Platelet-activating factor (PAF)-dependent biochemical, morphologic, and physiologic responses of human platelets: demonstration of translocation of protein kinase C associated with protein phosphorylation.

Platelet-activating factor (PAF) is a potent stimulus for platelet aggregation and secretion. PAF has been shown to stimulate the phosphatidylinositol (PI) pathway in platelets, which implies that PAF should activate protein kinase C. In this study, measurements of PI metabolites, the elevation of intracellular free calcium concentration, (Ca2+)i, the activation of protein kinase C, and the phosphorylation of platelet proteins (using a two-dimensional gel electrophoretic technique) were performed before and after the addition of 10(-8) M PAF to human platelets. These findings were correlated with morphologic changes in the platelets as determined by immunoelectron microscopic studies on the cytoskeleton and by X-ray analysis of dense bodies. The results show that PAF stimulates the production of PI metabolites and causes an increase in the membrane-associated activity of protein kinase C. These changes are accompanied by a rise in the (Ca2+)i and protein phosphorylation. The increase in protein kinase C activity reaches a maximum at approximately 60 s, a time frame that is consistent with the protein phosphorylation and the subsequent morphologic and secretory events. X-ray analysis revealed two types of dense bodies containing various amounts of calcium which appeared to be released sequentially after PAF activation. These results suggest that the protein phosphorylation that controls the physiologic events resulting from PAF activation of human platelets is catalyzed by protein kinase C.

Identification and sequencing of cDNA clones encoding the granule-associated serine proteases granzymes D, E, and F of cytolytic T lymphocytes.

Cytoplasmic granules of cytolytic T lymphocytes contain at least six related serine esterases (granzymes) that are released together with perforin, a pore-forming protein related to complement component C9, during target-cell lysis. Polyclonal antibodies were used to isolate a large number of cDNA clones from an expression library derived from cytolytic-T-cell mRNA. Three distinct full-length cDNA clones coding for granzymes D, E, and F were identified by restriction site mapping and nucleotide sequencing. The three deduced amino acid sequences are highly similar to one another (between 72% and 90% amino acid identities) and to the sequences of granzymes B and C, cathepsin G, and rat mast-cell proteases I and II (between 43% and 57% amino acid identities). Cysteine residues capable of forming intramolecular disulfide bonds are conserved, as are the catalytic-site residues characteristic of serine proteases. Comparison of the cDNA-derived protein sequences with the amino termini of the isolated granzymes provides evidence that they are stored in a fully processed, activated form after removal of the signal peptide and two additional residues (propeptide) at the amino terminus. Immunoelectron microscopic studies demonstrated that granzymes D, E, and F are present in the same morphologically distinct cytoplasmic granules in which perforin has been found previously.

Low density lipoprotein causes general cellular activation with increased phosphatidylinositol turnover and lipoprotein catabolism.

Low density lipoprotein (LDL), at concentrations high enough for receptor binding but not high enough to saturate the receptor, induces activation of phosphatidylinositol (PtdIns) turnover in a variety of cell types with various biological functions. Using both biochemical and electron microscopic studies, we have shown that blood platelets take up and degrade LDL in a manner reminiscent of phagocytic cell types. The activation of both PtdIns turnover and LDL metabolism is inhibited by high density lipoprotein. Thus, LDL at hormonal concentrations causes general cellular activation. Since all cell types studied responded to LDL with increased PtdIns turnover and uptake of LDL cholesterol, the PtdIns cycle may also be involved in the cellular regulation of LDL cholesterol metabolism.

Cellular localization of perforin 1 in murine cloned cytotoxic T lymphocytes.

The localization of perforin 1 (P1) in cytotoxic cells was studied by immuno-electron microscopy by using a monospecific rabbit antiserum against highly purified mouse P1 and protein A gold as a second ligand. P1 was found in specific granules of cloned cytotoxic T lymphocytes (CTL). Within the granules, P1 antigen was localized in the fine granular matrix, whereas the vesicular compartment remained free of gold particles. The amount of P1 antigen detectable by immuno-electron microscopy varied between different CTL clones. CTL with NK-like activity had the highest level of P1 antigen. A cytotoxicity loss CTL mutant had no detectable P1 antigen, suggesting an important role of P1 during cell-mediated cytolysis. P1 antigen was undetectable also in bone marrow macrophages, indicating a different cytolytic mechanism of these cells.