SummaryWe identified the stress-induced ClpP of Listeria monocytogenes and demonstrated its crucial role in intracellular survival of this pathogen. ClpP is a 21.6 kDa protein belonging to a family of proteases highly conserved in prokaryotes and eukaryotes. A clpP-deleted mutant enabled us to demonstrate that ClpP is involved in proteolysis and is required for growth under stress conditions. Intramacrophage survival of this mutant was strongly restricted, thus resulting in loss of virulence for the mouse. The activity of listeriolysin O, a major virulence factor implicated in bacterial escape from phagosomes of macrophages, was much reduced in the clpP mutant under stress conditions. Direct evidence for the role of ClpP in the intracellular parasitism was obtained by showing that virulence and haemolytic activity were fully restored by complementation of the mutant. These results suggest that ClpP is involved in the rapid adaptive response of intracellular pathogens during the infectious process.
SummaryUnder stress conditions, the facultative intracellular pathogen Listeria monocytogenes produces a ClpC ATPase, which is a general stress protein encoded by clpC and belonging to the HSP-100/Clp family. A ClpC-deficient mutant was obtained by gene disruption in strain LO28, which became highly susceptible to stress conditions in vitro. Intracellular growth of this mutant was restricted within macrophages, one of the major target cells of L. monocytogenes, during the infectious process. A quantitative electron microscope study showed that, contrary to wild-type bacteria that rapidly gain access to the cytoplasm of macrophages, mutant bacteria remained confined to membrane-bound phagosomes. Only a few mutant bacteria disrupted the phagosome membrane after 4 h of incubation, then polymerized actin filaments and multiplied within the cytoplasm. The ClpC ATPase, therefore, promotes early bacterial escape from the phagosome of macrophages, thus enhancing intracellular survival. The ClpC ATPase was produced in vivo during experimental infection by wild-type bacteria. The virulence of the ClpC-deficient mutant was severely attenuated in mice, with a three-log decrease in its 50% lethal dose compared with wild-type bacteria. Bacterial growth of mutant bacteria was strongly restricted in organs, presumably because of an impairment of intracellular survival in host tissues. Our results provide evidence that a general stress protein is required for the virulence of L. monocytogenes, which behaves as a virulence factor promoting intracellular survival of this pathogen.
Stress proteins play an important role in virulence, yet little is known about the regulation of stress response in pathogens. In the facultative intracellular pathogen Listeria monocytogenes, the Clp ATPases, including ClpC, ClpP and ClpE, are required for stress survival and intracellular growth. The first gene of the clpC operon of L. monocytogenes encodes a homologue of the Bacillus subtilis CtsR repressor of stress response genes. An L. monocytogenes ctsR‐deleted mutant displayed enhanced survival under stress conditions (growth in the presence of 2% NaCl or at 42°C), but its level of virulence in the mouse was not affected. The virulence of a wild‐type strain constitutively expressing CtsR is significantly attenuated, presumably because of repression of the stress response. Regulation of the L. monocytogenes clpC, clpP and clpE genes was investigated using transcriptional fusions in B. subtilis as a host. The L. monocytogenes ctsR gene was placed under the control of an inducible promoter, and regulation by CtsR and heat shock was demonstrated in vivo in B. subtilis. The purified CtsR protein of L. monocytogenes binds specifically to the clpC, clpP and clpE regulatory regions, and the extent of the CtsR binding sites was defined by DNase I footprinting. Our results demonstrate that this human pathogen possesses a CtsR regulon controlling class III heat shock genes, strikingly similar to that of the saprophyte B. subtilis. This is the first description of a stress response regulatory gene in a pathogen.
SummaryWe identified, in the facultative intracellular pathogen Listeria monocytogenes, a previously unknown Clp ATPase, unique among the HSP100 proteins because of the presence of a short N-terminal region with a potential zinc finger motif. This protein of 726 amino acids is highly homologous to ClpE of Bacillus subtilis, and is a member of a new subfamily of HSP100/ Clp ATPases. The clpE gene is transcribed as a monocistronic mRNA from a typical consensus A promoter. clpE is not stimulated by various stresses, but is upregulated in a clpC mutant. This is the first example of cross-regulation between Clp ATPases. By constructing a clpE mutant of L. monocytogenes, we found that ClpE is required for prolonged survival at 42ЊC and is involved in the virulence of this pathogen. A double mutant deficient in both ClpE and ClpC was avirulent in a mouse model and completely eliminated in the liver. Electron microscopy studies did not show any morphological alterations in clpE or clpC mutants. In the clpE-clpC double mutant, however, cell division was affected, indicating that ClpE acts synergistically with ClpC in cell septation. These results show that the Clp chaperones play a crucial role in both cell division and virulence of L. monocytogenes.
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