Platelet enhancement of tumor cell adhesion to subendothelial matrix: role of platelet cytoskeleton and platelet membrane

Abstract

Platelet involvement during tumor cell adhesion to subendothelial matrix was examined in vitro. Platelets were subjected to thrombin stimulation and mechanical lysis and examined for their effects on tumor cell adhesion. These treatments altered the platelet ultrastructure and cytoskeletal integrity. Untreated washed rat platelets (WRP) exhibited extensive adhesion to and spreading on substrates and substantially enhanced tumor cell adhesion to the same substrates (i.e., 250% greater than tumor cells without platelets). Thrombin prestimulation of platelets limited platelet adhesion and spreading and platelet facilitation of tumor cell adhesion. Complete mechanical lysis disrupted both the platelet membrane and the cytoskeleton and eliminated the ability of platelets to adhere or to enhance tumor cell adhesion. Partially lysed platelets resembled membrane ghosts and facilitated tumor cell adhesion by a mechanism independent of spreading and cytoskeletal rearrangement. Fractionation studies indicated that platelet cytoskeletal components played a role in the adhesion process. Pretreatment of WRP with cytochalasin A or B dose dependently inhibited microfilament-mediated platelet spreading and platelet-enhanced tumor cell adhesion. Colchicine and vinblastine induced microtubule depolymerization, but they had no observable effect on platelet spreading or platelet-enhanced tumor cell adhesion. It was concluded that platelet-enhanced tumor cell adhesion to subendothelial matrix depends on an intact platelet cytoskeleton and on a platelet membrane component(s) and is mediated by surface contact between platelets and tumor cells. Furthermore, platelet-mediated tumor cell adhesion to subendothelial matrix may involve two mechanisms: one dependent on, and one independent of, platelet spreading and cytoskeletal rearrangement.