Identification of Sinorhizobium meliloti early symbiotic genes by use of a positive functional screen

The soil bacterium Sinorhizobium meliloti establishes nitrogen-fixing symbiosis with its leguminous host plant, alfalfa, following a series of continuous signal exchanges. The complexity of the changes of alfalfa root structures during symbiosis and the amount of S. meliloti genes with unknown functions raised the possibility that more S. meliloti genes may be required for early stages of the symbiosis. A positive functional screen of the entire S. meliloti genome for symbiotic genes was carried out using a modified in vivo expression technology. A group of genes and putative genes were found to be expressed in early stages of the symbiosis, and 23 of them were alfalfa root exudate inducible. These 23 genes were further separated into two groups based on their responses to apigenin, a known nodulation (nod) gene inducer. The group of six genes not inducible by apigenin included the lsrA gene, which is essential for the symbiosis, and the dgkA gene, which is involved in the synthesis of cyclic beta-1,2-glucan required for the S. meliloti-alfalfa symbiosis. In the group of 17 apigenin-inducible genes, most have not been previously characterized in S. meliloti, and none of them belongs to the nod gene family. The identification of this large group of alfalfa root exudate-inducible S. meliloti genes suggests that the interactions in the early stages of the S. meliloti and alfalfa symbiosis could be complex and that further characterization of these genes will lead to a better understanding of the symbiosis.     

Regulation of Syrm and Nodd3 in Rhizobium Meliloti

The early steps of symbiotic nodule formation by Rhizobium on plants require coordinate expression of several nod gene operons, which is accomplished by the activating protein NodD. Three different NodD proteins are encoded by Sym plasmid genes in Rhizobium meliloti, the alfalfa symbiont. NodD1 and NodD2 activate nod operons when Rhizobium is exposed to host plant inducers. The third, NodD3, is an inducer-independent activator of nod operons. We previously observed that nodD3 carried on a multicopy plasmid required another closely linked gene, syrM, for constitutive nod operon expression. Here, we show that syrM activates expression of the nodD3 gene, and that nodD3 activates expression of syrM. The two genes constitute a self-amplifying positive regulatory circuit in both cultured Rhizobium and cells within the symbiotic nodule. We find little effect of plant inducers on the circuit or on expression of nodD3 carried on pSyma. This regulatory circuit may be important for regulation of nod genes within the developing nodule.     

Genetic analysis of the Rhizobium meliloti bacA gene: functional interchangeability with the Escherichia coli sbmA gene and phenotypes of mutants.

The Rhizobium meliloti bacA gene encodes a function that is essential for bacterial differentiation into bacteroids within plant cells in the symbiosis between R. meliloti and alfalfa. An Escherichia coli homolog of BacA, SbmA, is implicated in the uptake of microcin B17, microcin J25 (formerly microcin 25), and bleomycin. When expressed in E. coli with the lacZ promoter, the R. meliloti bacA gene was found to suppress all the known defects of E. coli sbmA mutants, namely, increased resistance to microcin B17, microcin J25, and bleomycin, demonstrating the functional similarity between the two proteins. The R. meliloti bacA386::Tn(pho)A mutant, as well as a newly constructed bacA deletion mutant, was found to show increased resistance to bleomycin. However, it also showed increased resistance to certain aminoglycosides and increased sensitivity to ethanol and detergents, suggesting that the loss of bacA function causes some defect in membrane integrity. The E. coli sbmA gene suppressed all these bacA mutant phenotypes as well as the Fix- phenotype when placed under control of the bacA promoter. Taken together, these results strongly suggest that the BacA and SbmA proteins are functionally similar and thus provide support for our previous hypothesis that BacA may be required for uptake of some compound that plays an important role in bacteroid development. However, the additional phenotypes of bacA mutants identified in this study suggest the alternative possibility that BacA may be needed for membrane integrity, which is likely to be critically important during the early stages of bacterial differentiation within plant cells.     

