Endophytic pyrroloquinoline quinone enhances banana growth and immunity against Fusarium wilt for plant-microbe mutualisms

Shih-Hsun Walter Hung, Man-Yun Yu, Chia-Ho Liu, Tsai-Ching Huang, Jian-Hau Peng, Nai-Yun Jang, Chih-Horng Kuo, Yu-Liang Yang, Ying-Ning Ho, En-Pei Isabel Chiang, Hau-Hsuan Hwang, Chieh-Chen Huang
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Abstract

Fusarium wilt has a substantial impact on global banana production, posing a threat to food security worldwide. However, breeding new Fusarium-resistant cultivars is difficult and time-consuming. Alternatively, endophytic biostimulants that could combat such pervasive plant diseases provide possible novel solutions. Our prior research demonstrated that a pyrroloquinoline quinone (PQQ)-producing endophytic bacterium, Burkholderia seminalis 869T2, can enhance the growth of various plant species and protect bananas from Fusarium wilt in the field. PQQ is a peptide-derived redox cofactor known to stimulate mitochondrial biogenesis and metabolism in animals, but its molecular roles, especially in plants, remain to be elucidated. In this study, multi-omics approaches were employed to explore the potential mechanisms through which PQQ influences banana plants. The result of in situ imaging mass spectrometry revealed that the endophytic metabolite PQQ does not function through direct antagonism against Fusarium. The follow-up transcriptomic profiling shows it could regulate plant respiration, TCA cycle, oxidative phosphorylation, NAD/NADP-dependent dehydrogenases, MAPK signalling, and various phytohormone signalling pathways. Furthermore, PQQ appeared to trigger plant systemic immunity, thereby enhancing plant health and resistance to biotic stress. Beyond that, the complete genome of 869T2 was determined for follow-up comparative genomics analyses, revealing its genetic contexts, potential evolutionary events of PQQ operons among the Burkholderia species, and the absence of human virulence-facilitating genes within those PQQ-producing agricultural isolates. In summary, this study facilitates our understanding of PQQ in plant-microbe mutualisms and provides scientific evidence for its future application in agriculture.
内生吡咯喹啉醌可促进香蕉生长,增强香蕉对镰刀菌枯萎病的免疫力,促进植物与微生物的互生关系
镰刀菌枯萎病对全球香蕉生产产生了重大影响,对全球粮食安全构成了威胁。然而,培育新的抗镰刀菌栽培品种既困难又耗时。另外,可防治此类普遍植物病害的内生生物刺激素也提供了可能的新型解决方案。我们之前的研究表明,一种能产生吡咯喹啉醌(PQQ)的内生细菌--精囊伯克霍尔德氏菌 869T2--能促进多种植物的生长,保护香蕉在田间免受镰刀菌枯萎病的侵害。PQQ 是一种多肽衍生的氧化还原辅助因子,已知可刺激动物线粒体的生物生成和新陈代谢,但其分子作用,尤其是在植物中的作用仍有待阐明。本研究采用多组学方法探讨了 PQQ 影响香蕉植物的潜在机制。原位成像质谱分析结果显示,内生代谢物 PQQ 并非通过直接拮抗镰刀菌发挥作用。后续的转录组分析表明,它可以调节植物呼吸、TCA 循环、氧化磷酸化、NAD/NAD-依赖性脱氢酶、MAPK 信号传导以及各种植物激素信号传导途径。此外,PQQ 似乎还能触发植物系统免疫,从而增强植物健康和对生物胁迫的抵抗力。此外,还确定了 869T2 的完整基因组,以便进行后续的比较基因组学分析,从而揭示了其遗传背景、伯克霍尔德氏菌物种间 PQQ 操作子的潜在进化事件,以及在这些产生 PQQ 的农业分离物中缺乏人类毒力促进基因的情况。总之,这项研究有助于我们了解 PQQ 在植物-微生物互作中的作用,并为其未来在农业中的应用提供了科学依据。
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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