Doherty D, Leigh J A, Glazebrook J, Walker G C
Biology Department, Massachusetts Institute of Technology, Cambridge 02139.
J Bacteriol. 1988 Sep;170(9):4249-56. doi: 10.1128/jb.170.9.4249-4256.1988.
The acidic Calcofluor-binding exopolysaccharide of Rhizobium meliloti Rm1021 plays one or more critical roles in nodule invasion and possibly in nodule development. Two loci, exoR and exoS, that affect the regulation of synthesis of this exopolysaccharide were identified by screening for derivatives of strain Rm1021 that formed mucoid colonies that fluoresced extremely brightly under UV light when grown on medium containing Calcofluor. The exopolysaccharide produced in large quantities by the exoR95::Tn5 and exoS96::Tn5 strains was indistinguishable from that produced by the parental strain Rm1021, and its synthesis required the function of at least the exoA, exoB, and exoF genes. Both the exoR and exoS loci were located on the chromosome, and the exo96::Tn5 mutation was 84% linked to the trp-33 mutation by phi M12 transduction. Synthesis of the Calcofluor-binding exopolysaccharide by strain Rm1021 was greatly stimulated by starvation for ammonia. In contrast, the exoR95::Tn5 mutant produced high levels of exopolysaccharide regardless of the presence or absence of ammonia in the medium. The exoS96::Tn5 mutant produced elevated amounts of exopolysaccharide in the presence of ammonia, but higher amounts were observed after starvation for ammonia. The presence of either mutation increased the level of expression of exoF::TnphoA and exoP::TnphoA fusions (TnphoA is Tn5 IS50L::phoA). Analyses of results obtained when alfalfa seedlings were inoculated with the exoR95::Tn5 strain indicated that the mutant strain could not invade nodules. However, pseudorevertants that retained the original exoR95::Tn5 mutation but acquired unlinked suppressors so that they produced an approximately normal amount of exopolysaccharide were able to invade nodules and fix nitrogens. The exoS95::Tn5 strain formed Fix+ nodules, although some minor variability was observed.
苜蓿中华根瘤菌Rm1021的酸性钙荧光结合胞外多糖在根瘤侵染以及可能在根瘤发育过程中发挥一个或多个关键作用。通过筛选Rm1021菌株的衍生物来鉴定影响这种胞外多糖合成调控的两个基因座,exoR和exoS,这些衍生物在含有钙荧光白的培养基上生长时形成在紫外光下发出极亮荧光的黏液状菌落。exoR95::Tn5和exoS96::Tn5菌株大量产生的胞外多糖与亲本菌株Rm1021产生的胞外多糖没有区别,其合成至少需要exoA、exoB和exoF基因的功能。exoR和exoS基因座都位于染色体上,通过phi M12转导,exo96::Tn5突变与trp-33突变的连锁率为84%。菌株Rm1021对钙荧光白结合胞外多糖的合成受到氨饥饿的极大刺激。相反,无论培养基中是否存在氨,exoR95::Tn5突变体都产生高水平的胞外多糖。exoS96::Tn5突变体在有氨存在时产生的胞外多糖量增加,但在氨饥饿后观察到更高的量。任何一种突变的存在都会增加exoF::TnphoA和exoP::TnphoA融合体(TnphoA是Tn5 IS50L::phoA)的表达水平。用exoR95::Tn5菌株接种苜蓿幼苗后获得的结果分析表明,突变菌株不能侵染根瘤。然而,保留原始exoR95::Tn5突变但获得不连锁抑制子从而产生大致正常量胞外多糖的假回复体能够侵染根瘤并固氮。exoS95::Tn5菌株形成了Fix+根瘤,尽管观察到一些微小的变异性。
