Collagen degrading activity associated with Mycobacterium species.

BACKGROUND: The mechanism of Mycobacterium tuberculosis penetration into tissues is poorly understood but it is reasonable to assume that there is a contribution from proteases capable of disrupting the extracellular matrix of the pulmonary epithelium and the blood vessels. A study was undertaken to identify and characterise collagen degrading activity of M tuberculosis. METHODS: Culture filtrate protein extract (CFPE) was obtained from reference mycobacterial strains and mycobacteria isolated from patients with tuberculosis. The collagen degrading activity of CFPE was determined according to the method of Johnson-Wint using 3H-type I collagen. The enzyme was identified by the Birkedal-Hansen and Taylor method and its molecular mass determined by SDS-PAGE and Sephacryl S-300 gel filtration chromatography using an electroelution purified enzyme. RESULTS: CFPE from Mycobacterium tuberculosis strain H37Rv showed collagenolytic activity that was four times higher than that of the avirulent strain H37Ra. The 75 kDa enzyme responsible was divalent cation dependent. Other mycobacterial species and those isolated from patients with tuberculosis also had collagen degrading activity. CONCLUSIONS: Mycobacterium species possess a metalloprotease with collagen degrading activity. The highest enzymatic activity was found in the virulent reference strain H37Rv.

Disruption of the cysteine-75 and zinc ion coordination is not sufficient to activate the precursor of human matrix metalloproteinase 3 (stromelysin 1).

Matrix metalloproteinases (MMPs) are activated in vitro from their precursors (proMMPs) by multiple means such as treatment with proteinases, mercurial compounds, chaotropic agents, sodium dodecyl sulfate, HOCl, and heat. The latency of proMMPs is stabilized by intramolecular interaction of the single cysteine residue in the conserved sequence PRCG(V/N)PD of the propeptide and the zinc atom at the active site. The activation of proMMP-1 (interstitial procollagenase) by multiple treatments has been explained by the "cysteine switch" model, in which the disruption of the Cys-Zn interaction is considered to be critical for activation [Springman, E. B., Angleton, E. L., Birkedal-Hansen, H., & VanWart, H. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 364-368]. To further test this hypothesis we dissociated the Cys-Zn interaction by specifically modifying Cys-75 of proMMP-3 (prostromelysin 1) with iodoacetamide, (4-aminophenyl)mercuric acetate (APMA), or 5,5'-dithiobis(2-nitrobenzoate) and examined the expression of enzymic activity. The enzymic assays of the modified proMMP-3s against protein and synthetic substrates did not reveal any significant activity. The modified 57-kDa proMMP-3s were stable and did not show spontaneous activation. Activation of the modified proMMP-3s required further treatment with APMA or a proteinase and was accompanied by conversion of the proMMP-3 to a 45-kDa species. Circular dichroism studies of proMMP-3 treated with HgCl2 demonstrated time-dependent conformational changes in proMMP-3 prior to the expression of proteolytic activity and processing of the zymogen to lower molecular weight species. These results indicate that the disruption of the Cys-Zn coordination alone is not sufficient to activate proMMP-3.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescent probes as tools to assess the receptor for the urokinase-type plasminogen activator on tumor cells.

Flow cytofluorometric protocols (FACScan) are described for the rapid and quantitative real-time analysis of binding of FITC-pro-u-PA to cell surface receptors (u-PAR) on living, resting, and also on PMA-stimulated human monocytic U937 cells. Binding of pro-u-PA was visualized by CLSM. This fairly new technique is superior over conventional fluorescence microscopy and is an alternative to electron microscopic approaches. Both flow cytofluorometry and confocal laser scanning microscopy allow the analysis quantitatively and with high-sensitivity binding of FITC-pro-u-PA to single suspended or adherent cells. By CLSM u-PA/u-PAR were found to be located in heterogeneously distributed discrete patches at the cell surface on U937 and not inside the cell. This is in agreement with previous studies by Hansen et al, who applied radioiodinated u-PA and electron microscopy to locate u-PAR on microvilli of fixed U937 cells. By flow cytofluorometry, it was possible to quantify the time-dependent and temperature-dependent binding of FITC-pro-u-PA to living single U937. Apparent saturation of u-PAR was achieved at 5 nM FITC-pro-u-PA for both nonstimulated and PMA-stimulated U937 cells. Half saturation of u-PAR was also determined. Nonstimulated U937 was 0.7 nM, and PMA-stimulated U937 was 1.1 nM of FITC-pro-u-PA. This increase in half-saturation concentration in PMA-stimulated cells is paralleled by a steep increase in binding sites (3.6-fold). The use of fluoresceinated reference beads is recommended to verify changes in affinity and binding sites. Using CLSM or flow cytofluorometry, it is also possible to study the structure relationship of u-PA/u-PAR in the presence of competitive binding analogues or inhibitors. Fluorescence techniques will also permit the identification of u-PAR-positive cells in blood, ascitic fluid, or biopsies obtained from cancer patients.

Mutational analysis of the transin (rat stromelysin) autoinhibitor region demonstrates a role for residues surrounding the "cysteine switch".

The family of mammalian extracellular matrix metalloproteases (MMPs) are secreted by cells in an inactive (latent) proenzyme form. A highly conserved amino acid sequence, PRCGVPDV, is found near the COOH-terminal end of the pro-domain of these MMPs and believed to act as an "autoinhibitor." Recent studies (Springman, E. B., Angleton, E. L., Birkedal-Hansen, H., and Wart, H. E. V. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 364-368) indicate the Cys of this sequence ligands to the active-site zinc keeping the proenzyme in an inactive state, and mutational analysis (Sanchez-Lopez, R., Nicholson, R., Gesnel, M. C., Matrisian, L. M., and Breathnach, R. (1988) J. Biol. Chem. 263, 11892-11899) suggests that the conserved residues surrounding this Cys are required for latency. We have constructed 16 new site-directed mutations of the PRCGVPDV autoinhibitor region of the MMP transin (rat stromelysin) and tested whether these mutant enzymes are produced in a latent or activated form. We find that the conserved Arg as well as the Cys are essential for maintaining latency. The Cys cannot be replaced by other zinc-liganding amino acids, and the Arg cannot be replaced by Lys. Residues immediately surrounding the Cys are sensitive to even conservative amino acid substitutions. We show that a synthetic peptide PRCGVPDV is capable of acting as a weak inhibitor of transin and that replacement of the Cys with a Ser abolishes inhibition by the peptide. A review of the current knowledge of MMP substrate specificity in combination with these new results suggests that the PRCGVPDV sequence does not inhibit activity by mimicking the known substrates of the protease.