cathepsin-g and Necrosis

Neutrophil granule serine proteases contribute to immune responses through cleavage of microbial toxins and structural proteins. They induce tissue damage and modulate inflammation if levels exceed their inhibitors. Here, we show that the intracellular protease inhibitors Serpinb1a and Serpinb6a contribute to monocyte and neutrophil survival in steady-state and inflammatory settings by inhibiting cathepsin G (CatG). Importantly, we found that CatG efficiently cleaved gasdermin D (GSDMD) to generate the signature N-terminal domain GSDMD-p30 known to induce pyroptosis. Yet GSDMD deletion did not rescue neutrophil survival in Sb1a.Sb6a

Topics: Animals; Apoptosis; Cathepsin G; Endotoxins; Female; Inflammasomes; Inflammation; Intracellular Signaling Peptides and Proteins; Macrophages; Male; Mice; Mice, Inbred C57BL; Mice, Knockout; Monocytes; Necrosis; Neutrophils; Phosphate-Binding Proteins; Pyroptosis; Serpins

The hallmark of human Mycobacterium tuberculosis infection is the presence of lung granulomas. Lung granulomas can have different phenotypes, with caseous necrosis and hypoxia present within these structures during active tuberculosis. Production of NO by the inducible host enzyme NOS2 is a key antimycobacterial defense mechanism that requires oxygen as a substrate; it is therefore likely to perform inefficiently in hypoxic regions of granulomas in which M. tuberculosis persists. Here we have used Nos2-/- mice to investigate host-protective mechanisms within hypoxic granulomas and identified a role for host serine proteases in hypoxic granulomas in determining outcome of disease. Nos2-/- mice reproduced human-like granulomas in the lung when infected with M. tuberculosis in the ear dermis. The granulomas were hypoxic and contained large amounts of the serine protease cathepsin G and clade B serine protease inhibitors (serpins). Extrinsic inhibition of serine protease activity in vivo resulted in distorted granuloma structure, extensive hypoxia, and increased bacterial growth in this model. These data suggest that serine protease activity acts as a protective mechanism within hypoxic regions of lung granulomas and present a potential new strategy for the treatment of tuberculosis.

Topics: Animals; Cathepsin G; Granuloma; Hypoxia; Lung; Mice; Mice, Inbred C57BL; Mice, Knockout; Mycobacterium tuberculosis; Necrosis; Pulmonary Fibrosis; Serine Proteases; Tuberculosis, Pulmonary

The role of cardiac mast cells (MCs) in the progression to heart failure has recently become increasingly evident. Cathepsin g is a neutrophil- and mast cell-derived protease, which can convert angiotensin I to angiotensin II and thereby activate the TGF-beta pathway, resulting in myocyte necrosis, hypertrophy, and increased fibrosis. This study focuses on mast cell-derived cathepsin g in the human heart during heart failure and following mechanical unloading by means of heart-assist devices (LVADs).. Myocardial tissue was obtained from 10 patients with end-stage cardiomyopathy at the time of LVAD implantation (pre-LVAD) and following orthotopic heart transplantation (post-LAVD). In addition, biopsies of four normal hearts served as a control group. Paraffin-embedded sections were dual stained for cathepsin g and tryptase, a known marker for mast cells, using standard immunohistochemistry protocols. Total cathepsin g positive mast cells were counted.. No cathepsin g positive MCs were found in normal hearts. However, we found evidence for cathepsin g in cardiac MCs in heart failure tissues (pre-LVAD). During heart failure, 46% of total MCs were cathepsin g positive as compared to after mechanical unloading, where only 11% of total MCs were cathepsin g positive (P<0.001).. Heart failure causes an increase of myocardial MCs. We have provided evidence that cathepsin g positive MCs accumulate during heart failure and their total percentage decreases after ventricular unloading. This coincides with the decrease in myocyte necrosis, hypertrophy, and fibrosis. Thus, cathepsin g may play a role in the progression to heart failure by activating angiotensin II, leading to detrimental effects on the heart.

