E. coli Fis Protein Insulates the cbpA Gene from Uncontrolled Transcription

The Escherichia coli curved DNA binding protein A (CbpA) is a poorly characterised nucleoid associated factor and co-chaperone. It is expressed at high levels as cells enter stationary phase. Using genetics, biochemistry, and genomics, we have examined regulation of, and DNA binding by, CbpA. We show that Fis, the dominant growth-phase nucleoid protein, prevents CbpA expression in growing cells. Regulation by Fis involves an unusual “insulation” mechanism. Thus, Fis protects cbpA from the effects of a distal promoter, located in an adjacent gene. In stationary phase, when Fis levels are low, CbpA binds the E. coli chromosome with a preference for the intrinsically curved Ter macrodomain. Disruption of the cbpA gene prompts dramatic changes in DNA topology. Thus, our work identifies a novel role for Fis and incorporates CbpA into the growing network of factors that mediate bacterial chromosome structure.     

Structural Basis of the Regulation of the CbpA Co-chaperone by its Specific Modulator CbpM

CbpA, one of the Escherichia coli DnaJ homologues, acts as a co-chaperone in the DnaK chaperone system. Despite its extensive similarity in domain structure and function to DnaJ, CbpA has a unique and specific regulatory mechanism mediated through the small protein CbpM. Both CbpA and CbpM are highly conserved in bacteria. Earlier studies showed that CbpM interacts with the N-terminal J-domain of CbpA inhibiting its co-chaperone activity but the structural basis of this interaction is not known. Here, we have combined NMR spectroscopy, site-directed mutagenesis and surface plasmon resonance to characterize the CbpA/CbpM interaction at the molecular level. We have determined the solution structure of the CbpA J-domain and mapped the residues that are perturbed upon CbpM binding. The NMR data defined a broad region on helices α2 and α3 as involved in the interactions. Site-directed mutagenesis has been used to further delineate the CbpA J-domain/CbpM interface. We show that the binding sites of CbpM and DnaK on CbpA J-domain overlap, which suggests a competition between DnaK and CbpM for binding to CbpA as a mechanism for CbpA regulation. This study also provides the explanation for the specificity of CbpM for CbpA versus DnaJ, by identifying the key residues for differential binding.     

Alternate promoters direct stress-induced transcription of the Bacillus subtilis clpC operon

clpC ofBacillus subtilis is part of an operon containing six genes. Northern blot analysis suggested that all genes are co-transcribed and encode stress-inducible proteins. Two promoters (P_A and P_B) were mapped upstream of the first gene. P_A resembles promoters recognized by the vegetative RNA polymerase Eσ^A. The other promoter (P_B) was shown to be dependent on σ^B, the general stress σ factor in B. subtilis, suggesting that clpC, a potential chaperone, is expressed in a σ^B-dependent manner. This is the first evidence that σ^B in B, subtilis is involved in controlling the expression of a gene whose counterpart, clpB, is subject to regulation by σ³² in Escherichia coli, indicating a new function of σ^B-dependent general stress proteins. P_B deviated from the consensus sequence of σ^B promoters and was only slightly induced by starvation conditions. Nevertheless, strong induction by heat, ethanol, and salt stress occurred at the σ^B-dependent promoter, whereas the vegetative promoter was only weakly induced under these conditions. However, in a sigB mutant, the σ^A-like promoter became inducible by heat and ethanol stress, completely compensating for sigB deficiency. Only the downstream σ^A-like promoter was induced by certain stress conditions such as hydrogen peroxide or puromycin. These results suggest that novel stress-induction mechanisms are acting at a vegetative promoter. Involvement of additional elements in this mode of induction are discussed.     

A study of the double mutation of dnaJ and cbpA, whose gene products function as molecular chaperones in Escherichia coli.

The CbpA protein is an analog of the DnaJ molecular chaperone of Escherichia coli. To gain insight into the function of CbpA, we examined the nature of a cbpA null mutation with special reference to those of dnaK and dnaJ null mutations. In particular, the cbpA dnaJ double-null mutant was found to exhibit severe defects in cell growth, namely, a very narrow temperature range for growth, a defect in cell division, and susceptibility to killing by carbon starvation. These phenotypes are very similar to those reported for dnaK null mutants but not to those of dnaJ null mutants. Our results are best interpreted by assuming that CbpA is capable of compensating for DnaJ for cell growth and thus that the function(s) of CbpA is closely related to that of DnaJ.     

