α-Tomatine gradient across artificial roots recreates the recruitment of tomato root-associated Sphingobium.

IF 2.3 3区 生物学 Q2 PLANT SCIENCES Plant Direct Pub Date : 2023-12-18 eCollection Date: 2023-12-01 DOI:10.1002/pld3.550
Kyoko Takamatsu, Miwako Toyofuku, Fuki Okutani, Shinichi Yamazaki, Masaru Nakayasu, Yuichi Aoki, Masaru Kobayashi, Kentaro Ifuku, Kazufumi Yazaki, Akifumi Sugiyama
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Abstract

α-Tomatine is a major saponin that accumulates in tomatoes (Solanum lycopersicum). We previously reported that α-tomatine secreted from tomato roots modulates root-associated bacterial communities, particularly by enriching the abundance of Sphingobium belonging to the family Sphingomonadaceae. To further characterize the α-tomatine-mediated interactions between tomato plants and soil bacterial microbiota, we first cultivated tomato plants in pots containing different microbial inoculants originating from three field soils. Four bacterial genera, namely, Sphingobium, Bradyrhizobium, Cupriavidus, and Rhizobacter, were found to be commonly enriched in tomato root-associated bacterial communities. We constructed a pseudo-rhizosphere system using a mullite ceramic tube as an artificial root to investigate the influence of α-tomatine in modifying bacterial communities. The addition of α-tomatine from the artificial root resulted in the formation of a concentration gradient of α-tomatine that mimicked the tomato rhizosphere, and distinctive bacterial communities were observed in the soil close to the artificial root. Sphingobium was enriched according to the α-tomatine concentration gradient, whereas Bradyrhizobium, Cupriavidus, and Rhizobacter were not enriched in α-tomatine-treated soil. The tomato root-associated bacterial communities were similar to the soil bacterial communities in the vicinity of artificial root-secreting exudates; however, hierarchical cluster analysis revealed a distinction between root-associated and pseudo-rhizosphere bacterial communities. These results suggest that the pseudo-rhizosphere device at least partially creates a rhizosphere environment in which α-tomatine enhances the abundance of Sphingobium in the vicinity of the root. Enrichment of Sphingobium in the tomato rhizosphere was also apparent in publicly available microbiota data, further supporting the tight association between tomato roots and Sphingobium mediated by α-tomatine.

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人工根上的α-托马汀梯度再现了番茄根相关鞘氨醇的招募。
α-托马汀是番茄(Solanum lycopersicum)中积累的一种主要皂甙。我们以前曾报道过,番茄根部分泌的α-托马汀能调节根相关细菌群落,特别是通过富集属于鞘氨单胞菌科的鞘氨单胞菌。为了进一步描述α-托马汀介导的番茄植株与土壤细菌微生物群之间的相互作用,我们首先将番茄植株栽培在含有来自三种田间土壤的不同微生物接种物的花盆中。结果发现,番茄根相关细菌群落中通常富含四种细菌属,即鞘霉属、子囊菌属、杯霉属和根瘤菌属。我们用莫来石陶瓷管作为人工根,构建了一个假根圈系统,以研究α-托马汀对细菌群落变化的影响。从人工根中加入α-托马汀后,形成了模仿番茄根瘤层的α-托马汀浓度梯度,在靠近人工根的土壤中观察到了独特的细菌群落。根据α-托马汀浓度梯度,番茄变形菌富集,而在经过α-托马汀处理的土壤中,巴西根瘤菌、杯状芽孢杆菌和根瘤菌没有富集。番茄根相关细菌群落与人工根分泌渗出液附近的土壤细菌群落相似;然而,分层聚类分析显示根相关细菌群落与假根圈细菌群落之间存在区别。这些结果表明,假根圈装置至少在一定程度上创造了一种根圈环境,在这种环境中,α-托马汀能提高根部附近的鞘氨醇数量。在公开的微生物群数据中,番茄根瘤菌在番茄根圈中的富集也是显而易见的,这进一步证明了α-托马汀介导的番茄根和鞘氨醇之间的紧密联系。
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来源期刊
Plant Direct
Plant Direct Environmental Science-Ecology
CiteScore
5.00
自引率
3.30%
发文量
101
审稿时长
14 weeks
期刊介绍: Plant Direct is a monthly, sound science journal for the plant sciences that gives prompt and equal consideration to papers reporting work dealing with a variety of subjects. Topics include but are not limited to genetics, biochemistry, development, cell biology, biotic stress, abiotic stress, genomics, phenomics, bioinformatics, physiology, molecular biology, and evolution. A collaborative journal launched by the American Society of Plant Biologists, the Society for Experimental Biology and Wiley, Plant Direct publishes papers submitted directly to the journal as well as those referred from a select group of the societies’ journals.
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