Ras Processing Research Articles

Tyrosine phosphorylation of focal adhesion kinase by PDGF is dependent on ras in human hepatic stellate cells.

Focal adhesion kinase (FAK) is a widely expressed nonreceptor tyrosine kinase found in focal adhesions. FAK has been indicated as a point of convergence of other signaling pathways including platelet-derived growth factor (PDGF) receptors, and recently, FAK tyrosine phosphorylation has been shown to be stimulated by PDGF. In the present study we assessed the role of Ras as a possible intermediate protein regulating PDGF-induced FAK tyrosine phosphorylation in human hepatic stellate cells (HSCs), liver-specific pericytes primarily involved in the pathogenesis of liver fibrosis. For this purpose, cells were first subjected to retroviral-mediated gene transfer with a dominant-negative mutant of Ras (N17Ras). This resulted in a marked inhibition of PDGF-induced FAK tyrosine phosphorylation together with the expected reduction of PDGF-induced extracellular signal-regulated kinase activity (ERK). Afterward, the effects of pharmacological agents potentially affecting Ras isoprenylation were evaluated. PDGF-induced FAK tyrosine phosphorylation, ERK activity and intracellular calcium increase, as well as the biological effects of this growth factor, (i.e., mitogenesis and cell migration) were effectively blocked by GGTI-298, an inhibitor of geranylgeranyltransferase I. Inhibition of Ras processing obtained with FTI-277, an inhibitor of farnesyltransferase, resulted in detectable effects only at high doses. Taken together, these results establish that Ras operates as a protein-linking PDGF-beta receptor to FAK in human HSCs, and that signaling molecules requiring geranylgeranylation may also be involved in this process.

Differential expression of ras isoforms in hepatic stellate cells

DIFFERENTIAL EXPRESSION OF RAS ISOFORMS IN HEPATIC STELLATE CELLS E Ridolfi, A. Benedetti, A. Di Sario, S. Saccomanno, L. Marucci, E. Bendia, A.M. Jezequel, G. Sve~liati Baroni Dept. of Gastroenterology and Inst. of Exp. Pathology, University of Ancona, Ancona, Italy. Ras proteins represent the products of three different Ras genes (H-, K-, and N-ms) and are plasma membrane-associated GTPases that function as relay switches transducing biological information from extracellular signals to the nucleus. One or the other isoform may predominate in a different cell type where they play a key role in transforming activity and regulating cell proliferation. Hepatic stellate cell (HSC) proliferation close to area of necrosis represent a key event in liver fibrosis and PDGF represents the main mitogen. Aims of the present study ware thus:l)to evaluate the expression of Ras isoforms in activated HSC;2)to determine the effect of blocking Ras signaling on HSC proliferation;3)to determine the intracellular pathways which transduce extracellular signal to the nucleus via Ras proteins. By immunoprecipitation, the H-Ras isoform only was detected in total HSC lysate. This was confirmed by immunohistochemisffy by which the H-Ras isofonn was detected preferentially in the cytoplasmic area. PDGF-stimulated HSC showed a 4-fold increase in cell proliferation as determined by BrdU incorporation in S-phase nuclei. This was blocked by chaetomellic acid (a H-Ras processing inhibitor) which reduced cell proliferation down to control value starting at 2 pM. In addition, chaetomellic acid reduced PDGF-induced ERKll2 phosphorylation while had no effect on 70 kD $6 kinase (a downstream component of the PI3Kinase pathway) activation as determined by Western blot. This study thus indicates that PDGF-induced HSC proliferation is driven by H-Res. Since a non toxic inhibition of Ras processing has been obtained in vivo, H-Ras represents a plausible target for the experimental therapy of hepatic fibrosis. [ P/C03/38 ]

Farnesylation of Ras is important for the interaction with phosphoinositide 3-kinase gamma.

