Your search keyword '"Metkar, Sunil S."' showing total 4 results

1. Perforin rapidly induces plasma membrane phospholipid flip-flop.

Author

Metkar SS, Wang B, Catalan E, Anderluh G, Gilbert RJ, Pardo J, and Froelich CJ

Subjects

Animals, Annexin A5 metabolism, Apoptosis drug effects, Biomarkers metabolism, Calcium pharmacology, Cattle, Cell Membrane drug effects, Cholesterol deficiency, Cholesterol metabolism, Epitopes, Exocytosis drug effects, Extracellular Space drug effects, Extracellular Space metabolism, Granzymes pharmacology, HeLa Cells, Humans, Ions, Jurkat Cells, Mice, Models, Biological, Perforin isolation & purification, Perforin pharmacology, Propidium metabolism, Sheep, T-Lymphocytes, Cytotoxic drug effects, T-Lymphocytes, Cytotoxic metabolism, Time Factors, Cell Membrane metabolism, Perforin metabolism, Phosphatidylserines metabolism

Abstract

The cytotoxic cell granule secretory pathway is essential for host defense. This pathway is fundamentally a form of intracellular protein delivery where granule proteases (granzymes) from cytotoxic lymphocytes are thought to diffuse through barrel stave pores generated in the plasma membrane of the target cell by the pore forming protein perforin (PFN) and mediate apoptotic as well as additional biological effects. While recent electron microscopy and structural analyses indicate that recombinant PFN oligomerizes to form pores containing 20 monomers (20 nm) when applied to liposomal membranes, these pores are not observed by propidium iodide uptake in target cells. Instead, concentrations of human PFN that encourage granzyme-mediated apoptosis are associated with pore structures that unexpectedly favor phosphatidylserine flip-flop measured by Annexin-V and Lactadherin. Efforts that reduce PFN mediated Ca influx in targets did not reduce Annexin-V reactivity. Antigen specific mouse CD8 cells initiate a similar rapid flip-flop in target cells. A lipid that augments plasma membrane curvature as well as cholesterol depletion in target cells enhance flip-flop. Annexin-V staining highly correlated with apoptosis after Granzyme B (GzmB) treatment. We propose the structures that PFN oligomers form in the membrane bilayer may include arcs previously observed by electron microscopy and that these unusual structures represent an incomplete mixture of plasma membrane lipid and PFN oligomers that may act as a flexible gateway for GzmB to translocate across the bilayer to the cytosolic leaflet of target cells.

Published

2011

2. Human and mouse granzyme A induce a proinflammatory cytokine response.

Author

Metkar SS, Menaa C, Pardo J, Wang B, Wallich R, Freudenberg M, Kim S, Raja SM, Shi L, Simon MM, and Froelich CJ

Subjects

Adenoviridae immunology, Animals, Cell Adhesion, Cell Death, Cell Line, Tumor, Cytotoxicity, Immunologic, Gene Knockdown Techniques, Granzymes metabolism, HeLa Cells, Humans, Inflammation immunology, Inflammation metabolism, Interleukin-1beta metabolism, Interleukin-6 metabolism, Jurkat Cells, Macrophages immunology, Mice, Perforin metabolism, T-Lymphocytes, Cytotoxic metabolism, Tumor Necrosis Factor-alpha metabolism, U937 Cells, Granzymes immunology, Interleukin-1beta immunology, Interleukin-6 immunology, Leukocytes, Mononuclear immunology, Perforin immunology, T-Lymphocytes, Cytotoxic immunology, Tumor Necrosis Factor-alpha immunology

Abstract

Granzyme A (GzmA) is considered a major proapoptotic protease. We have discovered that GzmA-induced cell death involves rapid membrane damage that depends on the synergy between micromolar concentrations of GzmA and sublytic perforin (PFN). Ironically, GzmA and GzmB, independent of their catalytic activity, both mediated this swift necrosis. Even without PFN, lower concentrations of human GzmA stimulated monocytic cells to secrete proinflammatory cytokines (interleukin-1beta [IL-1beta], TNFalpha, and IL-6) that were blocked by a caspase-1 inhibitor. Moreover, murine GzmA and GzmA(+) cytotoxic T lymphocytes (CTLs) induce IL-1beta from primary mouse macrophages, and GzmA(-/-) mice resist lipopolysaccharide-induced toxicity. Thus, the granule secretory pathway plays an unexpected role in inflammation, with GzmA acting as an endogenous modulator.

Published

2008

3. Detection of functional cell surface perforin by flow cytometry

Author

Metkar, Sunil S., Wang, Baikun, and Froelich, Christopher J.

Subjects

*CELL membranes, *PROTEOGLYCANS, *GLYCOPROTEINS, *KILLER cells

Abstract

Abstract: How perforin (PFN) delivers the granzymes during cytotoxic granule mediated apoptosis remains a mystery. A major obstacle has been the inability to visualize PFN in either monomeric or polymeric form after interaction with the target cell surface. An antibody based technique is described which detects cell surface PFN on intact cells by flow cytometry. The methodology requires the presence of calcium (Ca2+) at a concentration which supports binding but not polymerization of PFN. Functionality was ensured by showing the cell surface PFN was able to deliver GrB causing caspase-3 activation and mitochondrial depolarization. The technique demonstrates a role for heparan sulfate proteoglycans in PFN binding. Further, the variable sensitivity of effector versus target cell lines to the permeabilizing effects of PFN could not be attributed to differential binding of PFN. [Copyright &y& Elsevier]

Published

2005

4. Human perforin permeabilizing activity, but not binding to lipid membranes, is affected by pH

Author

Praper, Tilen, Beseničar, Mojca Podlesnik, Istinič, Helena, Podlesek, Zdravko, Metkar, Sunil S., Froelich, Christopher J., and Anderluh, Gregor

Subjects

*PROTEINS, *BILAYER lipid membranes, *HYDROGEN-ion concentration, *NATURAL immunity, *IMMUNE response, *SURFACE plasmon resonance, *T cells, *EPIDERMAL growth factor

Abstract

Abstract: The various steps that perforin (PFN), a critical mediator of innate immune response, undertakes to form a transmembrane pore remains poorly understood. We have used surface plasmon resonance (SPR) to dissect mechanism of pore formation. The membrane association of PFN was calcium dependent irrespective of pH. However, PFN does not permeabilize large or giant unilamellar vesicles (GUV) at pH 5.5 even though the monomers bind to the membranes in the presence of calcium. It was possible to activate adsorbed PFN and to induce membrane permeabilization by simply raising pH to a physiological level (pH 7.4). These results were independently confirmed on GUV and Jurkat cells. The conformational state of PFN at either pH was further assessed with monoclonal antibodies Pf-80 and Pf-344. Pf-344 maps to a linear epitope within region 373–388 of epidermal growth factor (EGF)-like domain while the Pf-80 appears to recognize a conformational epitope. Pf-344 interacts with the EGF-like domain after PFN monomers undergo pore formation, the site recognized by Pf-80 is only accessible at acidic but not neutral pH. Thus, the Pf-80 mAb likely interacts with a region of the monomer that participates in oligomerization prior to insertion of the monomer into the lipid bilayer and thus may have therapeutic utility against PFN-mediated immunopathology. [ABSTRACT FROM AUTHOR]

Published

2010