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Phenoxyacetic acid enhances nodulation symbiosis during the rapid growth stage of soybean
Thursday, 2024/09/12 | 08:36:43

Weijun LiXinfang ZhuMengyue ZhangXifeng YanJunchen LengYuhong ZhouLike Liu

Dajian ZhangXianzheng YuanDawei XueHuiyu Tian, and Zhaojun Ding

PNAS; September 6, 2024; 121 (37) e2322217121

Significance

Root exudates act as signaling molecules that influence legume nodulation, yet the molecular mechanisms of nonflavonoid molecules remain largely unexplored. This study identifies the role of phenoxyacetic acid (POA) in enhancing symbiosis during the rapid growth phase of soybean. It was found that POA induces infection thread formation by up-regulating GmGA2ox10, which encodes GA inactivating C20-GA2-oxidase. Additionally, POA regulates nodule development by inducing miR172c expression, which in turn removes the Nodule Number Control 1 (NNC1). We propose that POA may act as a signaling molecule to initiate nodule formation, offering unique insights into the influence of root exudates on nodulation symbiosis.

Abstract

Root exudates are known signaling agents that influence legume root nodulation, but the molecular mechanisms for nonflavonoid molecules remain largely unexplored. The number of soybean root nodules during the initial growth phase shows substantial discrepancies at distinct developmental junctures. Using a combination of metabolomics analyses on root exudates and nodulation experiments, we identify a pivotal role for certain root exudates during the rapid growth phase in promoting nodulation. Phenoxyacetic acid (POA) was found to activate the expression of GmGA2ox10 and thereby facilitate rhizobial infection and the formation of infection threads. Furthermore, POA exerts regulatory control on the miR172c-NNC1 module to foster nodule primordia development and consequently increase nodule numbers. These findings collectively highlight the important role of POA in enhancing nodulation during the accelerated growth phase of soybeans.

 

See https://www.pnas.org/doi/10.1073/pnas.2322217121

 

Figure 2: Inoculation with rhizobium induces alterations in the composition of root exudates. (A and B) Classification of root exudates metabolites from soybean uninoculated (A) and inoculated (B) with B. diazoefficiens USDA110 was performed, resulting in the identification of 355 and 928 compounds, respectively, in each sample type. (C and D) Compound number (C) and percent (D) in each category of soybean root exudates were compared between uninoculated and inoculated with B. diazoefficiens USDA110.

 

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