The correct functioning of Ras proteins requires post-translational modification of the GTP hydrolases (GTPases). These modifications provide hydrophobic moieties that lead to the attachment of Ras to the inner side of the plasma membrane. In this study we investigated the role of Ras processing in the interaction with various putative Ras-effector proteins. We describe a specific, GTP-independent interaction between post-translationally modified Ha- and Ki-Ras4B and the G-protein responsive phosphoinositide 3-kinase p110gamma. Our data demonstrate that post-translational processing increases markedly the binding of Ras to p110gamma in vitro and in Sf9 cells, whereas the interaction with p110alpha is unaffected under the same conditions. Using in vitro farnesylated Ras, we show that farnesylation of Ras is sufficient to produce this effect. The complex of p110gamma and farnesylated RasGTP exhibits a reduced dissociation rate leading to the efficient shielding of the GTPase from GTPase activating protein (GAP) action. Moreover, Ras processing affects the dissociation rate of the RasGTP complex with the Ras binding domain (RBD) of Raf-1, indicating that processing induces alterations in the conformation of RasGTP. The results suggest a direct interaction between a moiety present only on fully processed or farnesylated Ras and the putative target protein p110gamma.

Effect of novel CAAX peptidomimetic farnesyltransferase inhibitor on angiogenesis in vitro and in vivo

Ras oncogenes can contribute to tumour development by stimulating vascular endothelial growth factor (VEGF)-dependent angiogenesis. The effect of Ras on angiogenesis may be affected by farnesyltransferase inhibitors (FTI) since farnesylation of Ras is required for its biological activity. In this paper we evaluated the effect of A-170634, a novel and potent CAAX FTI on angiogenesis. Human umbilical vein endothelial cell (HUVEC) tube formation and VEGF secretion were used to assess the effect of A-170634 on angiogenesis in vitro. In vivo, nude mice were injected with the K- ras mutant colon carcinoma cell line HCT116 and treated subcutaneously with A-170634 using osmotic minipump infusion for 10 days. The effect of A-170634 on corneal angiogenesis in vivo was assessed using pellets containing hydron, VEGF, A-170634 or vehicle. In vitro, A-170634 selectively inhibited farnesyltransferase activity over the closely related geranylgeranyltransferase I, inhibited Ras processing, blocked anchorage-dependent and -independent growth of HCT116 K- ras mutated cells, decreased HUVEC capillary structure formation, decreased VEGF secretion from tumour cells and HUVEC growth stimulating activity in a dose-dependent manner. In vivo, tumour growth was decreased by 30% and vascularisation in and around the tumours was reduced by 41% following drug-treatment with no apparent toxicity to the animals. VEGF-induced corneal neovascularisation was reduced by 80% following A-170634 treatment for 7 days. The data presented here demonstrated that A-170634 was a potent and selective peptidomimetic CAAX FTI with anti-angiogenic properties. These results implied that A-170634 may affect tumour growth in vivo by one or more antitumour pathways.

Second-generation peptidomimetic inhibitors of protein farnesyltransferase demonstrating improved cellular potency and significant in vivo efficacy.

The synthesis and evaluation of analogues of previously reported farnesyltransferase inhibitors, pyridyl benzyl ether 3 and pyridylbenzylamine 4, are described. Substitution of 3 at the 5-position of the core aryl ring resulted in inhibitors of equal or less potency against the enzyme and decreased efficacy in a cellular assay against Ras processing by the enzyme. Substitution of 4 at the benzyl nitrogen yielded 26, which showed improved efficacy and potency and yet presented a poor pharmacokinetic profile. Further modification afforded 30, which demonstrated a dramatically improved pharmacokinetic profile. Compounds 26 and 29 demonstrated significant in vivo efficacy in nude mice inoculated with MiaPaCa-2, a human pancreatic tumor-derived cell line.

Apoptosis of medulloblastoma cells in vitro follows inhibition of farnesylation using manumycin A.

