Protein kinase C activation after cellular adhesion on fibronectin: partial suppression after inhibition of protein isoprenylation.

The cellular events following interaction between matrix proteins and cells are important requisites for physiological mechanisms as well as the progress of a number of diseases. Cellular adhesion to fibronectin, an important component of the extracellular matrix has been demonstrated to be associated with translocation of protein kinase C (PKC) by an integrin-dependent pathway. For this process G-proteins may play an important role as coupling proteins. Membrane association and activity of G-proteins has been shown to be regulated by isoprenylation. We therefore studied whether fibronectin mediated adhesion resulted in PKC translocation and if isoprenylation of cellular proteins may play a role for this integrin-dependent pathway of PKC activation. Chinese hamster ovary (CHO) cells were pretreated with either the Hydroxy-methylglutaryl(HMG)-CoA reductase inhibitor lovastatin or prenylation inhibitor limonene. For the stimulation by extracellular matrices, CHO cells were plated on tissue culture dishes coated with fibronectin or bovine serum albumin and PKC activity was determined. To investigate direct effects of inhibition of isoprenylation on cytoskeletal organization, phalloidin-stained stress fibers were characterized after adhesion on different matrices. CHO cells seeded on fibronectin displayed over twice the PKC translocation to the particulate fraction in comparison to that measured in cells on albumin. Pretreatment of CHO cells with lovastatin or limonene resulted in partial suppression of PKC activation after cell-seeding on the specific matrix fibronectin. Changed PKC distribution was not due to a disorganization of the actin skeleton. These data show that inhibition of isoprenylation of cellular proteins, possibly small Guanosine triphosphate(GTP)-binding proteins, alters only the integrin-mediated PKC distribution but does not greatly influence constitutive PKC distribution.

Fibrinogen promotes monocyte adhesion via a protein kinase C dependent mechanism.

The accumulation of blood monocytes at sites of predilection of the vessel wall is an early cellular event of atherogenesis. Proteins of the vessel wall may facilitate monocyte adhesion and thus promote their recruitment. It has been shown that the relative content of extracellular fibrinogen increases during lesion development, and this study investigated the contribution of immobilized fibrinogen to monocyte adhesion and the underlying mechanism. Freshly isolated human blood monocytes were cultivated in serum-free RPMI 1640 in tissue culture wells precoated with albumin, fibrinogen, or fibrin. After 16 h the plates were washed and adherent cells enumerated. Immobilized fibrinogen enhanced monocyte adhesion more than 1.9-fold compared to immobilized albumin or fibrin (P < 0.05). Concomitant addition of the protein kinase C (PKC) inhibitors staurosporine or H7 suppressed monocyte adherence to immobilized fibrinogen but exerted no significant effect upon adhesion to any other surface tested. Stimulation of monocytes using phorbol myristate acetate resulted in increased binding of monocytes on fibrinogen but not on bovine serum albumin. When PKC activity was reduced through prolonged incubation with PMA for 16 h, a significant reduction of monocyte adhesion on fibrinogen was observed. Peptides containing RGD sequences, which have been demonstrated to be ligands for certain integrins, did not inhibit monocyte adhesion. The data suggest that fibrinogen promotes monocyte adhesion in vitro by a PKC-dependent mechanism. PKC appears to be important not only for the initial cell adhesion but also for sustained binding of monocytes to fibrinogen.