Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0023241 (Legionella)
6,990 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The extracellular metalloprotease of Legionella pneumophila, also called tissue-destructive protease or major secretory protein, has been proposed as one of the virulence factors of this organism. Considering the decisive role played by the phagocytic cells in host defense against Legionella infection, we investigated the effect of this protease on the function of human neutrophils and monocytes. L. pneumophila protease inhibited the chemotactic response of neutrophils to F-Met-Leu-Phe and zymosan-activated serum in a concentration-dependent and heat-labile manner. A direct effect of the protease on the chemotactic activity of neutrophils was demonstrated by the continued inhibition of neutrophil chemotaxis when the protease was removed following pre-incubation of the cells. In contrast, the enzyme had no effect on monocyte chemotaxis. The protease inhibited, also in a concentration-dependent and heat-labile manner, the binding of F-Met-Leu-Phe to both cell types. Neutrophil and monocyte oxidative burst response, as measured by superoxide release and chemiluminescence response, was not significantly affected by the enzyme. A slight enhancement of PMA-stimulated superoxide release was induced by the protease in both cell types. Lastly, the protease inhibited the killing of Listeria monocytogenes by neutrophils or monocytes. Inhibition of Listeria killing was concentration-dependent, heat-labile, and did not require the presence of the enzyme in the bactericidal assay. The inhibitory activity of L. pneumophila protease on neutrophil chemotaxis and on the listericidal activity of human neutrophils and monocytes demonstrated in this study provides evidence for a role of this enzyme in the pathogenesis of Legionnaires' disease.
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PMID:Effect of Legionella pneumophila cytotoxic protease on human neutrophil and monocyte function. 158 5

In a previous study, we demonstrated that immunization of guinea pigs with the major secretory protein (MSP) of Legionella pneumophila, serogroup 1 induced humoral and cell-mediated immune responses to MSP and protective immunity against lethal aerosol challenge with this serogroup of L. pneumophila. Although serogroup 1 L. pneumophila cause most cases of Legionnaires' disease, other serogroups of L. pneumophila and species of Legionella cause many cases. In this study, we have examined if immunization with MSP induces humoral and cell-mediated immune responses and protective immunity across different serogroups of L. pneumophila and species of Legionella. By immunoblot analysis, MSP from L. pneumophila serogroup 1 (Lp1 MSP), L. pneumophila serogroup 6 (Lp6 MSP), and Legionella bozemanii (Lb MSP) shared common epitopes recognized by guinea pig anti-Lp1 MSP antiserum. These MSP molecules, however, were not identical as they had different apparent m.w. Immunization of guinea pigs with MSP induced strong cell-mediated immune responses across the different serogroups and species, as indicated by splenic lymphocyte proliferation and cutaneous delayed-type hypersensitivity in response to both homologous and heterologous MSP. Immunization with MSP induced strong protective immunity across two serogroups of L. pneumophila; overall, 9 survived aerosol challenge with L. pneumophila serogroup 1 compared to 0 of 12 (0%) sham-immunized control animals (p = 3 x 10(-4), Cochran-Mantel-Haenzel chi 2 statistic for pooled data). Immunization with MSP also induced protective immunity across species of Legionella but protection was species-specific. Whereas immunization with Lb MSP induced protective immunity against L. pneumophila, neither immunization with Lp1 MSP nor immunization with Lb MSP induced protective immunity against L. bozemanii, which produces MSP. Not surprisingly, immunization with MSP did not induce protective immunity against MSP-negative Legionella micdadei. In the case of both L. bozemanii and L. micdadei, immunization with a sublethal dose did confer protective immunity to aerosol challenge indicating that these species do contain immunoprotective components. This study demonstrates that immunization with MSP induces humoral and cell-mediated immune responses across different serogroups of L. pneumophila and species of Legionella, but that the capacity of MSP immunization to induce protective immunity is species-specific. Nevertheless, an MSP vaccine has the potential to induce protective immunity against the great majority of cases of Legionnaires' disease.
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PMID:Vaccination with the major secretory protein of Legionella induces humoral and cell-mediated immune responses and protective immunity across different serogroups of Legionella pneumophila and different species of Legionella. 171 Oct 78