苜蓿中华根瘤菌042B nodD基因的克隆、序列分析及其表达

苜蓿中华根瘤菌０４２Ｂ是一株能在苜蓿和大豆上结瘤的菌株。将０４２Ｂ的ｎｏｄＳＤ基因克隆到时载体ｐＢＢＲ１ＭＣＳ－５,并在豌豆根瘤菌ＬＲＲ５０４５系统中进行功能分析,发现０４２Ｂ的ＮｏｄＤ蛋白能与大豆的类黄酮化合物ｇｅｎｉｓｔｅｉｎ结合,也怀苜蓿原类黄酮化合物ｌｕｔｅｏｌｉｎ反应。     

Phosphorus-free membrane lipids of Sinorhizobium meliloti are not required for the symbiosis with alfalfa but contribute to increased cell yields under phosphorus-limiting conditions of growth

The microsymbiont of alfalfa, Sinorhizobium meliloti, possesses phosphatidylglycerol, cardiolipin, phosphatidylethanolamine, and phosphatidylcholine as major membrane phospholipids, when grown in the presence of sufficient accessible phosphorus sources. Under phosphate-limiting conditions of growth, S. meliloti replaces its phospholipids by membrane lipids that do not contain any phosphorus in their molecular structure and, in S. meliloti, these phosphorus-free membrane lipids are sulphoquinovosyl diacylglycerols (SL), ornithine-containing lipids (OL), and diacylglyceryl-N,N,N-trimethylhomoserines (DGTS). In earlier work, we demonstrated that neither SL nor OL are required for establishing a nitrogen-fixing root nodule symbiosis with alfalfa. We now report the identification of the two structural genes btaA and btaB from S. meliloti required for DGTS biosynthesis. When the sinorhizobial btaA and btaB genes are expressed in Escherichia coli, they cause the formation of DGTS in this latter organism. A btaA-deficient mutant of S. meliloti is unable to form DGTS but can form nitrogen-fixing root nodules on alfalfa, demonstrating that sinorhizobial DGTS is not required for establishing a successful symbiosis with the host plant. Even a triple mutant of S. meliloti, unable to form any of the phosphorus-free membrane lipids SL, OL, or DGTS is equally competitive for nodule occupancy as the wild type. Only under growth-limiting concentrations of phosphate in culture media did mutants that could form neither OL nor DGTS grow to lesser cell densities.     

Involvement of the syrM and nodD3 genes of Rhizobium meliloti in nod gene activation and in optimal nodulation of the plant host

We identified and sequenced the regulatory syrM and nodD3 genes of Rhizobium meliloti 41. Both genes were shown to contribute to optimal nodulation of alfalfa. In R. meliloti strains carrying syrM and nodD3 on plasmid, the nod genes are expressed constitutively, resulting in host-range extension to siratro. This is due to the presence of multiple syrM copies, suggesting that SyrM participates directly in nod gene activation. NodD3 activates nod genes in conjunction with flavonoids and enhances syrM expression, which is controlled also by its own product, NodD2, and two putative trans-acting factors. nodD3 is regulated by SyrM, NodD1, nodD3, the repressor NoIR, and two putative factors.     

Identification of NolR, a negative transacting factor controlling the nod regulon in Rhizobium meliloti.

In Rhizobium meliloti, expression of the nodulation genes (nod and nol genes) is under both positive and negative controls. These genes are activated by the products of the three related nodD genes, in conjunction with signal molecules from the host plants. We showed that negative regulation is mediated by a repressor protein, binding to the overlapping nodD1 and nodA as well as to the nodD2 promoters. The encoding gene, termed nolR, was identified and cloned from strain 41. By subcloning, deletion and Tn5 mutagenesis, a region of 594 base-pairs was found to be necessary and sufficient for repressor production in strains of R. meliloti lacking the repressor or in Escherichia coli. Sequence analysis revealed that nolR encodes a 13,349 Da protein, which is in agreement with the molecular weight of the NolR protein, determined after purification by affinity chromatography, utilizing long synthetic DNA multimers of the 21 base-pair conserved repressor-binding sequence. Our data suggest that the native NolR binds to the operator site in dimeric form. The NolR contains a helix-turn-helix motif, which shows homology to the DNA-binding sequences of numerous prokaryotic regulatory proteins such as the repressor XylR or the activator NodD and other members of the LysR family. Comparison of the putative DNA-binding helix-turn-helix motifs of a large number of regulatory proteins pointed to a number of novel regularities in this sequence. Hybridizations with an internal nolR fragment showed that sequences homologous to the nolR gene are present in all R. meliloti isolates tested, even in those that do not produce the repressor. In another species, such as Rhizobium leguminosarum, where NodD is autoregulated, however, such sequences were not detected.     