Medulloblastoma is a malignant cerebellar tumor usually manifesting in childhood. We have previously shown that blocking the mevalonate pathway with lovastatin, a competitive inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, inhibits medulloblastoma proliferation and induces apoptosis in vitro. The underlying mechanism may involve blocking post-translational modification of important mitogenic signal-transduction proteins. We show that p21 ras processing is blocked by lovastatin, suggesting that inhibition of isoprenylation may be important in lovastatin-induced apoptosis. To test this hypothesis, manumycin A, an antibiotic which inhibits farnesyl protein transferase and thus farnesylation, was administered to 4 medulloblastoma cell lines in vitro. We found that blocking protein farnesylation with manumycin A was followed by apoptosis in a time- and dose-dependent manner. However, cell death induced by manumycin A was uniformly more rapid and efficient, requiring only 12 to 24 hr of treatment, than lovastatin-induced apoptosis, which required 36 to 96 hr (depending on the cell line tested). In addition, unlike lovastatin, which caused cell-cycle arrest in G1 phase and HMG-CoA reductase gene up-regulation, manumycin A had no effect on the cell cycle and resulted in down-regulation of HMG-CoA reductase gene expression. In both lovastatin- and manumycin A-treated cells, cellular cysteine protease precursor (CPP32) was activated, confirming the occurrence of apoptosis.

Characterization of Lectin Resistant Cell Populations Derived from Human Colon Carcinoma: Correlation of K-Ras with β1-6 Branching of N-Linked Carbohydrate and CEA Production

Previous studies of cell lines derived from human colon carcinoma showed that the extent of β1-6 branching on N-linked carbohydrate was associated with the presence of K-ras mutation and Ras-activation. We observed that the extent of Ras-activation in these cell lines depends not only upon the presence of an activating mutation in K-ras, but also on the amount of total K-Ras protein produced. Here we examined whether negative selective pressure by PHA-L against β1-6 branching could select for cells having a lower level of K-Ras protein and Ras-activation. PHA-L binds specifically to the β1-6 branch in N-linked carbohydrate. We utilized a K-ras mutant colon carcinoma cell line, HTB39, which had abundant β1-6 branching and high levels of K-Ras mutant protein. Lectin resistant cell populations of HTB39 were generated and found to have less β1-6 branching and less K-Ras protein than their parental counterpart. The lectin resistant cell populations produced lower levels of highly glycosylated CEA, which contributed to the lower level of β1-6 branching in these cells. PHA-L resistant cell populations were two-fold less sensitive than the parental line to an inhibitor of farnesyl transferase (an enzyme essential for Ras processing and function). This suggested a decrease in dependence on K-ras mediated signaling. Collectively, the data indicated that β1-6 branching of N-linked carbohydrate and CEA production were linked to K-Ras protein synthesis and activation of the Ras-signaling pathway.

Hyperactive Ras as a therapeutic target in neurofibromatosis type 1

The NF1 gene encodes neurofibromin, a GTPase-activating protein (GAP) for members of the p21(ras) (Ras) family, which negatively regulates Ras output by accelerating the conversion of active Ras. GTP to inactive Ras.GDP. Analysis of tumors from patients with neurofibromatosis type 1 (NF1) has shown biochemical evidence of hyperactive Ras as well as frequent loss of the normal NF1 allele, consistent with its role as a tumor suppressor gene. Taken together, these data suggest that novel therapeutics directed against components of the Ras signaling cascade might provide effective treatments for certain pathological complications of NF1. Here we summarize data that support a role for hyperactive Ras in NF1 disease, including Ras processing, activation, and down-regulation. We review targets for rational drug design, provide preliminary results, and discuss implications for future studies. Am. J. Med. Genet. (Semin. Med. Genet.) 89:14-22, 1999.

Disruption of the Mouse Rce1 Gene Results in Defective Ras Processing and Mislocalization of Ras within Cells

Little is known about the enzyme(s) required for the endoproteolytic processing of mammalian Ras proteins. We identified a mouse gene (designated Rce1) that shares sequence homology with a yeast gene (RCE1) implicated in the proteolytic processing of Ras2p. To define the role of Rce1 in mammalian Ras processing, we generated and analyzed Rce1-deficient mice. Rce1 deficiency was lethal late in embryonic development (after embryonic day 15.5). Multiple lines of evidence revealed that Rce1-deficient embryos and cells lacked the ability to endoproteolytically process Ras proteins. First, Ras proteins from Rce1-deficient cells migrated more slowly on SDS-polyacrylamide gels than Ras proteins from wild-type embryos and fibroblasts. Second, metabolic labeling of Rce1-deficient cells revealed that the Ras proteins were not carboxymethylated. Finally, membranes from Rce1-deficient fibroblasts lacked the capacity to proteolytically process farnesylated Ha-Ras, N-Ras, and Ki-Ras or geranylgeranylated Ki-Ras. The processing of two other prenylated proteins, the farnesylated Ggamma1 subunit of transducin and geranylgeranylated Rap1B, was also blocked. The absence of endoproteolytic processing and carboxymethylation caused Ras proteins to be mislocalized within cells. These studies indicate that Rce1 is responsible for the endoproteolytic processing of the Ras proteins in mammals and suggest a broad role for this gene in processing other prenylated CAAX proteins.

