Streptomyces improves sugarcane drought tolerance by enhancing phenylalanine biosynthesis and optimizing the rhizosphere environment

IF 6.1 2区 生物学 Q1 PLANT SCIENCES Plant Physiology and Biochemistry Pub Date : 2024-10-24 DOI:10.1016/j.plaphy.2024.109236
Fei Pang , Manoj Kumar Solanki , Yong-Xiu Xing , Deng-Feng Dong , Zhen Wang
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Abstract

Drought stress is a common hazard faced by sugarcane growth, and utilizing microorganisms to enhance plant tolerance to abiotic stress has become an important method for sustainable agricultural development. Several studies have demonstrated that Streptomyces chartreuses WZS021 improves sugarcane tolerance to drought stress. However, the molecular mechanisms underlying tolerance at the transcriptional and metabolomic levels remain unclear. We comprehensively evaluated the physiological and molecular mechanisms by which WZS021 enhances drought tolerance in sugarcane, by performing transcriptome sequencing and non-targeted metabolomics; and examining rhizosphere soil properties and plant tissue antioxidant capacity. WZS021 inoculation improved the rhizosphere nutritional environment (AP, ammonia, OM) of sugarcane and enhanced the antioxidant capacity of plant roots, stems, and leaves (POD, SOD, CAT). Comprehensive analyses of the transcriptome and metabolome revealed that WZS021 mainly affects plant drought tolerance through phenylalanine metabolism, plant hormone signal transduction, and flavonoid biosynthesis pathways. The drought tolerance signaling molecules mediated by WZS021 include petunidin, salicylic acid, α-Linoleic acid, auxin, geranylgeraniol and phenylalanine, as well as key genes related to plant hormone signaling transduction (YUCCA, amiE, AUX, CYPs, PAL, etc.). Interestingly, inoculation with WZS021 during regular watering induces a transcriptome-level response to biological stress in sugarcane plants. This study further elucidates a WZS021-dependent rhizosphere-mediated regulatory mechanism for improving sugarcane drought tolerance, providing a theoretical basis for increasing sugarcane production capacity.

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链霉菌通过加强苯丙氨酸的生物合成和优化根瘤菌环境提高甘蔗的耐旱性
干旱胁迫是甘蔗生长面临的常见危害,利用微生物提高植物对非生物胁迫的耐受性已成为农业可持续发展的重要方法。多项研究表明,图链霉菌 WZS021 能提高甘蔗对干旱胁迫的耐受性。然而,在转录和代谢组水平上的耐受性分子机制仍不清楚。我们通过进行转录组测序和非靶向代谢组学研究,并考察根圈土壤特性和植物组织抗氧化能力,全面评估了 WZS021 提高甘蔗耐旱性的生理和分子机制。接种 WZS021 改善了甘蔗根圈的营养环境(AP、氨、OM),提高了植物根、茎、叶的抗氧化能力(POD、SOD、CAT)。转录组和代谢组的综合分析表明,WZS021主要通过苯丙氨酸代谢、植物激素信号转导和类黄酮生物合成途径影响植物的抗旱性。WZS021 介导的抗旱信号分子包括矮牵牛素、水杨酸、α-亚油酸、辅助素、香叶醇和苯丙氨酸,以及与植物激素信号转导相关的关键基因(YUCCA、amiE、AUX、CYPs、PAL 等)。有趣的是,在常规浇水期间接种 WZS021 会诱导甘蔗植物对生物胁迫做出转录组水平的反应。本研究进一步阐明了依赖 WZS021 的根瘤菌介导的提高甘蔗抗旱性的调控机制,为提高甘蔗生产能力提供了理论依据。
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来源期刊
Plant Physiology and Biochemistry
Plant Physiology and Biochemistry 生物-植物科学
CiteScore
11.10
自引率
3.10%
发文量
410
审稿时长
33 days
期刊介绍: Plant Physiology and Biochemistry publishes original theoretical, experimental and technical contributions in the various fields of plant physiology (biochemistry, physiology, structure, genetics, plant-microbe interactions, etc.) at diverse levels of integration (molecular, subcellular, cellular, organ, whole plant, environmental). Opinions expressed in the journal are the sole responsibility of the authors and publication does not imply the editors'' agreement. Manuscripts describing molecular-genetic and/or gene expression data that are not integrated with biochemical analysis and/or actual measurements of plant physiological processes are not suitable for PPB. Also "Omics" studies (transcriptomics, proteomics, metabolomics, etc.) reporting descriptive analysis without an element of functional validation assays, will not be considered. Similarly, applied agronomic or phytochemical studies that generate no new, fundamental insights in plant physiological and/or biochemical processes are not suitable for publication in PPB. Plant Physiology and Biochemistry publishes several types of articles: Reviews, Papers and Short Papers. Articles for Reviews are either invited by the editor or proposed by the authors for the editor''s prior agreement. Reviews should not exceed 40 typewritten pages and Short Papers no more than approximately 8 typewritten pages. The fundamental character of Plant Physiology and Biochemistry remains that of a journal for original results.
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