DegP periplasmic protease a new anti-infective target and an...

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Reexamination Certificate

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C435S220000

Reexamination Certificate

active

06306619

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The DegP (HtrA) protease is a multifunctional protein essential for the removal of misfolded and aggregated proteins in the periplasm. DegP has been shown to be essential for virulence in several Gram negative pathogens. Only three natural targets for DegP have been described: colicin A lysis protein (Cal), pilin subunits (K88, K99, Pap) and recently HMW1 and HMW2 from
Hemophilus influenzae.
In vitro, DegP has shown weak protease activity on casein and several other non-native substrates. The present inventors have identified the major pilin subunit of the Pap pilus, PapA, as a native DegP substrate and demonstrated binding and proteolysis of this substrate in vitro. Using an NH
2
-terminal affinity tag the present inventors have purified PapA away from the PapD chaperone, in the presence of denaturant, to use as a proteolysis substrate. This finding will allow the identification of the DegP recognition and cleavage sites in substrate proteins, and further, allow the design of small molecule inhibitors of protease function.
2. Description of the Related Art
Proteolysis of misfolded and denatured proteins in the bacterial cytoplasm and periplasm is a crucial housekeeping function and critical for cell viability (Pallen, M. J. and Wren, B. W. (1997)
Mol. Microbiol.
26,209-221; Miller, C. G. (1996) in
Escherichia coli and Salmonella Cellular and Molecular Biology
(Neidhardt, F. C., eds) pp. 938-954, ASM Press Washington D.C.). It is becoming increasingly clear that the proteolytic machinery is also an essential component for bacterial pathogenesis (Pallen & Wren, supra). Recently, scientists have uncovered a regulatory system, CpxA/CpxR, that responds to the changing environment of the periplasm; recruiting proteases, chaperones and “foldases” to assist in managing the state of affairs in this bacterial compartment (see, e.g., Danese, P. N., et al. (1995)
Genes and Development
9,387-398; Danese, P. N. and Silhavy, T. J. (1997)
Genes Dev.
11, 1183-1193). As the host often presents a hostile environment to the invading organism it is suggested that the CpxA/CpxR regulatory circuit is “tripped” upon engaging the host defenses. One of the most important proteases in the periplasm, the DegP/HtrA serine protease (Pallen & Wren, supra) is a member of the CpxA/CpxR regulon (Danese, P. N., et aL (1995), supra; Danese and Silhavy (1997) supra). This protein is also a key player in pathogenesis in Salmonella, Brucella, and Yersinia (Pallen & Wren, supra). Specifically, DegP has been shown to be a virulence determinant in
Salmonella typhimurium, Brucella abortus
and
Yersinia enterocolitica.
According to the current model of DegP function in pathogenesis, DegP acts to remove misfolded proteins and protein aggregates that result from exposure to reactive oxygen intermediates in the host. In the absence of functional DegP, these protein aggregates compromise the pathogenic process (Pallen & Wren, supra).
The DegP (degradation) nomenclature refers to the initial mapping of a mutation in
E. coli
that allowed the accumulation of unstable fusion proteins in the periplasm (Strauch, K. L., Johnson, K. and Beckwith, J. (1989)
J. Bacteriol.
171,2689-2696; Strauch, K. L. and Beckwith, J. (1988)
Proc. Natl. Acad. Sci. U.S.A.
85,1576-1580). The HtrA (heat shock regulated) designation indicates that a transposon insertion in the same gene resulted in a heat sensitive growth phenotype (Lipinska, B., Sharma, S. and Georgopoulos (1988)
Nucleic Acids Research
16,10053-10066). Lastly, DegP was also designated protease Do, again as a mutation that conferred a heat sensitive phenotype in
E. coli
(Seol, J. H., et al. (1991)
Biochemical and Biophysical Research Communications
176,730-736). DegP exhibited functional protease activity in in vitro assays using casein as a substrate, although its activity on this substrate was weak (Lipinska, B., Zylicz, M. and Georgopoulos, C. (1990)
