Severe and mild drought cause distinct phylogenetically linked shifts in the blue grama (Bouteloua gracilis) rhizobiome

Hannah M. Goemann, Danielle E. M. Ulrich, Brent M. Peyton, La Verne Gallegos-Graves, Rebecca C. Mueller
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Abstract

Plants rely on a diverse rhizobiome to regulate nutrient acquisition and plant health. With increasing severity and frequency of droughts worldwide due to climate change, untangling the relationships between plants and their rhizobiomes is vital to maintaining agricultural productivity and protecting ecosystem diversity. While some plant physiological responses to drought are generally conserved, patterns of root exudation (release of small metabolites shown to influence microbes) and the consequential effects on the plant rhizobiome can differ widely across plant species under drought. To address this knowledge gap, we conducted a greenhouse study using blue grama (Bouteloua gracilis), a drought-tolerant C4 grass native to shortgrass prairie across North American plains, as a model organism to study the effect of increasing drought severity (ambient, mild drought, severe drought) on root exudation and the rhizobiome. Our previous results demonstrated physiological effects of increasing drought severity including an increase in belowground carbon allocation through root exudation and shifts in root exudate composition concurrent with the gradient of drought severity. This work is focused on the rhizobiome community structure using targeted sequencing and found that mild and severe drought resulted in unique shifts in the bacterial + archaeal and fungal communities relative to ambient, non-droughted controls. Specifically, using the change in relative abundance between ambient and drought conditions for each ZOTU as a surrogate for population-scale drought tolerance (e.g., as a response trait), we found that rhizobiome response to drought was non-randomly distributed across the phylogenies of both communities, suggesting that Planctomycetota, Thermoproteota (formerly Thaumarchaeota), and the Glomeromycota were the primary clades driving these changes. Correlation analyses indicated weak correlations between droughted community composition and a select few root exudate compounds previously implicated in plant drought responses including pyruvic acid, D-glucose, and myoinositol. This study demonstrates the variable impacts of drought severity on the composition of the blue grama rhizobiome and provides a platform for hypothesis generation for targeted functional studies of specific taxa involved in plant-microbe drought responses.
严重干旱和轻度干旱导致蓝禾草(Bouteloua gracilis)根瘤生物群发生明显的系统发育关联转变
植物依靠多样化的根状生物群来调节养分获取和植物健康。由于气候变化,全球干旱的严重程度和频率都在增加,因此理清植物与其根系生物群落之间的关系对于维持农业生产力和保护生态系统多样性至关重要。虽然植物对干旱的一些生理反应通常是一致的,但在干旱条件下,不同植物物种的根系渗出模式(释放出被证明能影响微生物的小分子代谢物)以及由此对植物根瘤生物群产生的影响可能大相径庭。为了填补这一知识空白,我们以蓝花酢浆草(Bouteloua gracilis)--一种原产于北美平原短草草原的耐旱C4禾本科植物--为模式生物进行了一项温室研究,以研究干旱严重程度(环境、轻度干旱、严重干旱)的增加对根系渗出和根生物群的影响。我们之前的研究结果表明,干旱严重程度增加会产生生理效应,包括通过根系渗出增加地下碳分配,以及根系渗出物成分随干旱严重程度梯度变化而变化。这项工作的重点是利用靶向测序研究根瘤生物群落结构,发现相对于环境和非干旱对照,轻度和严重干旱导致细菌+古细菌和真菌群落发生独特的变化。具体来说,利用每个ZOTU在环境条件和干旱条件下的相对丰度变化作为种群规模干旱耐受性(例如,作为反应性状)的代用指标,我们发现根瘤生物群对干旱的反应在这两个群落的系统发育中呈非随机分布,这表明Planctomycetota、Thermoproteota(前Thaumarchaeota)和Glomeromycota是驱动这些变化的主要支系。相关性分析表明,干旱群落组成与之前被认为与植物干旱响应有关的少数根外渗化合物(包括丙酮酸、D-葡萄糖和肌醇)之间存在微弱的相关性。这项研究证明了干旱严重程度对蓝禾草根生物群组成的不同影响,并为参与植物-微生物干旱响应的特定类群的定向功能研究提供了一个假设生成平台。
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