帮助者和受益者之间的根瘤菌合成作用促进番茄植株健康

Sang-Moo Lee, Roniya Thapa Magar, Min Kyeong Jung, Hyun Gi Kong, Ju Yeon Song, Joo Hwan Kwon, Minseo Choi, Hyoung Ju Lee, Seung Yeup Lee, Raees Khan, Jihyun F Kim, Seon-Woo Lee
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摘要

无声明。利益冲突微生物之间的相互作用会影响微生物群落的功能。然而,人们对宿主相关群落内的微生物相互作用仍然知之甚少。在这里,我们报告了受益根瘤菌 Niallia sp. RD1 需要辅助菌 Pseudomonas putida H3 来促进细菌生长并与植物宿主进行有益的相互作用。在缺少辅助菌株 H3 的情况下,Niallia sp. RD1 菌株表现出微弱的呼吸作用和拉长的细胞形态,但不形成细菌菌落。编码琥珀酸-半醛脱氢酶基因的 H3 转座子突变体对 RD1 菌落形成的支持作用大大减弱。通过在培养基中添加琥珀酸,我们发现琥珀酸是支持 RD1 生长的公益物。基因组比较分析显示,RD1 缺乏足够的琥珀酸基因,这表明它是琥珀酸生物合成的受益者。RD1 和 H3 之间的合成互作有效地保护了番茄植株免受细菌枯萎病的侵害,并促进了番茄的生长。在培养基中添加琥珀酸可恢复 RD1 中依赖于复合体 II 的呼吸作用,并促进从根瘤中分离出的各种细菌的培养。综上所述,我们发现了微生物群落中无处不在的能量辅助营养受益者,这些受益者可以借助根瘤菌圈中的助手使寄主植物受益。
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Rhizobacterial syntrophy between a helper and a beneficiary promotes tomato plant health
None declared.Conflicts of interestMicrobial interactions impact the functioning of microbial communities. However, microbial interactions within host-associated communities remains poorly understood. Here, we report that the beneficiary rhizobacterium Niallia sp. RD1 requires the helper Pseudomonas putida H3 for bacterial growth and beneficial interactions with the plant host. In the absence of the helper H3 strain, the Niallia sp. RD1 strain exhibited weak respiration and elongated cell morphology without forming bacterial colonies. A transposon mutant of H3 in a gene encoding succinate-semialdehyde dehydrogenase displayed much attenuated support of RD1 colony formation. Through subsequent addition of succinate to the media, we found that succinate serves as a public good that supports RD1 growth. Comparative genome analysis highlighted that RD1 lacked the gene for sufficient succinate, suggesting its evolution as a beneficiary of succinate biosynthesis. The syntrophic interaction between RD1 and H3 efficiently protected tomato plants from bacterial wilt and promoted the tomato growth. The addition of succinate to the medium restored complex II-dependent respiration in RD1 and facilitated the cultivation of various bacterial isolates from the rhizosphere. Taken together, we delineate energy auxotrophic beneficiaries ubiquitous in the microbial community, and these beneficiaries could benefit host plants with the aid of helpers in the rhizosphere.
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