J. Bacteriol
172,1791-1797). Lipinska et al. demonstrated that the activity on casein was inhibitable by DFP and not by any other known protease inhibitors, suggesting that DegP is a serine protease. Site directed mutagenesis at serine 210 and histidine 105, two components of the serine protease catalytic triad, compromised DegP function in vitro and in vivo; i.e. strains carrying serine 210 or histidine 105 mutant derivatives were sensitive for growth at elevated temperatures (Skorko-Glonek, J., et al. (1995) Gene 163,47-52). The preferred substrate for DegP appears to be proteins that are globally or transiently denatured; suggesting that the role in vivo is to clear misfolded or denatured proteins from the periplasm (Kolmar, H., Waller, P. R. H. and Sauer, R. T. (1996)
J. Bacteriol
178,5925-5929). In support of this finding, Laskowa et al. (Laskowska, E., et al. (1996)
Mol Microbiol.
22,555-571) demonstrated in vitro that purified DegP protein would degrade thermally aggregated proteins fractionated from
E. coli
extracts and that the DnaJ chaperone would antagonize DegP degradation; i.e. the chaperone would aid in refolding the proteins such that they were no longer targets for degradation by DegP.
In addition to its weak protease activity, DegP/HtrA has been shown to be a virulence factor for several pathogenic organisms. In
Salmonella typhimurium,
htrA nulls were found to be avirulent and more susceptible to oxidative stress (Johnson, K., et al. (1991)
Mol. Microbiol.
5,401-407). The authors of this study suggest that the htrA mutants are less able to withstand oxidative killing within the macrophage. An htrA lesion was found to be useful in attenuating
Salmonella typhi
for implementation as a vaccine strain. Similarly,
Brucella abortus
and
Brucella melentensis
htrA null mutants were attenuated for virulence in goats and found to be significantly more sensitive to oxidative killing by cultured neutrophils in vitro (Elzer, P. H., et al. (1996)
Research in Veterinary Science
60,48-50; Elzer, P. H., et al. (1 996)
Infection and Immunity
64,4838-4841; Phillips, R. W., et al. (1997)
Research in Veterinary Science
63,165-167). An isogenic pair, wild-type and htrA null mutant, in
Yersinia enterocolitica
were created and tested in a mouse yersiniosis model. HtrA was found to be essential for virulence and the mutant strain was more sensitive to oxidative stress (Li, S.-R., et al. (1996)
Infection and Immunity
64,2088-2094). Finally, Boucher et al. ((1996)
J. Bacteriol.
178,511-523) recently demonstrated that
Pseudomonas aeruginosa
conversion to mucoidy, the so-called CF phenotype involves two HtrA homologs. DegP homologs have been found in
Streptococcus pneumoniae
(Gasc, A-M et al. (1998)
Microbiology
144:433-439),
Streptococcus pyogenes,
and
Staphylococcus aureus.
All three homologs share the catalytic triad of the
E. coli
DegP protein.
The first identified in vivo target for DegP was colicin A lysis protein (Cal) (Cavard, D., Lazdunski, C. and Howard, S. P. (1989)
J. Bacteriol.
171,6316-6322). DegP was found to degrade the acylated precusor form of Cal into two fragments. Mature Cal also accumulated to higher levels in degP mutant strains (Cavard et al.(1989), supra). A second family of DegP targets was identified as bacterial pilins. The K88 and K99 pilin subunits were found to accumulate to higher levels in degP mutant strains (Bakker, D., et a. (1991)
Mol. Microbiol.
5,875-886). A more detailed study of this phenomenon demonstrated that P pilins, specifically PapA, are substrates for the DegP protease (Jones, C. H., et aL (1997)
EMBO J.
16,6394-6406). More recently the
H. influenzae
non-pilus adhesin proteins HMW1 and HMW2 were found to be in vivo substrates for DegP (St. Geme III, J. W. and Grass, S. (1998)
Mol. Microbiol
27,617-630).
The DegP/HtrA sequence was published in 1988 (Lipinska, Sharma, & Georgopoulos, supra). HtrA is one of several dozen proteases in
E coli
and is known to have homologs in cyanobacteria, mycobacteria, yeast and man (Pallen & Wren, supra). There are also two homologs of DegP:

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