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986 related items for PubMed ID: 31182497

  • 21. Symbiotic Efficiency of Spherical and Elongated Bacteroids in the Aeschynomene-Bradyrhizobium Symbiosis.
    Lamouche F, Bonadé-Bottino N, Mergaert P, Alunni B.
    Front Plant Sci; 2019; 10():377. PubMed ID: 31001301
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  • 22. Extended Hopanoid Loss Reduces Bacterial Motility and Surface Attachment and Leads to Heterogeneity in Root Nodule Growth Kinetics in a Bradyrhizobium-Aeschynomene Symbiosis.
    Belin BJ, Tookmanian EM, de Anda J, Wong GCL, Newman DK.
    Mol Plant Microbe Interact; 2019 Oct; 32(10):1415-1428. PubMed ID: 31170026
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  • 23. RibBX of Bradyrhizobium ORS285 Plays an Important Role in Intracellular Persistence in Various Aeschynomene Host Plants.
    Nouwen N, Arrighi JF, Gully D, Giraud E.
    Mol Plant Microbe Interact; 2021 Jan; 34(1):88-99. PubMed ID: 33226302
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  • 24. The role of rhizobial (NifV) and plant (FEN1) homocitrate synthases in Aeschynomene/photosynthetic Bradyrhizobium symbiosis.
    Nouwen N, Arrighi JF, Cartieaux F, Chaintreuil C, Gully D, Klopp C, Giraud E.
    Sci Rep; 2017 Mar 27; 7(1):448. PubMed ID: 28348373
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  • 25. Insights into the Phylogeny, Nodule Function, and Biogeographic Distribution of Microsymbionts Nodulating the Orphan Kersting's Groundnut [Macrotyloma geocarpum (Harms) Marechal & Baudet] in African Soils.
    Mohammed M, Jaiswal SK, Dakora FD.
    Appl Environ Microbiol; 2019 Jun 01; 85(11):. PubMed ID: 30952658
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  • 26. Evolution of Bradyrhizobium-Aeschynomene mutualism: living testimony of the ancient world or highly evolved state?
    Okubo T, Fukushima S, Minamisawa K.
    Plant Cell Physiol; 2012 Dec 01; 53(12):2000-7. PubMed ID: 23161855
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  • 27. Aeschynomene indica-Nodulating Rhizobia Lacking Nod Factor Synthesis Genes: Diversity and Evolution in Shandong Peninsula, China.
    Zhang Z, Li Y, Pan X, Shao S, Liu W, Wang ET, Xie Z.
    Appl Environ Microbiol; 2019 Nov 15; 85(22):. PubMed ID: 31562167
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  • 28. Homocitrate Synthase Genes of Two Wide-Host-Range Bradyrhizobium Strains are Differently Required for Symbiosis Depending on Host Plants.
    Hashimoto S, Wongdee J, Songwattana P, Greetatorn T, Goto K, Tittabutr P, Boonkerd N, Teaumroong N, Uchiumi T.
    Microbes Environ; 2019 Dec 27; 34(4):393-401. PubMed ID: 31597890
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  • 29. A Stringent-Response-Defective Bradyrhizobium diazoefficiens Strain Does Not Activate the Type 3 Secretion System, Elicits an Early Plant Defense Response, and Circumvents NH4NO3-Induced Inhibition of Nodulation.
    Pérez-Giménez J, Iturralde ET, Torres Tejerizo G, Quelas JI, Krol E, Borassi C, Becker A, Estevez JM, Lodeiro AR.
    Appl Environ Microbiol; 2021 Apr 13; 87(9):. PubMed ID: 33608284
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  • 30. Terminal bacteroid differentiation in the legume-rhizobium symbiosis: nodule-specific cysteine-rich peptides and beyond.
    Alunni B, Gourion B.
    New Phytol; 2016 Jul 13; 211(2):411-7. PubMed ID: 27241115
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  • 31. Hopanoid lipids promote soybean-Bradyrhizobium symbiosis.
    Pan H, Shim A, Lubin MB, Belin BJ.
    mBio; 2024 Apr 10; 15(4):e0247823. PubMed ID: 38445860
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  • 32. Metabolomic Profiling of Bradyrhizobium diazoefficiens-Induced Root Nodules Reveals Both Host Plant-Specific and Developmental Signatures.
    Lardi M, Murset V, Fischer HM, Mesa S, Ahrens CH, Zamboni N, Pessi G.
    Int J Mol Sci; 2016 May 27; 17(6):. PubMed ID: 27240350
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  • 33. Hopanoids Confer Robustness to Physicochemical Variability in the Niche of the Plant Symbiont Bradyrhizobium diazoefficiens.
    Tookmanian E, Junghans L, Kulkarni G, Ledermann R, Saenz J, Newman DK.
    J Bacteriol; 2022 Jul 19; 204(7):e0044221. PubMed ID: 35657706
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  • 34. Poor Competitiveness of Bradyrhizobium in Pigeon Pea Root Colonization in Indian Soils.
    Chalasani D, Basu A, Pullabhotla SVSRN, Jorrin B, Neal AL, Poole PS, Podile AR, Tkacz A.
    mBio; 2021 Aug 31; 12(4):e0042321. PubMed ID: 34225488
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  • 35. Molecular insights into bacteroid development during Rhizobium-legume symbiosis.
    Haag AF, Arnold MF, Myka KK, Kerscher B, Dall'Angelo S, Zanda M, Mergaert P, Ferguson GP.
    FEMS Microbiol Rev; 2013 May 31; 37(3):364-83. PubMed ID: 22998605
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  • 36. Bradyrhizobium ontarionense sp. nov., a novel bacterial symbiont isolated from Aeschynomene indica (Indian jointvetch), harbours photosynthesis, nitrogen fixation and nitrous oxide (N2O) reductase genes.
    Bromfield ESP, Cloutier S.
    Antonie Van Leeuwenhoek; 2024 Apr 22; 117(1):69. PubMed ID: 38647727
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  • 37. An antimicrobial peptide essential for bacterial survival in the nitrogen-fixing symbiosis.
    Kim M, Chen Y, Xi J, Waters C, Chen R, Wang D.
    Proc Natl Acad Sci U S A; 2015 Dec 08; 112(49):15238-43. PubMed ID: 26598690
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  • 38. Investigating the Involvement of Cytoskeletal Proteins MreB and FtsZ in the Origin of Legume-Rhizobial Symbiosis.
    Zhao W, Zhu H, Wei F, Zhou D, Li Y, Zhang XX.
    Mol Plant Microbe Interact; 2021 May 08; 34(5):547-559. PubMed ID: 33596109
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  • 39. Rhizobial adaptation to hosts, a new facet in the legume root-nodule symbiosis.
    Koch M, Delmotte N, Rehrauer H, Vorholt JA, Pessi G, Hennecke H.
    Mol Plant Microbe Interact; 2010 Jun 08; 23(6):784-90. PubMed ID: 20459317
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  • 40. An overview of the metabolic differences between Bradyrhizobium japonicum 110 bacteria and differentiated bacteroids from soybean (Glycine max) root nodules: an in vitro 13C- and 31P-nuclear magnetic resonance spectroscopy study.
    Vauclare P, Bligny R, Gout E, Widmer F.
    FEMS Microbiol Lett; 2013 Jun 08; 343(1):49-56. PubMed ID: 23480054
    [Abstract] [Full Text] [Related]

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