Does soil history decline in influencing the structure of bacterial communities of Brassica napus host plants across different growth stages?

IF 5.1 Q1 ECOLOGY ISME communications Pub Date : 2024-01-31 eCollection Date: 2024-01-01 DOI:10.1093/ismeco/ycae019
Andrew J C Blakney, Marc St-Arnaud, Mohamed Hijri
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Abstract

Soil history has been shown to condition future rhizosphere microbial communities. However, previous experiments have also illustrated that mature, adult plants can "re-write," or mask, different soil histories through host plant-soil community feedbacks. This leaves a knowledge gap concerning how soil history influences bacterial community structure across different growth stages. Thus, here we tested the hypothesis that previously established soil histories will decrease in influencing the structure of Brassica napus bacterial communities over the growing season. We used an on-going agricultural field experiment to establish three different soil histories, plots of monocrop canola (B. napus), or rotations of wheat-canola, or pea-barley-canola. During the following season, we repeatedly sampled the surrounding bulk soil, rhizosphere, and roots of the B. napus hosts at different growth stages-the initial seeding conditions, seedling, rosette, bolting, and flower-from all three soil history plots. We compared composition and diversity of the B. napus soil bacterial communities, as estimated using 16S rRNA gene metabarcoding, to identify any changes associated with soil history and growth stages. We found that soil history remained significant across each growth stage in structuring the bacterial bulk soil and rhizosphere communities, but not the bacterial root communities. This suggests that the host plant's capacity to "re-write" different soil histories may be quite limited as key components that constitute the soil history's identity remain present, such that the previously established soil history continues to impact the bacterial rhizosphere communities, but not the root communities. For agriculture, this highlights how previously established soil histories persist and may have important long-term consequences on future plant-microbe communities, including bacteria.

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不同生长阶段的土壤历史是否会影响油菜寄主植物细菌群落的结构?
事实证明,土壤历史会对未来的根瘤菌群落产生影响。然而,以前的实验也表明,成熟的成年植物可以通过寄主植物-土壤群落反馈 "重写 "或掩盖不同的土壤历史。这就留下了一个知识空白,即土壤历史如何影响不同生长阶段的细菌群落结构。因此,我们在此测试了一个假设,即先前形成的土壤历史会在生长季节减少对甘蓝型油菜细菌群落结构的影响。我们利用一个正在进行的农业田间试验,建立了三种不同的土壤历史:单作油菜(B. napus)地块、小麦-油菜轮作地块或豌豆-大麦-油菜轮作地块。在接下来的一季中,我们在不同的生长阶段--播种初期、幼苗期、莲座期、拔节期和花期--从所有三种土壤历史地块中反复对周围的大块土壤、根瘤菌层和油菜寄主的根部进行采样。我们比较了使用 16S rRNA 基因代谢编码估算的油菜土壤细菌群落的组成和多样性,以确定与土壤历史和生长阶段相关的任何变化。我们发现,在每个生长阶段,土壤历史对土壤和根圈细菌群落的结构都有重要影响,但对根部细菌群落的结构影响不大。这表明,宿主植物 "重写 "不同土壤历史的能力可能非常有限,因为构成土壤历史特征的关键成分仍然存在,因此先前建立的土壤历史会继续影响细菌根圈群落,但不会影响根部群落。对于农业来说,这突出说明了以前形成的土壤历史如何持续存在,并可能对未来的植物-微生物群落(包括细菌)产生重要的长期影响。
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