We have examined the capacity of Legionella pneumophila membranes to induce cell-mediated immune responses and protective immunity in a guinea pig model of Legionnaires' disease. Guinea pigs immunized by aerosol with L. pneumophila membranes developed strong cell-mediated immune responses to L. pneumophila membranes as demonstrated by cutaneous delayed-type hypersensitivity and in vitro splenic lymphocyte proliferation. Guinea pigs immunized by aerosol or by subcutaneous inoculation with L. pneumophila membranes developed strong protective immunity against lethal aerosol challenge with L. pneumophila. Overall, in six independent experiments, 39 of 49 (80%) guinea pigs immunized with L. pneumophila membranes survived challenge compared with 2 of 40 (5%) sham-immunized controls (P = 2 x 10(-13). In contrast, guinea pigs immunized by aerosol with formalin-killed L. pneumophila did not develop either a strong cell-mediated immune response to L. pneumophila antigens or protective immunity to lethal aerosol challenge. The capacity of L. pneumophila membranes to induce protective immunity was independent of the major secretory protein of L. pneumophila, which we previously demonstrated is an immunoprotective molecule. Purified L. pneumophila membranes did not contain detectable major secretory protein (MSP) on immunoblots; immunization of guinea pigs with L. pneumophila membranes did not induce anti-MSP antibody; and guinea pigs developed comparable protective immunity after immunization with membranes from either an L. pneumophila strain that secretes the major secretory protein or an isogenic mutant that does not. This study demonstrates that (a) immunization with L. pneumophila membranes but not formalin-killed L. pneumophila induces strong cell-mediated immune responses and protective immunity, (b) L. pneumophila membranes contain immunoprotective molecules distinct from the major secretory protein of L. pneumophila, and (c) L. pneumophila membranes have potential as a vaccine against Legionnaires' disease.
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PMID:Vaccination with Legionella pneumophila membranes induces cell-mediated and protective immunity in a guinea pig model of Legionnaires' disease. Protective immunity independent of the major secretory protein of Legionella pneumophila. 199 85

The Legionella pneumophila major secretory protein (Msp) is a Zn2+ metalloprotease whose function in pathogenesis is unknown. The structural gene for the Msp protease, mspA, was isolated from an L. pneumophila genomic library. In Escherichia coli which contain plasmids with the mspA gene, Msp protein and activity are found in the periplasmic space and the cytoplasm. Transposon mutagenesis with Tn9 of an mspA-containing plasmid in E. coli yielded mutants which no longer expressed protease activity and others with increased protease activity. These results suggested that mspA expression might be regulated. Msp was shown to be produced at a much higher level in L. pneumophila grown in rich compared to semidefined media. A Tn9 insertion which abolishes Msp expression was introduced into the L. pneumophila genome. This mspA::Tn9 L. pneumophila strain showed no detectable production of Msp by immunoblot analysis, and it had less than 0.1% of the protease activity found in the wild-type strain. This mutant was fully capable of growing within and killing human macrophages derived from the HL-60 cell line.
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PMID:The Legionella pneumophila major secretory protein, a protease, is not required for intracellular growth or cell killing. 216 10

We have examined whether a molecule that is capable of inducing immune protection, the major secretory protein (MSP) of Legionella pneumophila, is required for virulence in a guinea pig model of Legionnaires' disease. To do so, we have compared the virulence in guinea pigs of an isogenic pair of L. pneumophila, Philadelphia 1 strain, one of which produces MSP (MSP+) and one of which does not (MSP-). Both the MSP- strain and the MSP+ strain of L. pneumophila are highly virulent for guinea pigs, inducing similar signs and progression of illness. Both strains are lethal and have comparable LD50s and LD100s. Both strains multiply in the lungs of guinea pigs at a similar rate, and both strains produce indistinguishable pathological lesions in the lungs. Both strains maintain a stable phenotype with guinea pig passage, i.e., the MSP- strain does not regain the capacity to secrete MSP and the MSP+ strain retains its capacity to secrete MSP after lung passage. Although vaccination with MSP induces strong protective immunity in the guinea pig against lethal aerosol challenge with L. pneumophila, this protective immunogen is not required in its intact proteolytically active form for the expression of virulence by the intracellular pathogen L. pneumophila. This demonstrates that a protective immune response need not necessarily be directed against a virulence determinant and suggests that any molecule that allows the host immune system to detect and act against an intracellularly sequestered pathogen may potentially serve as a protective immunogen against such a pathogen.
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PMID:An immunoprotective molecule, the major secretory protein of Legionella pneumophila, is not a virulence factor in a guinea pig model of Legionnaires' disease. 220 24

