青枯菌GMI 1000菌株c-di-GMP合成酶Rsp1208的功能OA
Function of c-di-GMP Synthase Rsp1208 of Ralstonia solanacearum Strain GMI 1000
[背景]青枯病是由青枯劳尔氏菌(Ralstonia solanacearum)引发的毁灭性土传植物病害,c-di-GMP 作为细菌保守第二信使调控病原菌致病表型,但其在青枯菌中的核心代谢基因功能仍需深入解析.[目的]探究青枯菌 GMI 1000 中c-di-GMP 代谢相关基因的功能及调控机制,明确关键基因对菌株生理表型和致病力的影响,完善青枯菌 c-di-GMP 信号调控网络,为青枯病新型防控靶点挖掘与绿色防控策略研发提供理论依据.[方法]以青枯菌 GMI 1000 为研究对象,采用RT-qPCR 检测常规培养与模拟侵染条件下 24 个潜在 c-di-GMP 代谢基因的转录表达差异;针对极显著下调的Rsp1208,通过同源重组与电转化技术构建缺失、回补、酶活位点突变及过表达工程菌株;系统测定各菌株的生长动态、运动能力、生物膜形成量、胞外多糖产量等关键生理表型,结合RT-qPCR分析运动与胞外多糖合成相关基因的转录水平;采用LC-MS/MS与噻唑橙荧光反应法检测胞内 c-di-GMP 含量及体外合成酶活性;采用伤根接种法测定菌株对番茄的致病力.[结果]模拟侵染环境下,24 个 c-di-GMP 代谢相关基因均呈不同程度转录下调,其中Rsp1208下调水平极显著,其编码蛋白同时含有 GGDEF 与 EAL 双结构域.Rsp1208缺失后,菌株运动能力与胞外多糖产量分别显著提升 26.57%、85.92%,生物膜形成量降低 75%,胞内 c-di-GMP 水平显著下降,对番茄致病力极显著增强;回补菌株表型恢复至野生型水平,过表达菌株则表现为运动能力减弱、生物膜形成微量提升、致病力显著降低.Rsp1208缺失株中运动相关基因(flhC、fliA、fliM、fliC)与胞外多糖合成基因(xpsR、epsB)转录水平均极显著上调.GGDEF 酶活位点突变可使 Rsp1208 基本丧失 c-di-GMP 合成能力,EAL 位点突变无显著影响.[结论]Rsp1208通过 GGDEF 结构域发挥 c-di-GMP 合成酶功能,调控青枯菌胞内 c-di-GMP稳态,进而介导运动性、生物膜、胞外多糖等表型重塑,最终调控病原菌致病力,研究结果可为深入解析青枯菌的致病机制、研发绿色防控技术提供理论支撑.
[Background]Bacterial wilt is a devastating soil-borne vascular disease caused by Ralstonia solanacearum.As a conserved second messenger in bacteria,c-di-GMP orchestrates multiple pathogenic phenotypes of plant bacterial pathogens.However,the functional characteristics of core c-di-GMP metabolic genes in R.solanacearum remain to be fully elucidated.[Objective]This study aimed to investigate the functions and regulatory mechanisms of c-di-GMP metabolism-associated genes in R.solanacearum GMI 1000,clarify the impacts of key genes on bacterial physiological phenotypes and pathogenicity,refine the c-di-GMP signaling regulatory network,and to provide a theoretical foundations for screening novel control targets and developing green management strategies against bacterial wilt.[Method]Using R.solanacearum GMI 1000 as the material,RT-qPCR was performed to compare the transcriptional profiles of 24 putative c-di-GMP metabolic genes under routine culture and simulated infection conditions.For the most significantly downregulated gene Rsp1208,gene deletion,complementation,enzyme active-site mutagenesis and overexpression strains were constructed via homologous recombination and electroporation.Key physiological phenotypes including growth kinetics,motility,biofilm formation and exopolysaccharide(EPS)yield were systematically quantified.Transcriptional levels of motility-and EPS synthesis-related genes were analyzed by RT-qPCR.Intracellular c-di-GMP content and in vitro diguanylate cyclase activity were detected using LC-MS/MS and thiazole orange fluorescence assay,respectively.Pathogenicity assays on tomato seedlings were conducted using the root-wounding inoculation method.[Result]Under simulated infection conditions,all 24 c-di-GMP metabolic genes were transcriptionally downregulated to varying degrees,among which Rsp1208 showed the most extreme downregulation.The protein encoded by Rsp1208 harbors both GGDEF and EAL domains.Deletion of Rsp1208 significantly increased bacterial motility by 26.57%and EPS production by 85.92%,reduced biofilm formation by 75%,decreased intracellular c-di-GMP levels markedly,and extremely enhanced pathogenicity on tomato.The complemented strain restored wild-type phenotypes,whereas the overexpression strain exhibited attenuated motility,mildly elevated biofilm formation and significantly weakened pathogenicity.Transcriptional levels of motility-related genes(flhC,fliA,fliM,fliC)and EPS synthesis genes(xpsR,epsB)were drastically upregulated in the Rsp1208 deletion mutant.Mutation of the GGDEF active site abolished the c-di-GMP synthetic activity of Rsp1208,while EAL site mutation exerted no significant effect.[Conclusion]Rsp1208 functions as a c-di-GMP diguanylate cyclase through its GGDEF domain,regulating intracellular c-di-GMP homeostasis in R.solanacearum,mediating phenotypic remodeling of motility,biofilm formation and EPS production,and ultimately governing the pathogenicity of the pathogen.These findings deepen the mechanistic understanding of R.solanacearum pathogenesis and provide critical theoretical support for the development of green control technologies against bacterial wilt.
范晓涵;张维军;袁锦锋;赵栋霖;张成省;张之矾;徐康文
中国农业科学院烟草研究所,山东 青岛 266101贵州省烟草公司遵义市公司凤冈分公司,贵州 遵义 564200贵州省烟草公司遵义市公司凤冈分公司,贵州 遵义 564200中国农业科学院烟草研究所,山东 青岛 266101中国农业科学院烟草研究所,山东 青岛 266101贵州省烟草公司遵义市公司凤冈分公司,贵州 遵义 564200中国农业科学院烟草研究所,山东 青岛 266101
青枯菌c-di-GMP致病力运动性生物膜
Ralstonia solanacearumc-di-GMPpathogenicitymotilitybiofilm
《中国农业科学》 2026 (11)
2374-2386,13
国家自然科学基金(32302448)、贵州省烟草公司遵义市公司科技项目(2025520300270029)、山东省自然科学基金(ZR2024QC002)、中国农业科学院科技创新工程(ASTIP-TRIC-QH-2022C06)、中国烟草总公司青年人才项目(110202404015)
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