Drought shifts sorghum root metabolite and microbiome profiles and enriches for pipecolic acid

IF 3.3 3区 生物学 Q2 MICROBIOLOGY
Daniel F. Caddell, Dean J. Pettinga, Katherine B. Louie, Ben Bowen, Julie A. Sievert, Joy Hollingsworth, Rebeckah Rubanowitz, J. Dahlberg, E. Purdom, T. Northen, D. Coleman-Derr
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Abstract

Plant-associated microbial communities shift in composition as a result of environmental perturbations, such as drought. Recently, it has been shown that Actinobacteria are enriched in plant roots and rhizosphere during drought stress, however, the correlations between microbiome dynamics and plant response to drought are poorly understood. Here we apply a combination of bacterial community composition analysis and plant metabolite profiling in Sorghum bicolor root, rhizosphere, and soil during drought and drought-recovery to investigate potential contributions of host metabolism towards shifts in bacterial composition. Our results provide a detailed view of metabolic shifts across the plant root during drought and show that the response to rewatering differs between root and soil; additionally, we identify drought-responsive metabolites that are highly correlated with the observed changes in Actinobacteria abundance. Furthermore, our study reports that pipecolic acid is a drought-enriched metabolite in sorghum roots, and that exogenous application of pipecolic acid inhibits root growth. Finally, we show that this activity functions independently from the systemic acquired resistance pathway, and has the potential to impact Actinobacterial taxa within the root microbiome.
干旱改变了高粱的根代谢物和微生物群,并丰富了果酸
与植物相关的微生物群落由于环境扰动(如干旱)而发生组成变化。近年来,研究表明,在干旱胁迫下,放线菌在植物根部和根际富集,但对微生物组动力学与植物对干旱反应之间的相关性知之甚少。在这里,我们将细菌群落组成分析和植物代谢产物分析相结合,在干旱和干旱恢复期间对高粱根、根际和土壤进行分析,以研究宿主代谢对细菌组成变化的潜在贡献。我们的研究结果提供了干旱期间植物根系代谢变化的详细视图,并表明根系和土壤对重新浇水的反应不同;此外,我们还鉴定了与放线菌丰度变化高度相关的干旱响应代谢产物。此外,我们的研究报告称,哌啶酸是高粱根中富含干旱的代谢产物,外源施用哌啶酸会抑制根的生长。最后,我们表明,这种活性独立于系统获得性抗性途径发挥作用,并有可能影响根微生物组中的放线菌类群。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.40
自引率
6.80%
发文量
42
审稿时长
4 weeks
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