Driven to autoimmunity: the nod mouse

In the lymphoid system, T cells respond to space or under-crowding by dividing to maintain their numbers. In this issue of Cell, evidence is provided that this homeostatic proliferation, coupled with excess production of a cytokine, IL-21, is a key factor in susceptibility to autoimmune diabetes.     

Cloning of the nodulation (nod) genes of Rhizobium phaseoli and their homology to R. leguminosarum nod DNA

In Rhizobium phaseoli strain 8002, a large indigenous plasmid, pRP2JI, had previously been shown to carry many of the genes necessary for the induction of nitrogen-fixing nodules on Phaseolus beans. A cosmid clone library was constructed using DNA from strain 8002. From this library, two overlapping recombinant plasmids (pIJ1097 and pIJ1098) were isolated which spanned about 43 kb of pRP2JI DNA. These plasmids could restore nodulation to some, but not all nodulation-deficient strains of R. phaseoli, indicating that the nodulation genes were not clustered within one small region of pRP2JI. The cloned R. phaseoli nodulation region shared extensive DNA homology with the nodulation genes of R. leguminosarum, and on the basis of DNA hybridization, the nitrogenase genes were found to be within 10 kb of the R. phaseoli nodulation genes. Close to the nodulation genes of R. phaseoli was located a sequence that was repeated on pRP2JI but which was not present elsewhere in the genome of strain 8002.     

Inducers of nod genes of Rhizobium ciceri.

Induction of nodABC genes of R. ciceri was studied by constructing nodABC-lacZ fusion. The root exudates of the homologous hosts induced the expression of nodABC genes but those of heterologous hosts failed to do so. The HPLC analysis of the root exudates of C. arietinum showed the presence of 6-7 compounds with retention times matching to flavonoids like naringenin, hesperetin, daidzein, naringin, 7 OH coumarin and luteolin. Induction studies using the standard flavonoids showed naringenin, followed by daidzein, as most potent inducer of the nodABC genes of R. ciceri. Naringenin in combination with daidzein showed a synergistic effect on the expression of nodABC genes.     

可诱导结瘤基因nodA的体外转录

报道结瘤基因nodA的体外诱导转录 :当转录体系中有一定量的调控蛋白NodD和植物诱导分子柚皮素 (naringenin )存在时 ,在体外转录的产物中始终存在着与体内转录相一致的特异产物。体外诱导转录表明 ,可诱导结瘤基因nodA在体内转录时 ,可能同样存在NodD蛋白、柚皮素诱导剂分子和nodA启动子的某种方式的直接相互作用     

在结瘤基因nodA启动子内发现了两个不同功能的结构区域

在豌豆根瘤菌（ＲｈｉｚｏｂｉｕｍＬｅｇｕｍｉｎｏｓａｒｕｍ）结瘤基因ｎｏｄＡ的启动子内发现了具有两个不同功能的结构区域,其一我们称为Ｒｉｐ,在ｎｏｄＡ诱导表达中起着关键作用,可能识别经诱导剂作用而发生构象变化的调控蛋白ＮｏｄＤ,另一为ＲＩＰ缺失后留下的,我们称为ＲＰ区,只要ＲＰ存在,不需要诱导剂,ＮｏｄＤ蛋白即能导致结瘤基因ｎｏｄＡ的表达。因此该区可能识别原始构象的调控蛋白ＮｏｄＤ。     

Rhizobium nodM and nodN genes are common nod genes: nodM encodes functions for efficiency of nod signal production and bacteroid maturation.

Earlier, we showed that Rhizobium meliloti nodM codes for glucosamine synthase and that nodM and nodN mutants produce strongly reduced root hair deformation activity and display delayed nodulation of Medicago sativa (Baev et al., Mol. Gen. Genet. 228:113-124, 1991). Here, we demonstrate that nodM and nodN genes from Rhizobium leguminosarum biovar viciae restore the root hair deformation activity of exudates of the corresponding R. meliloti mutant strains. Partial restoration of the nodulation phenotypes of these two strains was also observed. In nodulation assays, galactosamine and N-acetylglucosamine could substitute for glucosamine in the suppression of the R. meliloti nodM mutation, although N-acetylglucosamine was less efficient. We observed that in nodules induced by nodM mutants, the bacteroids did not show complete development or were deteriorated, resulting in decreased nitrogen fixation and, consequently, lower dry weights of the plants. This mutant phenotype could also be suppressed by exogenously supplied glucosamine, N-acetylglucosamine, and galactosamine and to a lesser extent by glucosamine-6-phosphate, indicating that the nodM mutant bacteroids are limited for glucosamine. In addition, by using derivatives of the wild type and a nodM mutant in which the nod genes are expressed at a high constitutive level, it was shown that the nodM mutant produces significantly fewer Nod factors than the wild-type strain but that their chemical structures are unchanged. However, the relative amounts of analogs of the cognate Nod signals were elevated, and this may explain the observed host range effects of the nodM mutation. Our data indicate that both the nodM and nodN genes of the two species have common functions and confirm that NodM is a glucosamine synthase with the biochemical role of providing sufficient amounts of the sugar moiety for the synthesis of the glucosamine oligosaccharide signal molecules.     