In vitro observation of the molecular interaction between NodD and its inducer naringenin as monitored by fluorescence resonance energy transfer

At initial stages in the Rhizobium legume symbiosis, most nodulation genes are controlled by NodD protein and plant inducers. Some genetic studies and other reports have suggested that NodD may be activated by its direct interaction with plant inducers. However, there has been no molecular evidence of such an inducing interaction. In this paper, we used fluorescence resonance energy transfer technique to see whether such an interaction exists between NodD and its activator, naringenin, in vitro. The tetracysteine motif (Cys-Cys-Pro-Gly-Cys-Cys) was genetically inserted into NodD to label NodD with 4',5'-bis(1,3,2-dithioarsolan-2-yl) fluorescein (FlAsH). Naringenin was labeled with fluorescein by chemical linking. In the fluorescence resonance energy transfer experiments in vitro, the fluorescence intensity of one acceptor, NodD(90R6)-FlAsH, increased by 13%. This suggests that NodD may directly interact with inducer naringenin in vitro and that the reaction centre is likely near hinge region 1 of NodD.     

Bacterial genes induced within the nodule during the Rhizobium–legume symbiosis

During the symbiosis between the bacterium Rhizobium meliloti and plants such as alfalfa, the bacteria elicit the formation of nodules on the roots of host plants. The bacteria infect the nodule, enter the cytoplasm of plant cells and differentiate into a distinct cell type called a bacteroid, which is capable of fixing atmospheric nitrogen. To discover bacterial genes involved in the infection and differentiation stages of symbiosis, we obtained genes expressed at the appropriate time and place in the nodule by identifying promoters that are able to direct expression of the bacA gene, which is required for bacteroid differentiation. We identified 230 fusions that are expressed predominantly in the nodule. Analysis of 23 sequences indicated that only three encode proteins known to be involved in the Rhizobium-legume symbiosis, six encode proteins with homology to proteins not previously associated with symbiosis, and 14 have no significant similarity to proteins of known function. Disruption of a locus that encodes a protein with homology to a cell adhesion molecule led to a defect in the formation of nitrogen-fixing nodules, resulting in an increased number of nitrogen-starved plants. Our isolation of a large number of nodule-expressed genes will help to open the intermediate stages of nodulation to molecular analysis.     

Purification and characterization of the GroESLx chaperonins from the symbiotic X-bacteria in Amoeba proteus.

GroELx and GroESx proteins of symbiotic X-bacteria from Amoeba proteus were overproduced in Escherichia coli transformed with pAJX91 and pUXGPRM, respectively, and their chaperonin functions were assayed. We utilized sigma(70)-dependent specific promoters of groEx in the expression vectors and grew recombinant cells at 37 degrees C to minimize coexpression of host groE of E. coli. For purifying the proteins, we applied the principle of heat stability for GroELx and pI difference for GroESx to minimize copurification with the hosts GroEL and GroES, respectively. After ultracentrifugation in a sucrose density gradient, the yield and purity of GroELx were 56 and 89%, respectively. The yield and purity of GroESx after anion-exchange chromatography were 62 and 91%, respectively. Purified GroELx had an ATPase activity of 53.2 nmol Pi released/min/mg protein at 37 degrees C. The GroESx protein inhibited ATPase activity of GroELx to 60% of the control at a ratio of 1 for GroESx-7mer/GroELx-14mer. GroESLx helped refolding of urea-unfolded rhodanese up to 80% of the native activity at 37 degrees C. By chemical cross-linking analysis, oligomeric properties of GroESx and GroELx were confirmed as GroESx(7) and GroELx(14) in two stacks of GroELx(7). In this study, we developed a method for the purification of GroESLx and demonstrated that their chaperonin function is homologous to GroESL of E. coli.