We have examined the capacity of the major secretory protein (MSP) of Legionella pneumophila to induce humoral, cell-mediated, and protective immunity in a guinea pig model of Legionnaires' disease. MSP was purified to homogeneity by ammonium sulfate precipitation, molecular sieve chromatography, and ion-exchange chromatography. The purified MSP was nonlethal and nontoxic to guinea pigs upon subcutaneous administration. Guinea pigs immunized with a sublethal dose of aerosolized L. pneumophila or a subcutaneous dose of MSP developed a strong cell-mediated immune response to MSP. Such guinea pigs exhibited marked splenic lymphocyte proliferation and cutaneous delayed-type hypersensitivity to MSP in comparison with control animals. Guinea pigs immunized with MSP also developed a strong humoral immune response to MSP, as assayed by an ELISA. The median reciprocal antibody titer was 362 (range 45 to greater than 2,048) for immunized animals compared with less than 8 for controls. In contrast, guinea pigs immunized with a sublethal dose of L. pneumophila failed to develop anti-MSP antibody. Guinea pigs immunized with MSP and then challenged with a lethal aerosol dose of L. pneumophila exhibited highly significant protective immunity in each of five consecutive experiments. MSP induced protective immunity in dose-dependent fashion (40 greater than 10 greater than 2.5 greater than 0.6 micrograms MSP); vaccination with two doses of as little as 2.5 micrograms MSP induced significant protective immunity (p = 0.01, Fisher's Exact Test, two-tailed). Altogether, 21 (81%) of 26 animals immunized with 40 micrograms MSP survived challenge compared with 0 (0%) of 26 sham-immunized control animals (p = 7 x 10(-10), Fisher's Exact Test, two-tailed). MSP-immunized but not control guinea pigs were able to limit L. pneumophila multiplication in their lungs. This study demonstrates that (a) guinea pigs sublethally infected with L. pneumophila develop a strong cell-mediated immune response to MSP; (b) guinea pigs immunized with MSP develop a strong humoral and cell-mediated immune response to MSP; (c) guinea pigs immunized with MSP develop a very high level of protective immunity to lethal aerosol challenge with L. pneumophila; and (d) MSP-immunized animals are able to limit L. pneumophila multiplication in their lungs. MSP, an extracellular protein of an intracellular pathogen, has potential as a vaccine for the prevention of Legionnaires' disease. Secretory molecules of other intracellular pathogens may also have vaccine potential.
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PMID:Vaccination with the major secretory protein of Legionella pneumophila induces cell-mediated and protective immunity in a guinea pig model of Legionnaires' disease. 292 24

Legionella pneumophila, the causative agent of Legionnaires' disease, is a Gram-negative bacterium and a facultative intracellular parasite that multiplies in human monocytes and alveolar macrophages. In this paper, mutants of L. pneumophila avirulent for human monocytes were obtained and extensively characterized. The mutants were obtained by serial passage of wild-type L. pneumophila on suboptimal artificial medium. None of 44 such mutant clones were capable of multiplying in monocytes or exerting a cytopathic effect on monocyte monolayers. Under the same conditions, wild-type L. pneumophila multiplied 2.5-4.5 logs, and destroyed the monocyte monolayers. The basis for the avirulent phenotype was an inability of the mutants to multiply intracellularly. Both mutant and wild-type bacteria bound to and were ingested by monocytes, and both entered by coiling phagocytosis. Thereafter, their intracellular destinies diverged. The wild-type formed a distinctive ribosome-lined replicative phagosome, inhibited phagosome-lysosome fusion, and multiplied intracellularly. The mutant did not form the distinctive phagosome nor inhibit phagosome-lysosome fusion. The mutant survived intracellularly but did not replicate in the phagolysosome. In all other respects studied, the mutant and wild-type bacteria were similar. They had similar ultrastructure and colony morphology; both formed colonies of compact and diffuse type. They had similar structural and secretory protein profiles and LPS profile by PAGE. Both the mutant and wild-type bacteria were completely resistant to human complement in the presence or absence of high titer anti-L. pneumophila antibody. The mutant L. pneumophila have tremendous potential for enhancing our understanding of the intracellular biology of L. pneumophila and other parasites that follow a similar pathway through the mononuclear phagocyte. Such mutants also show promise for enhancing our understanding of immunity to L. pneumophila, and they may serve as prototypes in the development of safe and effective vaccines against intracellular pathogens.
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PMID:Characterization of avirulent mutant Legionella pneumophila that survive but do not multiply within human monocytes. 368 Nov 88

