Abstract
The serralysin family of bacterial metalloproteases is associated with virulence in multiple modes of infection. These extracellular proteases are members of the Repeats-in-ToXin (RTX) family of toxins and virulence factors, which mediated virulence in E. coli, B. pertussis, and P. aeruginosa, as well as other animal and plant pathogens. The serralysin proteases are structurally dynamic and their folding is regulated by calcium binding to a C-terminal domain that defines the RTX family of proteins. Previous studies have suggested that interactions between N-terminal sequences and this C-terminal domain are important for the high thermal and chemical stabilities of the RTX proteases. Extending from this, stabilization of these interactions in the native structure may lead to hyperstabilization of the folded protein. To test this hypothesis, cysteine pairs were introduced into the N-terminal helix and the RTX domain and protease folding and activity were assessed. Under stringent pH and temperature conditions, the disulfide-bonded mutant showed increased protease activity and stability. This activity was dependent on the redox environment of the refolding reaction and could be blocked by selective modification of the cysteine residues before protease refolding. These data demonstrate that the thermal and chemical stability of these proteases is, in part, mediated by binding between the RTX domain and the N-terminal helix and demonstrate that stabilization of this interaction can further stabilize the active protease, leading to additional pH and thermal tolerance.
Highlights
Serratia marcescens is an opportunistic human pathogen associated with multiple modes of infection, including pneumonia, empyema, urinary tract infection, corneal keratitis, meningitis, endocarditis, and septic arthritis.[1]
Previous work on AprA from Pseudomonas aeruginosa and CyaA from Bordetella pertussis demonstrated that Ca2+ induces the folding of RTX domains, which can nucleate the folding of other protein domains.[13,17,28]
Based on previous studies evaluating the Ca2+-associated regulation of RTX protease structure and function, we sought to further define the physical basis of the RTX protease’s high stability and engineer increased stability
Summary
Serratia marcescens is an opportunistic human pathogen associated with multiple modes of infection, including pneumonia, empyema, urinary tract infection, corneal keratitis, meningitis, endocarditis, and septic arthritis.[1] As with other pathogens, S. marcescens secretes multiple virulence factors to promote adherence, alter the host immune and clearance responses, and to facilitate infection. These include extracellular nucleases, chitinases, proteases and lipases and contribute to host immune responses and tissue damage.[1,2] Previous studies have shown that the serralysin metalloprotease, PrtS, is one of the most abundant extracellular virulence factors produced by S. marcescens.[3,4] Expression of serralysin is associated with corneal keratitis and pneumonia.[5,6,7].
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