Identification of a helix-turn-helix motif of Bacillus thermoglucosidasius HrcA essential for binding to the CIRCE element and thermostability of the HrcA-CIRCE complex,indicating a role as a thermosensor

In the heat shock response of bacillary cells, HrcA repressor proteins negatively control the expression of the major heat shock genes, the groE and dnaK operons, by binding the CIRCE (controlling inverted repeat of chaperone expression) element. Studies on two critical but yet unresolved issues related to the structure and function of HrcA were performed using mainly the HrcA from the obligate thermophile Bacillus thermoglucosidasius KP1006. These two critical issues are (i) identifying the region at which HrcA binds to the CIRCE element and (ii) determining whether HrcA can play the role of a thermosensor. We identified the position of a helix-turn-helix (HTH) motif in B. thermoglucosidasius HrcA, which is typical of DNA-binding proteins, and indicated that two residues in the HTH motif are crucial for the binding of HrcA to the CIRCE element. Furthermore, we compared the thermostabilities of the HrcA-CIRCE complexes derived from Bacillus subtilis and B. thermoglucosidasius, which grow at vastly different ranges of temperature. The thermostability profiles of their HrcA-CIRCE complexes were quite consistent with the difference in the growth temperatures of B. thermoglucosidasius and B. subtilis and, thus, suggested that HrcA can function as a thermosensor to detect temperature changes in cells.     

Renaturation of Bacillus thermoglucosidasius HrcA repressor by DNA and thermostability of the HrcA-DNA complex in vitro

HrcA, a negative control repressor for chaperone expression from the obligate thermophile Bacillus thermoglucosidasius KP1006, was purified in a His-tagged form in the presence of 6 M urea but hardly renatured to an intact state due to extreme insolubility. Renaturation trials revealed that the addition of DNA to purified B. thermoglucosidasius HrcA can result in solubilization of HrcA free from the denaturing agent urea. Results from band shift and light scattering assays provided three new findings: (i) any species of DNA can serve to solubilize B. thermoglucosidasius HrcA, but DNA containing the CIRCE (controlling inverted repeat of chaperone expression) element is far more effective than other nonspecific DNA; (ii) B. thermoglucosidasius HrcA renatured with nonspecific DNA bound the CIRCE element in the molecular ratio of 2.6:1; and (iii) B. thermoglucosidasius HrcA binding to the CIRCE element was stable at below 50 degrees C whereas the complex was rapidly denatured at 70 degrees C, suggesting that the breakdown of HrcA is induced by heat stress and HrcA may act as a thermosensor to affect the expression of heat shock regulatory genes. These results will help to determine the nature of HrcA protein molecules.     

Mycobacteria contain two groEL genes: the second Mycobacterium leprae groEL gene is arranged in an operon with groES

In contrast to other bacterial species, mycobacteria were thus far considered to contain groEL and groES genes that are present on separate loci on their chromosomes, Here, by screening a Mycobacterium leprae lambda gt11 expression library with serum from an Ethiopian lepromatous leprosy patient, two DNA clones were isolated that contain a groEL gene arranged in an operon with a groES gene. The complete DNA sequence of this groESL operon was determined. The predicted amino acid sequences of the GroES and GroEL proteins encoded by this operon are 85-90% and 59-61% homologous to the sequences from previously characterized mycobacterial GroES and GroEL proteins. Southern blotting analyses with M. leprae groES- and groEL-specific probes demonstrate that similar groESL homologous DNA is present in the genomes of other mycobacteria, including Mycobacterium tuberculosis. This strongly suggests that mycobacteria contain a groESL operon in addition to a separately arranged second groEL gene. Using five T-cell clones from two leprosy patients as probes, expression of the M. leprae GroES protein in Escherichia coli after heat shock was demonstrated. Four of these clones recognized the same M. leprae-specific GroES-derived peptide in a DR2-restricted fashion. No expression of the groEL gene from this operon was detected in E. coli after heat shock, as tested with a panel of T-cell clones and monoclonal antibodies reactive to previously described GroEL proteins of mycobacteria.     

Differential regulation of groESL operon expression in response to heat and light in Anabaena

The HrcA protein is known to bind the cis-element CIRCE and repress expression of hsp60 in certain bacteria. However, recent data from cyanobacteria have seriously questioned the HrcA/CIRCE interaction paradigm. A hrcA null mutant showed constitutive expression of Hsp60 proteins [GroEL/Cpn60(GroEL2)], and an unexpected further increase in GroEL during temperature upshift, suggesting involvement of regulatory mechanisms other than HrcA in groESL expression in Anabaena. The negative regulation of both hsp60 genes [groEL and cpn60 (groEL2)] at CIRCE element was established by: (1) constitutive expression of Green Fluorescent Protein gene, tagged to Anabaena hsp60 promoters, in E. coli, and its repression upon co-expression of Anabaena HrcA and (2) specific binding of Anabaena HrcA to the CIRCE element. Deletion analysis of other cis-elements further distinguished (a) a photo-regulation by the K-box and (b) thermoregulation from a novel H-box, over and above the negative regulation by HrcA at CIRCE.     

HrcA is a negative regulator of the dnaK and groESL operons of Streptococcus pyogenes

The genome of Streptococcus pyogenes, an important human pathogen, encodes homologs of the principal bacterial heat shock proteins DnaK and GroES, -EL, as well as HrcA, a negative regulator of dnaK and groESL expression in other Gram-positive bacteria. Using nuclease protection assays to measure dnaK/groESL mRNA abundance and a "non-polar" insertion to disrupt hrcA, we demonstrate that heat shock triggers a 4- to 8-fold increase in dnaK and groESL-specific mRNAs within 5 min of the temperature shift and that HrcA is a negative regulator of S. pyogenes dnaK/groESL mRNA abundance in unstressed S. pyogenes. Although the loss of HrcA elevated dnaK and groESL mRNA levels under non-heat shock conditions, the relative abundance of these RNAs increased further in heat shocked S. pyogenes, suggesting an additional element contributing to their synthesis or stability.