Inhibition of human smooth muscle cell proliferation in culture by farnesyl pyrophosphate analogues, inhibitors of in vitro protein:farnesyl transferase

Abstract

In this study, it was investigated whether and how inhibitors of protein:farnesyl transferase (PFT) can inhibit the proliferation of human smooth muscle cells (HSMC) in culture. Several farnesyl pyrophosphate (FPP) analogues were synthesized and tested in vitro for their specificity in inhibiting squalene synthase (SS), PFT, or protein:geranylgeranyl transferase-1 (PGGT-1) activities (the latter was determined using a newly designed assay). One of these compounds appeared to be a strong PFT inhibitor ( ic 50 value: 340 nM) and a weak inhibitor in the other two enzyme assays. This compound (designated as TR006) inhibited the farnesylation of Ras in a Ha- ras transfected cell line (Cohen et al., Biochem Pharmacol49: 839–845, 1995) and concomitantly slowed down the growth of these cells. Twenty-five μM of TR006 inhibited the proliferation of HSMC isolated from left internal mammary artery, as measured by counting the cells over a period of three cell cycles (10 days). A structurally related compound (TR007), a specific SS inhibitor, did not influence HSMC proliferation under the same conditions. The inhibition by TR006 was concentration-dependent. In HSMC, synchronized by serum depletion, platelet-derived growth factor (PDGF) or basic fibroblast growth factor (bFGF)-induced DNA synthesis was decreased by a 29-hr pretreatment with 100 μM of TR006, indicating that this inhibitor acted in an early phase of the cell cycle, probably by preventing protein isoprenylation. Some other FPP analogues with comparable ic 50 values in the in vitro PFT assay were also able to decrease bFGF-induced DNA synthesis without affecting cell viability. A more negatively charged member of this group, TR018, did not influence the growth factor-induced DNA synthesis, probably due to an impaired uptake into the cells. However, the pivaloyloxomethyl derivative of this compound, which is uncharged, and is thought to be converted into TR018 within the cells, showed a strong decrease in bFGF-induced DNA synthesis in HSMC. These data suggest that the compounds investigated may be developed further for treatment of conditions in which undesirable proliferation of smooth muscle cells plays an important role.