Expression of the nodulation gene nod C of Rhizobium meliloti in Escherichia coli: role of the nod C gene product in nodulation

The nod C gene of Rhizobium meliloti encodes a protein of mol. wt. 44 000 which is highly conserved in at least three Rhizobium species. In order to overproduce this protein, a gene fusion of lambda cI repressor sequences to a large fragment of nod C was constructed. The fusion was placed under control of the tac promoter on plasmid pEA305 to yield pJS1035. IPTG-induced Escherichia coli cells harbouring pJS1035 accumulated the cI-nod C hybrid protein up to 19% of total cellular protein. The synthesis of the hybrid protein drastically inhibits the growth rate of the bacterium. The fusion protein was purified by gel and hydroxyapatite chromatography in the presence of SDS. Antibodies raised against the purified fusion protein precipitated the mol. wt. 44 000 nod C proteins of R. meliloti and of the broad-host range Rhizobium strain NGR234, which were both expressed in E. coli mini-cells. The hybrid protein is associated with the outer membrane of E. coli cells, and the cI-nod C fusion protein appears to be an integral membrane protein. Nodulation of alfalfa by R. meliloti and of clover by R. trifolii was markedly inhibited (approximately 50%) by the addition of antibodies against the hybrid protein to plant growth medium and inoculum.     

Rhizobium common nod genes are required for biofilm formation

In legume nitrogen-fixing symbioses, rhizobial nod genes are obligatory for initiating infection thread formation and root nodule development. Here we show that the common nod genes, nodD1ABC , whose products synthesize core Nod factor, a chitin-like oligomer, are also required for the establishment of the three-dimensional architecture of the biofilm of Sinorhizobium meliloti . Common nod gene mutants form a biofilm that is a monolayer. Moreover, adding Nod Factor antibody to S. meliloti cells inhibits biofilm formation, while chitinase treatment disrupts pre-formed biofilms. These results attest to the involvement of core Nod factor in rhizobial biofilm establishment. However, luteolin, the plant-derived inducer of S. meliloti 's nod genes, is not required for mature biofilm formation, although biofilm establishment is enhanced in the presence of this flavonoid inducer. Because biofilm formation is plant-inducer-independent and because all nodulating rhizobia, both alpha- and beta-proteobacteria have common nod genes, the role of core Nod factor in biofilm formation is likely to be an ancestral and evolutionarily conserved function of these genes.     

Interaction of nod and exo Rhizobium meliloti in alfalfa nodulation

Among the genes of Rhizobium meliloti SU47 that affect nitrogen-fixing symbiosis with alfalfa are nod genes, in which mutations block nodule induction, and exo genes, in which mutations allow nodule formation but block rhizobial exopolysaccharide production as well as nodule invasion and nitrogen fixation. To investigate whether an exo+ bacterium can "help" (that is, reverse the symbiotic defect of) an exo mutant in trans, we have coinoculated alfalfa with pairs of rhizobia of different genotypes. Coinoculant genotypes were chosen so that the exo+ helper strain was nif while the exo "indicator" strain was nif+, and thus any fixation observed was carried out by the exo coinoculant. We find that a nod exo+ coinoculant can help an exo mutant both to invade nodules and to fix nitrogen. However, a nod+ exo+ coinoculant cannot help an exo mutant: Few exo bacteria are recovered from nodules, some bacteroids differentiate into bizarre aberrant forms, and the nodules fail to fix nitrogen. In a triple coinoculation, the effect of nod+ helper supersedes that of nod helper. Implications of these results for interaction of nod and exo gene products are discussed.     

Jasmonic acid stimulates the expression of nod genes in Rhizobium

Jasmonates and salicylic acid are considered to be signal molecules that induce a variety of plant genes involved in wound or defence response, as well as affecting nos promoter activity. In this paper we examined whether these chemicals could also affect nod genes from isogenic rhizobia strains. Isogenic strains contain the Rhizobium leguminosarum nodA promoter fused to the lacZ gene of Escherichia coli and differ only in the source of the regulatory nodD gene. Naringenin, jasmonic acid and methyl jasmonate induced expression of nod genes in strain RBL1284 and salicylic acid showed no activity alone or when used in combination with other compounds; addition of naringenin + jasmonic acid produced a synergistic effect. Results obtained with strain RBL5284 were similar to those for RBL1284 albeit the combination of naringenin with the other compounds markedly inhibited nod gene expression. Whereas RBL5283 responded to naringenin with a strong induction, jasmonic acid, methyl jasmonate or salicylic acid showed no significant responses. The inhibitory effect of salicylic acid on nod gene expression indicates that the induction mechanism of jasmonic acid, methyl jasmonate, N-propyldihydrojasmonate and naringenin is probably different from that of salicylic acid.     

Rhizobia catabolize nod gene-inducing flavonoids via C-ring fission mechanisms.

Gas chromatographic and mass spectrometric analyses of derivatized culture medium extracts were used to identify the products of flavonoid metabolism by rhizobia. A number of Rhizobium species and biovars degraded their nod gene-inducing flavonoids by mechanisms which originated in a cleavage of the C-ring of the molecule and which yielded conserved A- and B-ring products among the metabolites. In contrast, Pseudomonas putida degraded quercetin via an initial fission in its A-ring, and Agrobacterium tumefaciens displayed a nonspecific mode of flavonoid degradation which yielded no conserved A- or B-ring products. When incubated with rhizobia, flavonoids with OH substitutions at the 5 and 7 positions yielded phloroglucinol as the conserved A-ring product, and those with a single OH substitution at the 7 position yielded resorcinol. A wider range of structures was found among the B-ring derivatives, including p-coumaric, p-hydroxybenzoic, protocatechuic, phenylacetic, and caffeic acids. The isoflavonoids genistein and daidzein were also degraded via C-ring fission by Rhizobium fredii and Rhizobium sp. strain NGR234, respectively. Partially characterized aromatic metabolites with potential nod gene-inducing activity were detected among the products of naringenin degradation by Rhizobium leguminosarum bv. viciae. The initial structural modification of nod gene-inducing flavonoids by rhizobia can generate chalcones, whose open C-ring system may have implications for the binding of inducers to the nodD gene product.