Dexamethasone-induced decrease in HMG-CoA reductase and protein-farnesyl transferase activities does not impair ras processing in AR 4-2J cells.

Rat pancreatic acinar cells AR 4-2J respond to dexamethasone by differentiation and a decreased proliferation rate. Protein labelling by [3H]-mevalonolactone, used as a precursor of farnesyl and geranylgeranyl isoprenoid groups, was increased in the presence of dexamethasone. In these same conditions, dexamethasone decreased HMG-CoA reductase activity, leading to a diminished isotopic dilution of the mevalonate precursor. As ras proteins, known to be involved in the regulation of proliferation and differentiation, need to be farnesylated for full biological function, we also measured the level of farnesyl transferase activity and found a dose-dependent decrease in dexamethasone treated cells. Despite these negative effects of dexamethasone on mevalonate pathway, there was no appearance of non-isoprenylated forms of ras, indicating that the level of isoprenoid precursors and farnesyl transferase activity were not limiting in this model.

Clavaric acid and steroidal analogues as Ras- and FPP-directed inhibitors of human farnesyl-protein transferase.

We have identified a novel fungal metabolite that is an inhibitor of human farnesyl-protein transferase (FPTase) by randomly screening natural product extracts using a high-throughput biochemical assay. Clavaric acid [24, 25-dihydroxy-2-(3-hydroxy-3-methylglutaryl)lanostan-3-one] was isolated from Clavariadelphus truncatus; it specifically inhibits human FPTase (IC50 = 1.3 microM) and does not inhibit geranylgeranyl-protein transferase-I (GGPTase-I) or squalene synthase activity. It is competitive with respect to Ras and is a reversible inhibitor of FPTase. An alkaline hydrolysis product of clavaric acid, clavarinone [2,24,25-trihydroxylanostan-3-one], lacking the 3-hydroxy-3-methylglutaric acid side chain is less active as a FPTase inhibitor. Similarly, a methyl ester derivative of clavaric acid is also inactive. In Rat1 ras-transformed cells clavaric acid and lovastatin inhibited Ras processing without being overtly cytotoxic. Excess mevalonate reversed the effects of lovastatin but not of clavaric acid suggesting that the block on Ras processing by clavaric acid was due to inhibition of FPTase and not due to inhibition of HMG-CoA reductase. Despite these results, the possibility existed that clavaric acid inhibited Ras processing by directly inhibiting HMG-CoA reductase. To directly examine the effects of clavaric acid and clavarinone on HMG-CoA reductase, cholesterol synthesis was measured in HepG2 cells. No inhibition of HMG-CoA reductase was observed indicating that the inhibition of Ras processing by this class of compounds is due to inhibition of FPTase. To date, clavaric acid is the second reported nitrogen-free compound that competes with Ras to inhibit FPTase activity. A series of related compounds derived from computer-based similarity searches and subsequent rational chemical synthetic design provided compounds that exhibited a range of activity (0.04 --> 100 microM) against FPTase. Modest changes in the structures of these inhibitors dramatically change the inhibitory activity of these inhibitors.

A Farnesyl-Protein Transferase Inhibitor Induces p21 Expression and G1 Block in p53 Wild Type Tumor Cells

