Integrating Transcriptome, Metabolome and Microbiome to Explore the Molecular Mechanism of Phenotypic Plasticity in P. rotata During Low-Altitude Domestication.

IF 6.3 1区生物学 Q1 PLANT SCIENCES

Plant, Cell & Environment Pub Date : 2025-08-20 DOI:10.1111/pce.70138

Xuemei Wu, Hongchuan Chen, Rong Ding, Guopeng Chen, Hongmei Jia, Shihong Zhong, Rui Gu

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引用次数: 0

Abstract

The endangered Tibetan herb Phlomoides rotata is threatened by overharvesting and slow natural regeneration. To support its sustainable utilisation, we investigated the mechanisms underlying its phenotypic plasticity during low-altitude adaptation using an integrated multi-omics approach. Specifically, rhizosphere soils and leaf tissues were collected from P. rotata cultivated at high-, mid-, and low altitudes for multi-omics analysis, including bacterial and fungal profiling, and phenotypic, transcriptomic, and metabolomic assessments. Altitude-dependent shifts were observed in microbial community composition. Functional profiling suggests that rhizosphere microbial communities of P. rotata at low altitude possess enhanced metabolic activity and nutrient cycling capacity. Procrustes analysis revealed strong concordance between potential microbial indicators and phenotypic traits (R² = 0.84, p = 0.002 for bacteria, R² = 0.82, p = 0.005 for fungi). Transcriptomic analysis identified 3336 and 9208 unigenes associated with phenotypic variation. GO enrichment revealed that low-altitude samples were dominated by growth-related functions, while high-altitude samples favoured defence responses. KEGG enrichment of hub genes supported this pattern, highlighting enhanced developmental and biosynthetic pathways at low altitudes and stress-regulatory processes at high altitudes. Metabolomic analysis identified 658 altitude-associated differential metabolites. KEGG enrichment showed zeatin biosynthesis was prominent at high altitudes, while butanoate, starch, and sucrose metabolism were enriched at low altitudes. Furthermore, random forest analysis of phenotype-associated metabolites revealed that phenylpropanoids and organic acids were characteristic of high-altitude samples, while organoheterocyclic compounds were more typical of low-altitude environments. Mantel test and PLS-SEM modelling jointly revealed that altitude-driven shifts in rhizosphere microbiome function regulate host gene expression and secondary metabolism, ultimately shaping phenotypic variation. This comprehensive research provides novel insights into the environmentally induced phenotypic plasticity of alpine medicinal plants during low-altitude adaptation and offers a deeper understanding of the key drivers of this process.

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整合转录组、代谢组和微生物组，探索圆叶蒿低海拔驯化过程中表型可塑性的分子机制。

为了支持其可持续利用，我们利用综合多组学方法研究了其在低海拔适应过程中的表型可塑性机制。具体地说，收集了高、中、低海拔地区种植的轮叶青根际土壤和叶片组织，进行多组学分析，包括细菌和真菌谱，表型、转录组学和代谢组学评估。微生物群落组成随海拔变化而变化。功能分析表明，低海拔条件下轮作根际微生物群落具有较强的代谢活性和养分循环能力。Procrustes分析显示，潜在微生物指标与表型性状具有较强的一致性（细菌R²= 0.84,p = 0.002，真菌R²= 0.82,p = 0.005）。转录组学分析鉴定出3336和9208个与表型变异相关的单基因。氧化石墨烯富集表明，低海拔样品以生长相关功能为主，而高海拔样品则有利于防御反应。枢纽基因的KEGG富集支持这一模式，突出了低海拔地区发育和生物合成途径的增强以及高海拔地区应激调节过程的增强。代谢组学分析鉴定出658种与海拔相关的差异代谢物。KEGG富集表明，玉米素的生物合成在高海拔地区突出，而丁酸盐、淀粉和蔗糖的代谢在低海拔地区富集。此外，表型相关代谢物的随机森林分析显示，苯丙素和有机酸是高海拔样品的特征，而有机杂环化合物则是低海拔环境的典型代谢物。Mantel检验和PLS-SEM模型共同揭示了海拔驱动的根际微生物组功能变化调节宿主基因表达和次生代谢，最终形成表型变异。这项综合研究为高山药用植物在低海拔适应过程中环境诱导的表型可塑性提供了新的见解，并为这一过程的关键驱动因素提供了更深入的理解。

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来源期刊

Plant, Cell & Environment 生物-植物科学

CiteScore

13.30

自引率

4.10%

发文量

253

审稿时长

1.8 months

期刊介绍： Plant, Cell & Environment is a premier plant science journal, offering valuable insights into plant responses to their environment. Committed to publishing high-quality theoretical and experimental research, the journal covers a broad spectrum of factors, spanning from molecular to community levels. Researchers exploring various aspects of plant biology, physiology, and ecology contribute to the journal's comprehensive understanding of plant-environment interactions.