We studied the immune responses of guinea pigs and humans to two Legionella pneumophila antigens. Guinea pigs surviving a lethal intraperitoneal challenge dose of virulent L. pneumophila exhibited strong cutaneous delayed-type hypersensitivity (DTH) reactions to purified OmpS (28-kDa major outer membrane protein) and Hsp60 (heat shock protein or common antigen), while weak DTH reactions were noted for extracellular protease (major secretory protein [MSP] [ProA]) and no reaction was observed with an ovalbumin (OA) control. Lymphocyte proliferation responses (LPRs) were measured for peripheral blood and spleen lymphocytes from guinea pigs surviving sublethal and lethal challenge doses of L. pneumophila. Lymphocytes from uninfected animals showed no proliferation to Hsp60 or OmpS, while lymphocytes from sublethally and lethally challenged animals exhibited strong proliferative responses to Hsp60 and OmpS. Guinea pigs vaccinated with purified OmpS exhibited low antibody titers and strong DTH and LPRs to OmpS, whereas lymphocytes from animals vaccinated with Hsp60 exhibited weak DTH responses and high antibody titers to Hsp60. All guinea pigs immunized with OmpS survived experimental challenge with L. pneumophila (two of two in a pilot study and seven of seven in trial 2) versus zero of seven OA-immunized controls (P = 0.006 by Fisher's exact test). In three vaccine trials in which animals were vaccinated with Hsp60, only 1 guinea pig of 15 survived lethal challenge. Peripheral blood lymphocytes (PBLs) from humans with legionellosis showed stronger LPRs to OmpS than PBLs from humans with no history of legionellosis (P = 0.0002 by Mann-Whitney test). PBLs of humans surviving legionellosis exhibited a lower but highly significant proliferative response to Hsp60 (P < 0.0001 compared with controls by Mann-Whitney test). These studies indicate that OmpS and Hsp60 are important antigens associated with the development of protective cellular immunity. However, as determined in vaccine trial studies in the guinea pig model for legionellosis, the species-specific antigen OmpS proved much more effective than the genus-common Hsp60 antigen.
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PMID:Human and guinea pig immune responses to Legionella pneumophila protein antigens OmpS and Hsp60. 791 99

The role of the major secretory protein of Legionella pneumophila, a zinc protease, in Legionella infection is not known. Since an important step of the host reaction in Legionnaires' disease is the production of tumor necrosis factor-alpha (TNF-alpha) by alveolar macrophages, we studied the interaction of Legionella protease and U-937 cells with respect to TNF-alpha. The Legionella protease was purified by fractionated precipitation, gel filtration and hydrophobic interaction chromatography. The purified enzyme was added to U-937 cells, a promyelocytic cell line. In the supernatants of PMA-treated U-937 cells we found low concentrations of TNF-alpha after incubation with protease. Therefore we pursued the hypothesis of direct enzymatic degradation of TNF-alpha by Legionella protease. Enzymatic cleavage of TNF-alpha was proven by SDS-PAGE, ELISA and TNF-alpha bioassay with L-929 cells. The degradation of TNF-alpha by the Legionella protease was shown in all three systems. Enzymatic degradation of TNF-alpha might be important for the pathogenesis of Legionnaires' disease.
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PMID:Cleavage of tumor necrosis factor-alpha by Legionella exoprotease. 848 63

Legionella pneumophila produces several extracellular proteins, but their role in the pathogenesis of Legionnaires' disease is unclear. This study examined the effects of the L. pneumophila major secretory protein (Msp), a zinc metalloprotease, on the oxidative burst and chemotaxis of human phagocytes. Polymorphonuclear leucocytes (PMNLs) and adherent monocytes treated with sublethal amounts of Msp protease were stimulated with formyl-leucyl-methionyl-phenylalanine (fMLP) and opsonised zymosan particles (ZAP). A dose-dependent inhibition in superoxide anion production in response to both stimuli was seen, and complete inhibition was achieved in PMNLs and monocytes treated with Msp at concentrations of 1500 and 1000 U/ml, respectively. ZAP-induced chemiluminescence by PMNLs and mononuclear cells and fMLP-induced PMNL nitroblue tetrazolium dye reduction were both significantly inhibited. The chemotactic response of PMNLs to fMLP was inhibited in a dose-dependent manner and substantial inhibition (11% of control) was achieved with Msp 1200 U/ml. These results suggest that the L. pneumophila Msp protease alters human phagocyte functional responses significantly and may contribute to the pathogenesis of Legionnaires' disease.
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PMID:Inhibition of oxidative burst and chemotaxis in human phagocytes by Legionella pneumophila zinc metalloprotease. 1139 89


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