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1. Sinorhizobium medicae WSM419 Genes That Improve Symbiosis between Sinorhizobium meliloti Rm1021 and Medicago truncatula Jemalong A17 and in Other Symbiosis Systems

   https://doi.org/10.1128/AEM.03004-20  

   Ghosh, Prithwi; Adolphsen, Katie N.; Yurgel, Svetlana N.; Kahn, Michael L. (July 2021, Applied and Environmental Microbiology)

   Stabb, Eric V. (Ed.)

   ABSTRACT Some soil bacteria, called rhizobia, can interact symbiotically with legumes, in which they form nodules on the plant roots, where they can reduce atmospheric dinitrogen to ammonia, a form of nitrogen that can be used by growing plants. Rhizobium-plant combinations can differ in how successful this symbiosis is: for example, Sinorhizobium meliloti Rm1021 forms a relatively ineffective symbiosis with Medicago truncatula Jemalong A17, but Sinorhizobium medicae WSM419 is able to support more vigorous plant growth. Using proteomic data from free-living and symbiotic S. medicae WSM419, we previously identified a subset of proteins that were not closely related to any S. meliloti Rm1021 proteins and speculated that adding one or more of these proteins to S. meliloti Rm1021 would increase its effectiveness on M. truncatula A17. Three genes, Smed_3503, Smed_5985, and Smed_6456, were cloned into S. meliloti Rm1021 downstream of the E. coli lacZ promoter. Strains with these genes increased nodulation and improved plant growth, individually and in combination with one another. Smed_3503, renamed iseA ( i ncreased s ymbiotic e ffectiveness), had the largest impact, increasing M. truncatula biomass by 61%. iseA homologs were present in all currently sequenced S. medicae strains but were infrequent in other Sinorhizobium isolates. Rhizobium leguminosarum bv. viciae 3841 containing iseA led to more nodules on pea and lentil. Split-root experiments with M. truncatula A17 indicated that S. meliloti Rm1021 carrying the S. medicae iseA is less sensitive to plant-induced resistance to rhizobial infection, suggesting an interaction with the plant’s regulation of nodule formation. IMPORTANCE Legume symbiosis with rhizobia is highly specific. Rhizobia that can nodulate and fix nitrogen on one legume species are often unable to associate with a different species. The interaction can be more subtle. Symbiotically enhanced growth of the host plant can differ substantially when nodules are formed by different rhizobial isolates of a species, much like disease severity can differ when conspecific isolates of pathogenic bacteria infect different cultivars. Much is known about bacterial genes essential for a productive symbiosis, but less is understood about genes that marginally improve performance. We used a proteomic strategy to identify Sinorhizobium genes that contribute to plant growth differences that are seen when two different strains nodulate M. truncatula A17. These genes could also alter the symbiosis between R. leguminosarum bv. viciae 3841 and pea or lentil, suggesting that this approach identifies new genes that may more generally contribute to symbiotic productivity. 

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2. VPT ‐like genes modulate Rhizobium –legume symbiosis and phosphorus adaptation

   https://doi.org/10.1111/tpj.16363  

   Liu, Jinlong; Yang, Rongchen; Yan, Jun; Li, Chun; Lin, Xizhen; Lin, Lin; Cao, Yanyan; Xu, Tiandong; Li, Jianxuan; Yuan, Yangyang; et al (October 2023, The Plant Journal)

   SUMMARY Although vacuolar phosphate transporters (VPTs) are essential for plant phosphorus adaptation, their role inRhizobium–legume symbiosis is unclear. In this study, homologous genes ofVPT1(MtVPTs)were identified inMedicago truncatulato assess their roles inRhizobium–legume symbiosis and phosphorus adaptation.MtVPT2andMtVPT3mainly positively responded to low and high phosphate, respectively. However, bothmtvpt2andmtvpt3mutants displayed shoot phenotypes with high phosphate sensitivity and low phosphate tolerance. The root‐to‐shoot phosphate transfer efficiency was significantly enhanced inmtvpt3but weakened inmtvpt2, accompanied by lower and higher root cytosolic inorganic phosphate (Pi) concentration, respectively. Low phosphate inducedMtVPT2andMtVPT3expressions in nodules.MtVPT2andMtVPT3mutations markedly reduced the nodule number and nitrogenase activity under different phosphate conditions. Cytosolic Pi concentration in nodules was significantly lower inmtvpt2andmtvpt3than in the wildtype, especially in tissues near the base of nodules, probably due to inhibition of long‐distance Pi transport and cytosolic Pi supply. Also,mtvpt2andmtvpt3could not maintain a stable cytosolic Pi level in the nodule fixation zone as the wildtype under low phosphate stress. These findings show thatMtVPT2and MtVPT3modulate phosphorus adaptation and rhizobia–legume symbiosis, possibly by regulating long‐distance Pi transport. 