Farnesylation is required for the membrane partition and function of several proteins, including Ras. Farnesyl-protein transferase inhibitors (FTIs) were developed to prevent Ras processing and thus to be effective agents for the treatment of cancers harboring mutated ras. However, FTIs inhibit the growth of most tumor cells and several xenograft models, irrespective of whether they possess mutated ras. Furthermore, the antiproliferative effect is not correlated with inhibition of Ki-Ras processing; tumors with wild type ras are inhibited, and FTIs are not particularly toxic. These data suggest that the mechanism of FTI action is complex and may involve other targets besides Ras. To begin to understand how FTIs work, we investigated the mechanism of growth inhibition. FTI causes G1 arrest in a subset of sensitive lines. This is accomplished by transcriptional induction of p21, which mediates the inhibition of cyclin E-associated protein kinase activity, pRb hypophosphorylation and inhibition of DNA replication. Induction of p21 is p53-dependent; it does not occur in cells with mutant p53 or in cells expressing human papillomavirus E6. However, neither p53 nor p21 are required for inhibition of cell proliferation. FTI still blocks the growth of cells deficient in these proteins. In the absence of p21, G1 block is relaxed, DNA replication is not affected, and cells become polyploid and undergo apoptosis. These results suggest that farnesylated protein(s) may be involved in regulating p53 function and in coordinating entrance into S, and that the consequences of FTI treatment are a function of the other mutations found in the tumor cell.

J-104,871, a novel farnesyltransferase inhibitor, blocks Ras farnesylation in vivo in a farnesyl pyrophosphate-competitive manner.

Farnesylation of the activated ras oncogene product by protein farnesyltransferase (FTase) is a critical step for its oncogenic function. Because squalene synthase and FTase recruit farnesyl pyrophosphate as a common substrate, we modified squalene synthase (SS) inhibitors to develop FTase inhibitors. Among the compounds tested, a novel FTase inhibitor termed J-104,871 inhibited rat brain FTase with an IC50 of 3.9 nM in the presence of 0.6 microM farnesyl pyrophosphate (FPP), whereas it scarcely inhibited rat brain protein geranylgeranyltransferase-I or SS. The in vitro inhibition of rat brain FTase by J-104,871 depends on the FPP concentration but not on the concentration of Ras peptide. Thus, in vitro studies strongly suggest that J-series compounds have an FPP-competitive nature. J-104,871 also inhibited Ras processing in activated H-ras-transformed NIH3T3 cells with an IC50 value of 3.1 microM. We tested the effects of lovastatin and zaragozic acid A, which modify cellular FPP levels, on Ras processing of J-104,871. Lovastatin, a hepatic hydroxymenthyl coenzyme A reductase inhibitor that reduced the cellular FPP pool, increased the activity of J-104,871, whereas 3 microM zaragozic acid A, an SS inhibitor that raised the FPP level, completely abrogated the activity of J-104,871 even at 100 microM. These results suggest that J-104,871 inhibits FTase in an FPP-competitive manner in whole cells as well as in the in vitro system. Furthermore, J-104,871 suppressed tumor growth in nude mice transplanted with activated H-ras-transformed NIH3T3 cells.

Both farnesyltransferase and geranylgeranyltransferase I inhibitors are required for inhibition of oncogenic K-Ras prenylation but each alone is sufficient to suppress human tumor growth in nude mouse xenografts.

The ability of Ras oncoproteins to cause malignant transformation requires their post-translational modifications by prenyl groups. Because K-Ras can be both farnesylated and geranylgeranylated it is not known whether both farnesyltransferase and geranylgeranyltransferase I inhibitors are required for suppressing human tumor growth in whole animals. In this paper we report that oncogenic Ras processing, MAP kinase activation and growth in nude mice are inhibited by the farnesyltransferase inhibitor FTI-276 in H- and N-Ras transformed NIH3T3 cells; whereas in KB-Ras transformed NIH3T3 cells both FTI-276 and the geranylgeranyltransferase I inhibitor GGTI-297 are required for inhibition. Furthermore, human lung A-549 and Calu-1 carcinoma cell lines were found to co-express H-, N- and K-Ras. In Calu-1 cells, the processing of H- and N-Ras is inhibited greatly by FTI-276 but only partially by GGTI-297 whereas K-Ras processing inhibition requires both FTI-276 and GGTI-297. In contrast, in A-549 cells the processing of H- and N-Ras is inhibited only by FTI-276 and K-Ras processing is resistant to co-treatment with FTI-276 and GGTI-297. Yet, the growth in nude mice of A-549 and Calu-1 xenografts, both of which express K-Ras mutations, is inhibited by FTI-276 (80% inhibition) and GGTI-297 (60%). Furthermore, FTI-276 inhibits tumor growth of NIH3T3 cells transformed by a form of oncogenic H-Ras that is exclusively geranylgeranylated and whose processing is resistant to this inhibitor. Taken together, the results demonstrate that both FTase and GGTase I inhibitors are required for inhibition of K-Ras processing but that each alone is sufficient to suppress human tumor growth in nude mice.

