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.     

The 41 carboxy-terminal residues of the miniF plasmid CcdA protein are sufficient to antagonize the killer activity of the CcdB protein

Summary The ccd operon of plasmid F encodes two genes, ccdA and ccdB, which contribute to the high stability of the plasmid by post-segregational killing of plasmid-free bacteria. The CcdB protein is lethal to bacteria and the CcdA protein is an antagonist of this lethal action. A 520 by fragment containing the terminal part of the ccdA gene and the entire ccdB gene of plasmid F was cloned downstream of the tac promoter. Although the CcdB protein was expressed from this fragment, no killing of host bacteria was observed. We found that the absence of killing was due to the presence of a small polypeptide, CcdA41, composed of the 41 C-terminal residues of the CcdA protein. This polypeptide has retained the ability to regulate negatively the lethal activity of the CcdB protein.     

Structural and physiological studies of the Escherichia coli histidine operon inserted into plasmid vectors

A fragment of deoxyribonucleic acid 5,300 base paris long and containing the promoter-proximal portion of the histidine operon of Escherichia coli K-12, has been cloned in plasmid pBR313 (plasmids pCB2 and pCB3). Restriction mapping, partial nucleotide sequencing, and studies on functional expression in vivo and on protein synthesis in minicells have shown that the fragment contains the regulatory region of the operon, the hisG, hisD genes, and part of the hisC gene. Another plasmid (pCB5) contained the hisG gene and part of the hisD gene. Expression of the hisG gene in the latter plasmid was under control of the tetracycline promoter of the pBR313 plasmid. The in vivo expression of the two groups of plasmids described above, as well as their effect on the expression of the histidine genes not carried by the plasmids but present on the host chromosome, has been studied. The presence of multiple copies of pCB2 or pCB3, but not of pCB5, prevented derepression of the chromosomal histidine operon. Possible interpretations of this phenomenon are discussed.     

Evidence for autoregulation of camR, which encodes a repressor for the cytochrome P-450cam hydroxylase operon on the Pseudomonas putida CAM plasmid.

The regulatory gene camR on the CAM plasmid of Pseudomonas putida (ATCC 17453) negatively controls expression of the cytochrome P-450cam hydroxylase operon (camDCAB) for the camphor degradation pathway and is oriented in a direction opposite to that of the camDCAB operon. In this study, we examined expression of the camR gene by monitoring the beta-galactosidase activity of camR-lacZ translational fusions in P. putida camR and camR+ strains. We found that the camR gene was autogenously regulated by its own product, CamR. To search for an operator site of the camR gene, a cam repressor (CamR)-overproducing plasmid, pHAOV1, was constructed by placing the camR gene under the control of a pL promoter. The translational initiation codon of CamR was changed by site-directed mutagenesis from GTG to ATG to improve translation efficiency. Judging from sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, the CamR protein was expressed up to about 10% of the soluble protein of CamR-overproducing Escherichia coli JM83/pHAOV1 cells. Results of DNase I footprinting assays using the cell lysate indicated that the CamR repressor covered a single region between the camR gene and the camDCAB operon. Our findings also suggest that the camR gene autogenously regulates its own expression by binding of the gene product, CamR, to the operator, which also serves as an operator of the camDCAB operon.     

Construction and Initial Characterization of Escherichia coli Strains with Few or No Intact Chromosomal rRNA Operons

The Escherichia coli genome carries seven rRNA (rrn) operons, each containing three rRNA genes. The presence of multiple operons has been an obstacle to many studies of rRNA because the effect of mutations in one operon is diluted by the six remaining wild-type copies. To create a tool useful for manipulating rRNA, we sequentially inactivated from one to all seven of these operons with deletions spanning the 16S and 23S rRNA genes. In the final strain, carrying no intact rRNA operon on the chromosome, rRNA molecules were expressed from a multicopy plasmid containing a single rRNA operon (prrn). Characterization of these rrn deletion strains revealed that deletion of two operons was required to observe a reduction in the growth rate and rRNA/protein ratio. When the number of deletions was extended from three to six, the decrease in the growth rate was slightly more than the decrease in the rRNA/protein ratio, suggesting that ribosome efficiency was reduced. This reduction was most pronounced in the Delta7 prrn strain, in which the growth rate, unlike the rRNA/protein ratio, was not completely restored to wild-type levels by a cloned rRNA operon. The decreases in growth rate and rRNA/protein ratio were surprisingly moderate in the rrn deletion strains; the presence of even a single operon on the chromosome was able to produce as much as 56% of wild-type levels of rRNA. We discuss possible applications of these strains in rRNA studies.     

Commingling regulatory systems following acquisition of virulence plasmids by Bacillus anthracis

The conversion of a bacterium from a non-pathogenic to a pathogenic existence is usually associated with the acquisition of virulence factors, the genes of which gain entry through bacteriophage infection, transposable elements or plasmid transfer. Pathogenesis research is mostly focused on how these factors enable the bacterium to infect the host or evade the repertoire of host defenses. Less effort is expended on understanding how the invading genes are affected by the complex regulatory circuits of the bacterium and how virulence is the result of converting these regulatory circuits to make them complicit with pathogenesis. An example of such a conversion is seen in Bacillus anthracis, and how acquired plasmid regulatory functions affect the activity of the regulatory processes of the bacterium, and vice versa, is now being revealed.