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.     

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.     

Rhizobium meliloti nodD genes mediate host-specific activation of nodABC.

To differentiate among the roles of the three nodD genes of Rhizobium meliloti 1021, we studied the activation of a nodC-lacZ fusion by each of the three nodD genes in response to root exudates from several R. meliloti host plants and in response to the flavone luteolin. We found (i) that the nodD1 and nodD2 products (NodD1 and NodD2) responded differently to root exudates from a variety of hosts, (ii) that NodD1 but not NodD2 responded to luteolin, (iii) that NodD2 functioned synergistically with NodD1 or NodD3, (iv) that NodD2 interfered with NodD1-mediated activation of nodC-lacZ in response to luteolin, and (v) that a region adjacent to and upstream of nodD2 was required for NodD2-mediated activation of nodC-lacZ. We also studied the ability of each of the three R. meliloti nodD genes to complement nodD mutations in R. trifolii and Rhizobium sp. strain NGR234. We found (i) that nodD1 complemented an R. trifolii nodD mutation but not a Rhizobium sp. strain NGR234 nodD1 mutation and (ii) that R. meliloti nodD2 or nodD3 plus R. meliloti syrM complemented the nodD mutations in both R. trifolii and Rhizobium sp. strain NGR234. Finally, we determined the nucleotide sequence of the R. meliloti nodD2 gene and found that R. meliloti NodD1 and NodD2 are highly homologous except in the C-terminal region. Our results support the hypothesis that R. meliloti utilizes the three copies of nodD to optimize the interaction with each of its legume hosts.     

Role of the nodD and syrM genes in the activation of the regulatory gene nodD3, and of the common and host-specific nod genes of Rhizobium meliloti

To analyse the regulation of the nodulation (nod) genes of Rhizobium meliloti RCR2011 we have isolated lacZ gene fusions to a number of common, host-range and regulatory nod genes, using the mini-Mu-lac bacteriophage transposon MudII1734. Common (nodA, nodC, nod region IIa) and host-range (nodE, nodG, nodH) genes were found to be regulated similarly. They were activated (i) by the regulatory nodD1 gene in the presence of flavones such as chrysoeriol, luteolin and 7,3',4'-trihydroxyflavone, (ii) by nodD2 in the presence of alfalfa root exudate but not with the NodD1-activating flavones, and (iii) by the regulatory genes syrM-nodD3 even in the absence of plant inducers. Thus common and host-range nod genes belong to the same regulon. In contrast to the nodD1 gene, the regulatory nodD3 gene was not expressed constitutively and exhibited a complex regulation. It required syrM for expression, was activated by nodD1 in the presence of luteolin and was positively autoregulated.     

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.     

A two-component regulator mediates population-density-dependent expression of the Bradyrhizobium japonicum nodulation genes

Bradyrhizobium japonicum nod gene expression was previously shown to be population density dependent. Induction of the nod genes is highest at low culture density and repressed at high population densities. This repression involves both NolA and NodD2 and is mediated by an extracellular factor found in B. japonicum conditioned medium. NolA and NodD2 expression is maximal at high population densities. We demonstrate here that a response regulator, encoded by nwsB, is required for the full expression of the B. japonicum nodYABC operon. In addition, NwsB is also required for the population-density-dependent expression of both nolA and nodD2. Expression of nolA and nodD2 in the nwsB mutant remained at a basal level, even at high culture densities. The nwsB defect could be complemented by overexpression of a second response regulator, NodW. Consistent with the fact that NolA and NodD2 repress nod gene expression, the expression of a nodY-lacZ fusion in the nwsB mutant was unaffected by culture density. In plant assays with GUS fusions, nodules infected with the wild type showed no nodY-GUS expression. In contrast, nodY-GUS expression was not repressed in nodules infected with the nwsB mutant. Nodule competition assays between the wild type and the nwsB mutant revealed that the addition of conditioned medium resulted in a competitive advantage for the nwsB mutant.