Back to log phase: σS as a global regulator in the osmotic control of gene expression in Escherichia coli

It is now well established that the σ^S subunit of RNA polymerase is a master regulator in a complex regulatory network that governs the expression of many stationary-phase-inducible genes in Escherichiacoli. In this review, more recent findings will be summarized that demonstrate that σ^S also acts as a global regulator for the osmotic control of gene expression, and actually does so in exponentially growing cells. Thus, many σ^S-dependent genes are induced during entry into stationary phase as well as in response to osmotic upshift. K⁺ glutamate, which accumulates in hyperosmotically stressed cells, seems to specifically stimulate the activity of σ^S-containing RNA polymerase at σ^S-dependent promoters. Moreover, osmotic upshift results in an elevated cellular σ^S level similar to that observed in stationary-phase cells. This increase is the result of a stimulation of rpoS translation as well as an inhibition of the turnover of σ^S, which in exponentially growing non-stressed cells is a highly unstable protein. Whereas the RNA-binding protein HF-I, previously known as a host factor for the replication of phage Qβ RNA, is essential for rpoS translation, the recently discovered response regulator RssB, and ClpXP protease, have been shown to be required for σ^S degradation. The finding that the histone-like protein H-NS is also involved in the control of rpoS translation and σ^S turnover, sheds new light on the function of this protein in osmoregulation. Finally, preliminary evidence suggests that additional stresses, such as heat shock and acid shock, also result in increased cellular σ^S levels in exponentially growing cells. Taken together, σ^S function is clearly not confined to stationary phase. Rather, σ^S may be regarded as a sigma factor associated with general stress conditions.     

CbpA, a DnaJ homolog, is a DnaK co-chaperone, and its activity is modulated by CbpM

The DnaK chaperone system, consisting of DnaK, DnaJ, and GrpE, remodels and refolds proteins during both normal growth and stress conditions. CbpA, one of several DnaJ analogs in Escherichia coli, is known to function as a multicopy suppressor for dnaJ mutations and to bind nonspecifically to DNA and preferentially to curved DNA. We found that CbpA functions as a DnaJ-like co-chaperone in vitro. CbpA acted in an ATP-dependent reaction with DnaK and GrpE to remodel inactive dimers of plasmid P1 RepA into monomers active in P1 DNA binding. Additionally, CbpA participated with DnaK in an ATP-dependent reaction to prevent aggregation of denatured rhodanese. The cbpA gene is in an operon with an open reading frame, yccD, which encodes a protein that has some homology to DafA of Thermus thermophilus. DafA is a protein required for the assembly of ring-like particles that contain trimers each of T. thermophilus DnaK, DnaJ, and DafA. The E. coli YccD was isolated because of its potential functional relationship to CbpA. Purified YccD specifically inhibited both the co-chaperone activity and the DNA binding activity of CbpA, suggesting that YccD modulates the activity of CbpA. We named the product of the yccD gene CbpM for "CbpA modulator."     

The rpoD gene functions as a multicopy suppressor for mutations in the chaperones, CbpA, DnaJ and DnaK, in Escherichia coli

Abstract The CbpA protein is an analog of the DnaJ molecular chaperone of Escherichia coli . The dnaJ ⁻ cbpA ⁻ double-null mutant exhibits severe defects in cell growth, namely, a very narrow temperature range for growth. To gain insight into the functions of CbpA as well as DnaJ, we isolated a multicopy suppressor gene that permits this dnaJ ⁻ cbpA ⁻~ mutant to grow normally at low temperatures. The suppressor gene was identified as rpoD , the gene that encodes the major σ ⁷⁰. The biological implications of this finding are examined and discussed.     

CbpA: a novel surface exposed adhesin of Clostridium difficile targeting human collagen

Clostridium difficile is the leading cause of antibiotic‐associated diarrhoea and pseudomembranous colitis. While the role of toxins in pathogenesis has been extensively described, the contribution of surface determinants to intestinal colonization is still poorly understood. We focused our study on a novel member of the MSCRAMM family, named CbpA (C ollagen b inding p rotein A ), for its adhesive properties towards collagen. We demonstrate that CbpA, which carries an LPXTG‐like cell wall anchoring domain, is expressed on the bacterial surface of C. difficile and that the recombinant protein binds at high affinity to collagens I and V (apparent K_d in the order of 10^?9 M). These findings were validated by confocal microscopy studies showing the colocalization of the protein with type I and V collagen fibres produced by human fibroblasts and mouse intestinal tissues. However, the collagen binding activity of the wild‐type C. difficile 630 strain was indistinguishable to the cbpA knock‐out strain. To overcome this apparent clostridial adherence redundancy, we engineered a Lactococcus lactis strain for the heterologous expression of CbpA. When exposed on the surface of L. lactis, CbpA significantly enhances the ability of the bacterium to interact with collagen and to adhere to ECM‐producing cells. The binding activity of L. lactis–CbpA strain was prevented by an antiserum raised against CbpA, demonstrating the specificity of the interaction. These results suggest that CbpA is a newsurface‐exposed adhesin contributing to the C. difficile interaction with the host.