH10基因的表达模式

doi:10.11983/CBB25114

植物学报

草海桐DEAD-box基因家族鉴定及盐胁迫下StRH10基因的表达模式

廖丽娴^{1, 2}, 罗靖淋², 冼宇萍², 桑海涛², 郑春芳^*, 张颖^2*

¹温州大学生命与环境科学学院, 温州325035; ²岭南师范学院生命科学与技术学院, 湛江市红树林生态系统保护与修复重点实验室, 湛江524048

收稿日期:2025-06-24 修回日期:2025-08-04 出版日期:2025-09-05 发布日期:2025-09-05
通讯作者: 郑春芳, 张颖
基金资助:
海南省原始平台科研专项(No.YCPTZX2022011, No.YSPTZX2025011)和岭南师范学校校级科研团队项目(2024)

Identification of the DEAD-box Gene Family and Expression Pattern of the StRH10 Gene Under Salt Stress in Scaevola taccada

Liao Lixian^{1, 2}, Luo Jinglin², Xian Yuping², Sang Haitao², Zheng Chunfang^1*, Zhang Ying^2*

¹College of Life and Environmental Sciences, Wenzhou University, Wenzhou 325035, China; ²College of Life Science and Technology, Lingnan Normal University, Zhanjiang Key Laboratory of Mangrove Ecosystem Conservation and Restoration, Zhanjiang 524048, China

Received:2025-06-24 Revised:2025-08-04 Online:2025-09-05 Published:2025-09-05
Contact: Chunfang Zheng, Ying Zhang

摘要/Abstract

摘要： 草海桐(Scaevola taccada)是一种广泛分布于热带和亚热带滨海地区的半红树植物, 具有出色的抗盐、耐旱以及抗风浪能力。DEAD-box家族基因参与植物对逆境胁迫的响应。为解析该半红树植物耐盐分子机制, 本研究基于基因组数据, 利用生物信息学工具系统鉴定和分析了草海桐DEAD-box RNA解旋酶基因家族成员(StRHs), 同时对StRH10基因的分子特性、组织表达特异性及盐胁迫下的分子响应进行了分析。草海桐基因组共鉴定出50个StRHs基因, 其蛋白长度范围252–2189 aa, 不均匀分布在8条染色体上。StRHs的启动子区域富含胁迫响应的ABRE, TC-rich repeats, MBS, LTR, WUN-motif和ARE等顺式作用元件。共线性分析发现草海桐分别与拟南芥(Arabidopsis thaliana)和向日葵(Helianthus annuus)有20和39对共线性基因。StRH10在叶片中的相对表达量最高。盐胁迫下, StRH10相对表达量仅达到400 mmol·L^–1时显著上调, 说明基因StRH10可能在草海桐适应盐生境中起到了重要作用。以上研究为后续挖掘草海桐耐盐基因和解释RNA解旋酶在叶绿体功能调控中的作用提供基础以及为培育具有高耐盐能力的草海桐苗木的育种工作提供前期科学依据。

关键词: 草海桐, DEAD-box基因家族, StRH10基因, 盐胁迫, 表达模式

Abstract: INTRODUCTION: The global area of saline-alkali land is approximately 932 million hectares. The problem of soil salinization caused by seawater intrusion in china's coastal areas is intensifying. Salt stress is an important abiotic stress that affects plant growth and development. Throughout the long-term evolutionary process, plants have developed complex adaptation mechanisms to cope with stress, with gene expression regulation playing a central role. Among the numerous salt stress-responsive genes, the DEAD-box RNA helicase gene family has garnered significant attention due to its crucial roles in plant growth, development, and abiotic stress responses. Studies have confirmed that members of this family are involved in the regulation of salt stress in a variety of plants. Therefore, the DEAD-box RNA helicase gene family is an important object for studying the molecular mechanism of plant salt stress response.
RATIONALE: Scaevola taccada is a semi-mangrove plant widely distributed in tropical and subtropical coastal areas. It exhibits excellent salt tolerance, drought resistance, and resilience to wind and waves. This plant holds significant ecological value for coastal sand stabilization and ecological restoration. Although the DEAD-box RNA helicase gene has been extensively studied in model plants, the genome-wide identification, chromosomal distribution, and salt stress response mechanism of this gene family remain unclear in S. taccada. Therefore, based on the genome data of S. taccada, the members of the DEAD-box gene family (StRHs) were systematically identified, and the tissue expression specificity of the StRH10 gene and its response pattern under salt stress were analyzed, aiming to provide a preliminary scientific basis for the molecular breeding of high-salt tolerant S. taccada seedlings.
RESULTS: Fifty StRH genes were identified from the genome of S. taccada. Most StRH proteins contain 10 conserved motifs, while a few contain 8 or 9. The StRH proteins comprise 18 conserved domains, primarily SrmB and DEAD. Seven StRH genes lack introns. The promoter region of the StRH genes is rich in cis-acting elements associated with the stress response. S. taccada and Arabidopsis thaliana have 20 pairs of collinear genes, and S. taccada and Helianthus annuus have 39 pairs of collinear genes. StRH10 protein is most closely related to the chloroplast-localized DEAD-box RNA helicase AtRH03 protein in A. thaliana. The subcellular localization prediction indicated that the StRH10 protein is localized to the chloroplasts. StRH10 gene was the most expressed in leaves. Under salt stress treatment, the expression level of the StRH10 gene did not show a significant difference with increasing NaCl concentration but was significantly up-regulated when the NaCl concentration reached 400 mmol·L-1.
CONCLUSION: The 50 members of the DEAD-box gene family identified in the genome of S. taccada in this study were unevenly distributed across the chromosomes. Most StRH proteins contain 10 conserved motifs and are clustered within the same evolutionary branch. The promoter region of StRH genes is rich in stress-responsive cis-acting elements such as ABRE, TC-rich repeats, MBS, LTR, WUN-motif and ARE. Collinearity analysis showed that there were 39 pairs of collinearity genes in S. taccada and H. annuus. The StRH10 gene, which encodes a protein predicted to be located in the chloroplast, exhibits high expression in leaves.Under salt stress, the expression of the StRH10 gene was significantly up-regulated only when the NaCl concentration reached 400 mmol·L-1, indicating that this gene responds to salt stress with a certain concentration threshold.

(A) DEAD-box gene family Cis-acting elements in the promoter region; (B) Phylogenetic tree of DEAD-box gene family members in S. taccada and A. thaliana (The red pentagram indicates the RH gene of S. taccada); (C) StRH10 expression levels in different organizations; (D) StRH10 expression levels under salt stress

Key words: Scaevola taccada, DEAD-box gene family, StRH10 gene, Salt stress, Expression pattern

廖丽娴, 罗靖淋, 冼宇萍, 桑海涛, 郑春芳, 张颖. 草海桐DEAD-box基因家族鉴定及盐胁迫下StRH10基因的表达模式. 植物学报, DOI: 10.11983/CBB25114.

Liao Lixian, Luo Jinglin, Xian Yuping, Sang Haitao, Zheng Chunfang, Zhang Ying.

Identification of the DEAD-box Gene Family and Expression Pattern of the StRH10 Gene Under Salt Stress in Scaevola taccada . Chinese Bulletin of Botany, DOI: 10.11983/CBB25114.

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链接本文: https://www.chinbullbotany.com/CN/10.11983/CBB25114

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草海桐DEAD-box基因家族鉴定及盐胁迫下StRH10基因的表达模式

Identification of the DEAD-box Gene Family and Expression Pattern of the StRH10 Gene Under Salt Stress in Scaevola taccada

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