Stereochemistry-dependent inhibition of RAS farnesylation by farnesyl phosphonic acids.

This investigation compares the effects of three farnesyl pyrophosphate analogs on selected aspects of isoprenoid metabolism. E,E-alpha-Hydroxyfarnesylphosphonate was prepared by an improved variation on a literature synthesis, which also gave access to the new Z,E-alpha-hydroxyfarnesyl- and alpha-hydroxygeranylphosphonates. A striking find is that only E,E-alpha-hydroxyfarnesylphosphonate induces alteration of RAS processing in intact human-derived leukemia cells and inhibits farnesyl protein transferase in enzyme assays, while the Z,E-alpha-farnesyl- and geranylphosphonates are inactive. The inhibitory activity of E,E-alpha-hydroxyfarnesylphosphonate is greater in enzyme than intact cell assays. This active compound does not significantly inhibit geranylgeranyl protein transferase I or squalene synthase, nor does it diminish cholesterol synthesis. These results indicate that the length of the terpenoid chain and olefin stereochemistry allow selective inhibition of critical enzymes of terpenoid metabolism. Discrimination was observed between inhibition of farnesyl protein transferase and squalene synthase by E,E-alpha-hydroxyfarnesylphosphonate, even though both enzymes utilize farnesyl pyrophosphate as their natural substrate.

Induction of the cholesterol metabolic pathway regulates the farnesylation of RAS in embryonic chick heart cells: a new role for ras in regulating the expression of muscarinic receptors and G proteins.

We propose a novel mechanism for the regulation of the processing of Ras and demonstrate a new function for Ras in regulating the expression of cardiac autonomic receptors and their associated G proteins. We have demonstrated previously that induction of endogenous cholesterol synthesis in cultured cardiac myocytes resulted in a coordinated increase in expression of muscarinic receptors, the G protein alpha-subunit, G-alphai2, and the inward rectifying K+ channel, GIRK1. These changes in gene expression were associated with a marked increase in the response of heart cells to parasympathetic stimulation. In this study, we demonstrate that the induction of the cholesterol metabolic pathway regulates Ras processing and that Ras regulates expression of G-alphai2. We show that in primary cultured myocytes most of the RAS is localized to the cytoplasm in an unfarnesylated form. Induction of the cholesterol metabolic pathway results in increased farnesylation and membrane association of RAS. Studies of Ras mutants expressed in cultured heart cells demonstrate that activation of Ras by induction of the cholesterol metabolic pathway results in increased expression of G-alphai2 mRNA. Hence farnesylation of Ras is a regulatable process that plays a novel role in the control of second messenger pathways.

The Ras-related Protein Rheb Is Farnesylated and Antagonizes Ras Signaling and Transformation

Presently, nothing is known about the function of the Ras-related protein Rheb. Since Rheb shares significant sequence identity with the core effector domains of Ras and KRev-1/Rap1A, it may share functional similarities with these two structurally related, yet functionally distinct, small GTPases. Furthermore, since like Ras, Rheb terminates with a COOH terminus that is likely to signal for farnesylation, it may be a target for the farnesyltransferase inhibitors that block Ras processing and function. To compare Rheb function with those of Ras and KRev-1, we introduced mutations into Rheb that generate constitutively active or dominant negative forms of Ras and Ras-related proteins and were designated Rheb(64L) and Rheb(20N), respectively. Expression of wild type or mutant Rheb did not alter the morphology or growth properties of NIH 3T3 cells. Thus, aberrant Rheb function is distinct from that of Ras and fails to cause cellular transformation. Instead, similar to KRev-1, co-expression of Rheb antagonized oncogenic Ras transformation and signaling. In vitro and in vivo analyses showed that like Ras, Rheb proteins are farnesylated and are sensitive to farnesyltransferase inhibition. Thus, it is possible that Rheb function may be inhibited by farnesyltransferase inhibitors treatment and, consequently, may contribute to the ability of these inhibitors to impair Ras transformation.

