Functional characterization of malate dehydrogenase, HcMDH1, gene in enhancing abiotic stress tolerance in kenaf (Hibiscus cannabinus L.)

IF 5.2 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Chemical and Biological Technologies in Agriculture Pub Date : 2024-09-19 DOI:10.1186/s40538-024-00670-1

Dengjie Luo, Zengqiang Li, Samavia Mubeen, Muzammal Rehman, Shan Cao, Caijin Wang, Jiao Yue, Jiao Pan, Gang Jin, Ru Li, Tao Chen, Peng Chen

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Abstract

Drought and salt stress are two important environmental factors that significantly restrict plant growth and reproduction. Malate dehydrogenase is essential to life as it is engaged in numerous physiological processes in cells, particularly those related to abiotic stress reactions. However, a complete understanding of MDH family members in kenaf is not clear yet. In this study, subcellular localization analysis and a yeast transcriptional activation assay revealed that HcMDH1 was localized in chloroplasts but had no transcriptional activation activity. When exposed to salt or drought stress, yeast cells expressing the HcMDH1 gene exhibit an increased survival rate. Overexpression of HcMDH1 in Arabidopsis increased seed germination rate and root growth when transgenic lines were exposed to varying concentrations of mannitol and NaCl. Subsequent physiological studies revealed that transgenic lines had higher concentrations of soluble carbohydrates, proline, and chlorophyll and lower concentrations of malondialdehyde (MDA) and reactive oxygen species (ROS). Furthermore, inhibiting HcMDH1 in kenaf using virus-induced gene silencing (VIGS) decreased salt and drought tolerance due to elevated ROS and MDA levels. In these silenced lines, the expression of six essential genes engaged in stress-resistance and photosynthesis, namely HcGAPDH, HcGLYK, HcFBA, HcFBPase, HcPGA, and HcLSD, is significantly altered under salt and drought stress. In summary, HcMDH1 is a complex and positive regulatory gene that plays a key role in regulating chlorophyll content, antioxidant enzyme activity and osmotic regulation under salt and drought stress, which may have implications for kenaf transgenic breeding.

Graphical Abstract

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苹果酸脱氢酶 HcMDH1 基因在增强木槿（Hibiscus cannabinus L.）非生物胁迫耐受性方面的功能表征

干旱和盐胁迫是严重制约植物生长和繁殖的两个重要环境因素。苹果酸脱氢酶对生命至关重要，因为它参与细胞中的许多生理过程，尤其是与非生物胁迫反应有关的过程。然而，人们对剑麻中的 MDH 家族成员还没有一个全面的了解。本研究通过亚细胞定位分析和酵母转录激活试验发现，HcMDH1 定位于叶绿体，但没有转录激活活性。在盐胁迫或干旱胁迫下，表达 HcMDH1 基因的酵母细胞存活率提高。当转基因品系暴露于不同浓度的甘露醇和氯化钠时，拟南芥中 HcMDH1 的过表达提高了种子萌发率和根系生长。随后的生理研究表明，转基因品系的可溶性碳水化合物、脯氨酸和叶绿素浓度更高，丙二醛（MDA）和活性氧（ROS）浓度更低。此外，利用病毒诱导基因沉默（VIGS）抑制红豆杉中的 HcMDH1，会因 ROS 和 MDA 水平升高而降低耐盐性和耐旱性。在这些被沉默的品系中，参与抗逆性和光合作用的六个重要基因（即 HcGAPDH、HcGLYK、HcFBA、HcFBPase、HcPGA 和 HcLSD）的表达在盐胁迫和干旱胁迫下发生了显著变化。综上所述，HcMDH1是一个复杂的正调控基因，在盐胁迫和干旱胁迫下对叶绿素含量、抗氧化酶活性和渗透调节起着关键的调控作用，可能对剑麻转基因育种有一定的意义。

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来源期刊

Chemical and Biological Technologies in Agriculture Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

6.80

自引率

3.00%

发文量

审稿时长

15 weeks

期刊介绍： Chemical and Biological Technologies in Agriculture is an international, interdisciplinary, peer-reviewed forum for the advancement and application to all fields of agriculture of modern chemical, biochemical and molecular technologies. The scope of this journal includes chemical and biochemical processes aimed to increase sustainable agricultural and food production, the evaluation of quality and origin of raw primary products and their transformation into foods and chemicals, as well as environmental monitoring and remediation. Of special interest are the effects of chemical and biochemical technologies, also at the nano and supramolecular scale, on the relationships between soil, plants, microorganisms and their environment, with the help of modern bioinformatics. Another special focus is the use of modern bioorganic and biological chemistry to develop new technologies for plant nutrition and bio-stimulation, advancement of biorefineries from biomasses, safe and traceable food products, carbon storage in soil and plants and restoration of contaminated soils to agriculture. This journal presents the first opportunity to bring together researchers from a wide number of disciplines within the agricultural chemical and biological sciences, from both industry and academia. The principle aim of Chemical and Biological Technologies in Agriculture is to allow the exchange of the most advanced chemical and biochemical knowledge to develop technologies which address one of the most pressing challenges of our times - sustaining a growing world population. Chemical and Biological Technologies in Agriculture publishes original research articles, short letters and invited reviews. Articles from scientists in industry, academia as well as private research institutes, non-governmental and environmental organizations are encouraged.