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3. The role of microRNAs in the legume–Rhizobium nitrogen-fixing symbiosis

   https://doi.org/10.1093/jxb/eraa018  

   Hoang, Nhung T; Tóth, Katalin; Stacey, Gary; Mittler, Ron (March 2020, Journal of Experimental Botany)

   Abstract Under nitrogen starvation, most legume plants form a nitrogen-fixing symbiosis with Rhizobium bacteria. The bacteria induce the formation of a novel organ called the nodule in which rhizobia reside as intracellular symbionts and convert atmospheric nitrogen into ammonia. During this symbiosis, miRNAs are essential for coordinating the various plant processes required for nodule formation and function. miRNAs are non-coding, endogenous RNA molecules, typically 20–24 nucleotides long, that negatively regulate the expression of their target mRNAs. Some miRNAs can move systemically within plant tissues through the vascular system, which mediates, for example, communication between the stem/leaf tissues and the roots. In this review, we summarize the growing number of miRNAs that function during legume nodulation focusing on two model legumes, Lotus japonicus and Medicago truncatula, and two important legume crops, soybean (Glycine max) and common bean (Phaseolus vulgaris). This regulation impacts a variety of physiological processes including hormone signaling and spatial regulation of gene expression. The role of mobile miRNAs in regulating legume nodule number is also highlighted. 

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4. The Medicago truncatula hydrolase MtCHIT5b degrades Nod factors of Sinorhizobium meliloti and cooperates with MtNFH1 to regulate the nodule symbiosis

   https://doi.org/10.3389/fpls.2022.1034230  

   Li, Ru-Jie; Zhang, Chun-Xiao; Fan, Sheng-Yao; Wang, Yi-Han; Wen, Jiangqi; Mysore, Kirankumar S.; Xie, Zhi-Ping; Staehelin, Christian (November 2022, Frontiers in Plant Science)

   Nod factors secreted by nitrogen-fixing rhizobia are lipo-chitooligosaccharidic signals required for establishment of the nodule symbiosis with legumes. InMedicago truncatula, the Nod factor hydrolase 1 (MtNFH1) was found to cleave Nod factors ofSinorhizobium meliloti. Here, we report that the class V chitinase MtCHIT5b ofM. truncatulaexpressed inEscherichia colican release lipodisaccharides from Nod factors. Analysis ofM. truncatulamutant plants indicated that MtCHIT5b, together with MtNFH1, degradesS. melilotiNod factors in the rhizosphere.MtCHIT5bexpression was induced by treatment of roots with purified Nod factors or inoculation with rhizobia. MtCHIT5b with a fluorescent tag was detected in the infection pocket of root hairs. Nodulation of aMtCHIT5bknockout mutant was not significantly altered whereas overexpression ofMtCHIT5bresulted in fewer nodules. Reduced nodulation was observed whenMtCHIT5bandMtNFH1were simultaneously silenced in RNA interference experiments. Overall, this study shows that nodule formation ofM. truncatulais regulated by a second Nod factor cleaving hydrolase in addition to MtNFH1. 

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5. Mobile gene clusters and coexpressed plant–rhizobium pathways drive partner quality variation in symbiosis

   https://doi.org/10.1073/pnas.2411831122  

   Riaz, Muhammad_Rizwan; Sosa_Marquez, Ivan; Lindgren, Hanna; Levin, Garrett; Doyle, Rebecca; Romero, Mario_Cerón; Paoli, Julia_C; Drnevich, Jenny; Fields, Christopher_J; Geddes, Barney_A; et al (July 2025, Proceedings of the National Academy of Sciences)

   Plant–microbe symbioses such as the legume–rhizobium mutualism are vital in the web of ecological relationships within both natural and managed ecosystems, influencing primary productivity, crop yield, and ecosystem services. The outcome of these interactions for plant hosts varies quantitatively and can range from highly beneficial to even detrimental depending on natural genetic variation in microbial symbionts. Here, we take a systems genetics approach, harnessing the genetic diversity present in wild rhizobial populations to predict genes and molecular pathways crucial in determining partner quality, i.e., the benefits of symbiosis for legume hosts. We combine traits, dual-RNAseq of both partners from active nodules, pangenomics/pantranscriptomics, and Weighted Gene Co-expression Network Analysis (WGCNA) for a panel of 20Sinorhizobium melilotistrains that vary in symbiotic partner quality. We find that genetic variation in the nodule transcriptome predicts host plant biomass, and WGCNA reveals networks of genes in plants and rhizobia that are coexpressed and associated with high-quality symbiosis. Presence–absence variation of gene clusters on the symbiosis plasmid (pSymA), validated in planta, is associated with high or low-quality symbiosis and is found within important coexpression modules. Functionally our results point to management of oxidative stress, amino acid and carbohydrate transport, and NCR peptide signaling mechanisms in driving symbiotic outcomes. Our integrative approach highlights the complex genetic architecture of microbial partner quality and raises hypotheses about the genetic mechanisms and evolutionary dynamics of symbiosis. 

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