Farnesyltransferase as a target for anticancer drug design

The currently understood function for Ras in signal transduction is in mediating the transmission of signals from external growth factors to the cell nucleus. Mutated forms of this GTP-binding protein are found in 30% of human cancers with particularly high prevalence in colon and pancreatic carcinomas. These mutations destroy the GTPase activity of Ras and cause the protein to be locked in its active, GTP bound form. As a result, the signaling pathways are activated, leading to uncontrolled tumor growth. Ras function in signaling requires its association with the plasma membrane. This is achieved by posttranslational farnesylation of a cysteine residue present as part of the CA1A2X carboxyl terminal tetrapeptide of all Ras proteins. The enzyme that recognizes and farnesylates the CA1A2X sequence, Ras farnesyltransferase (FTase), has become an important target for the design of inhibitors that might be interesting as antitumor agents. Several approaches have been taken in the search for in vivo active inhibitors of farnesyltransferase. These include the identification of natural products such as the chaetomellic and zaragozic acids that mimic farnesylpyrophosphate, bisubstrate transition state analogs combining elements of the farnesyl and tetrapeptide substrates and peptidomimetics that reproduce features of the carboxyl terminal tetrapeptide CA1A2X sequence. This last group of compounds has been most successful in showing highly potent inhibition of FTase and selective blocking of Ras processing in a range of Ras transformed tumor cell lines at concentrations as low as 10 nM. Certain peptidomimetics will also block tumor growth in various mouse models, with apparently few toxic side effects. These results suggest that farnesyltransferase inhibitors hold considerable promise as anticancer drugs in the clinic.

Lovastatin Inhibits T-Cell Antigen Receptor Signaling Independent of Its Effects on ras

Lovastatin, a cholesterol-lowering drug, has antiproliferative properties that may be related to its inhibition of protein isoprenylation. We examined the effects of lovastatin on signal transduction via the T-cell antigen receptor (TCR). Lovastatin inhibited both proximal and distal TCR-mediated signaling events in a time- and concentration-dependent manner in the human Jurkat T-cell line. Upregulation of CD69 surface expression after TCR stimulation was blocked by lovastatin, although no inhibition of phorbol ester-induced CD69 expression was noted. Proximal TCR-mediated signaling events, including intracellular calcium mobilization, inositol phosphate production, and tyrosine phosphorylation of phospholipase Cgamma1, were similarly inhibited by lovastatin, although global protein tyrosine kinase activity remained intact. In a Jurkat variant transfected with the human type-1 muscarinic receptor, lovastatin also inhibited TCR-mediated calcium mobilization and inositol phosphate production but failed to affect muscarinic receptor-induced responses. Lovastatin, at similar doses, also disrupted post-translational processing of ras and inhibited ras-dependent signals, including phosphorylation and activation of mitogen-associated protein kinase after TCR stimulation. These findings suggest that the antiproliferative properties of lovastatin may be independent of ras and could result from uncoupling protein tyrosine kinases from distinct signal transduction pathways.

Solubilization, partial purification, and affinity labeling of the membrane-bound isoprenylated protein endoprotease.

A previously described [Ma, Y.-T., & Rando, R. R. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 6275-6279] membrane-associated isoprenylated protein endoprotease is important in the processing of isoprenylated proteins terminating with CAAX. The enzyme is of substantial interest because specific inhibitors of it block the processing and functioning of ras in vivo. The enzyme appears to be an integral membrane protein, as it can only be removed from microsomal membranes with detergent. The enzyme is effectively solubilized by the detergent CHAPSO and can be partially purified (approximately 10-fold) by anion ion exchange and size exclusion chromatography. Attempts to further purify the enzyme by other column means, including affinity chromatography, were unsuccessful. The partially purified enzyme is very sensitive to thiol reagents but insensitive to other kinds of protease inhibitors, suggesting that the enzyme is a thiol protease. Potent and specific chloroketone containing affinity labeling agents have been developed. These novel inactivators owe their potency to an S-farnesylcysteine moiety which is recognized by the enzyme. Specific inhibitors of this type should allow for the identification and cloning of this protease, which is important for signal transduction.