Topics: Adult; Aged; Angiotensin II; Cardiac Output, Low; Case-Control Studies; Cathepsin G; Cathepsins; Chymases; Disease Progression; Female; Heart-Assist Devices; Humans; Male; Mast Cells; Middle Aged; Myocardium; Necrosis; Serine Endopeptidases; Tryptases; Ventricular Remodeling

Granulocytes undergoing apoptosis are recognized and removed by phagocytes before their lysis. The release of their formidable arsenal of proteases and other toxic intracellular contents into tissues can create significant damage, prolonging the inflammatory response. Binding and/or uptake of apoptotic cells by macrophages inhibits release of proinflammatory cytokines by mechanisms that involve anti-inflammatory mediators, including TGF-beta. To model the direct effects of necrotic cells on macrophage cytokine production, we added lysed or apoptotic neutrophils and lymphocytes to mouse and human macrophages in the absence of serum to avoid complement activation. The results confirmed the ability of lysed neutrophils, but not lymphocytes, to significantly stimulate production of macrophage-inflammatory protein 2 or IL-8, TNF-alpha, and IL-10. Concomitantly, induction of TGF-beta1 by lysed neutrophils was significantly lower than that observed for apoptotic cells. The addition of selected serine protease inhibitors and anti-human elastase Ab markedly reduced the proinflammatory effects, the lysed neutrophils then behaving as an anti-inflammatory stimulus similar to intact apoptotic cells. Separation of lysed neutrophils into membrane and soluble fractions showed that the neutrophil membranes behaved like apoptotic cells. Thus, the cytokine response seen when macrophages were exposed to lysed neutrophils was largely due to liberated proteases. Therefore, we suggest that anti-inflammatory signals can be given by PtdSer-containing cell membranes, whether from early apoptotic, late apoptotic, or lysed cells, but can be overcome by proteases liberated during lysis. Therefore, the outcome of an inflammatory reaction and the potential immunogenicity of Ags within the damaged cell will be determined by which signals predominate.

Topics: Animals; Apoptosis; Bone Marrow Cells; Cathepsin G; Cathepsins; Cell Fractionation; Cells, Cultured; Chemokines; Culture Media, Serum-Free; Endopeptidases; Humans; Immune Sera; Jurkat Cells; Leukocyte Elastase; Lymphocytes; Macrophage Activation; Macrophages; Mice; Necrosis; Neutrophils; Protease Inhibitors; Serine Endopeptidases; Tumor Necrosis Factor-alpha; Zymosan

The poly(ADP-ribose) polymerase (PARP-1), a 113 kDa nuclear enzyme, is cleaved in fragments of 89 and 24 kDa during apoptosis. This cleavage has become a useful hallmark of apoptosis and has been shown to be done by DEVD-ase caspases, a family of proteases activated during apoptosis. Interestingly, PARP-1 is also processed during necrosis but a major fragment of 50 kDa is observed. This event is not inhibited by zVAD-fmk, a broad spectrum caspase inhibitor, suggesting that these proteases are not implicated in the necrotic cleavage of PARP-1. Since lysosomes release their content into the cytosol during necrosis, the proteases liberated could produce the cleavage of PARP-1. We therefore isolated lysosomal rich-fractions from Jurkat T cells. Our results reveal that the in vitro lysosomal proteolytic cleavage of affinity purified bovine PARP-1 is composed of fragments corresponding, in apparent molecular weight and function, to those found in Jurkat T cells treated with necrotic inducers like 0.1% H2O2, 10% EtOH or 100 microM HgCl2. Moreover, we used purified lysosomal proteases (cathepsins B, D and G) in an in vitro cleavage assay and found that cathepsins B and G cleaved PARP-1 in fragments also found with the lysosomal rich-fractions. These findings suggest that the necrotic cleavage of PARP-1 is caused in part or in totality by lysosomal proteases released during necrosis.

Topics: Amino Acid Sequence; Animals; Apoptosis; Blotting, Western; Caspases; Cathepsin B; Cathepsin G; Cathepsins; Cattle; Cell Extracts; Endopeptidases; Enzyme Activation; Humans; Jurkat Cells; Lysosomes; Molecular Weight; Necrosis; Peptide Fragments; Peptide Hydrolases; Poly(ADP-ribose) Polymerases; Protein Structure, Tertiary; Serine Endopeptidases; Time Factors