cDNA cloning and expression of rat and human protein geranylgeranyltransferase type-I

Identification of spinach farnesyl protein transferase. Dithiothreitol as an acceptor in vitro

Spinach seedlings were found to contain farnesyl protein transferase. The enzyme is activated by Zn2+, but not by Mg2+. The pH optimum is approximately 7.0 and maximal activity is obtained at 40-45 degrees C. The apparent Km for the farnesyl diphosphate substrate is 7 microM. Western blotting of soluble proteins with an antiserum raised against mammalian farnesyl protein transferase demonstrated a specific cross-reactivity with the spinach enzyme. The antiserum preferentially recognises the beta-subunit of the heterodimeric farnesyl protein transferase, and the corresponding spinach polypeptide has a molecular mass of 42 kDa on SDS/PAGE. The enzyme can employ dithiothreitol as an acceptor for the farnesyl moiety and catalyses the formation of a thioether linkage between these substrates. On the basis of this discovery, a new method was developed utilising the hydrophobicity of the reaction product, and its interaction with poly(propylene). During in vivo labelling, the plants took up dithiothreitol, which inhibited the incorporation of [3H]mevalonate metabolites into proteins, indicating that dithiothreitol might be isoprenylated in vivo as well as in vitro. However, isoprenylation of some proteins remains unaffected by dithiothreitol suggesting the existence of different isoprenylation mechanisms. Thus, it is demonstrated that plants possess farnesyl protein transferase, which resembles its mammalian and yeast homologues.

Disruption of oncogenic K-Ras4B processing and signaling by a potent geranylgeranyltransferase I inhibitor

Prenylation of the carboxyl-terminal CAAX (C, cysteine; A, aliphatic acid; and X, any amino acid) of Ras is required for its biological activity. We have designed a CAAX peptidomimetic, GGTI-287, which is 10 times more potent toward inhibiting geranylgeranyltransferase I (GGTase I) in vitro (IC50 = 5 nM) than our previously reported farnesyltransferase inhibitor, FTI-276. In whole cells, the methyl ester derivative of GGTI-287, GGTI-286, was 25-fold more potent (IC50 = 2 microM) than the corresponding methyl ester of FTI-276, FTI-277, toward inhibiting the processing of the geranylgeranylated protein Rap1A. Furthermore, GGTI-286 is highly selective for geranylgeranylation over farnesylation since it inhibited the processing of farnesylated H-Ras only at much higher concentrations (IC50 > 30 microM). While the processing of H-Ras was very sensitive to inhibition by FTI-277 (IC50 = 100 nM), that of K-Ras4B was highly resistant (IC50 = 10 microM). In contrast, we found the processing of K-Ras4B to be much more sensitive to GGTI-286 (IC50 = 2 microM). Furthermore, oncogenic K-Ras4B stimulation inhibited potently by GGTI-286 (IC50 = 1 microM) but weakly by FTI-277 (IC50 = 30 microM). Significant inhibition of oncogenic K-Ras4B stimulation of MAP kinase by GGTI-286 occurred at concentrations (1-3 microM) that did not inhibit oncogenic H-Ras stimulation of MAP kinase. The data presented in this study provide the first demonstration of selective disruption of oncogenic K-Ras4B processing and signaling by a CAAX peptidomimetic. The higher sensitivity of K-Ras4B toward a GGTase I inhibitor has a tremendous impact on future research directions targeting Ras in anticancer therapy.

Photoreactive analogues of prenyl diphosphates as inhibitors and probes of human protein farnesyltransferase and geranylgeranyltransferase type I

Photoreactive analogues of prenyl diphosphates have been useful in studying prenyltransferases. The effectiveness of analogues with different chain lengths as probes of recombinant human protein prenyltransferases is established here. A putative geranylgeranyl diphosphate analogue, 2-diazo-3,3,3-trifluoropropionyloxy-farnesyl diphosphate (DATFP-FPP), was the best inhibitor of both protein farnesyltransferase (PFT) and protein geranylgeranyltransferase-I (PFFT-I). Shorter photoreactive isprenyl diphosphate analogues with geranyl and dimethylallyl moieties and the DATFP-derivative of farnesyl monophosphate were much poorer inhibitors. DATFP-FPP was a competitive inhibitor of both PFT and PGGT-I with Ki values of 100 and 18 nM, respectively. [32P]DATFP-FPP specifically photoradiolabelled the beta-subunits of both PFT and PGGT-I. Photoradiolabelling of PGGT-I was inhibited more effectively by geranylgeranyl diphosphate than farnesyl diphosphate, whereas photoradiolabelling of PFT was inhibited better by farnesyl diphosphate than geranylgeranyl diphosphate. These results lead to the conclusions that DATFP-FPP is an effective probe of the prenyl diphosphate binding domains of PFT and PGGT-I. Furthermore, the beta-subunits of protein prenyltransferases must contribute significantly to the recognition and binding of the isoprenoid substrate.

Protein lipidation in cell signaling

The ability of cells to communicate with and respond to their external environment is critical for their continued existence. A universal feature of this communication is that the external signal must in some way penetrate the lipid bilayer surrounding the cell. In most cases of such signal acquisition, the signaling entity itself does not directly enter the cell but rather transmits its information to specific proteins present on the surface of the cell membrane. These proteins then communicate with additional proteins associated with the intracellular face of the membrane. Membrane localization and function of many of these proteins are dependent on their covalent modification by specific lipids, and it is the processes involved that form the focus of this article.

CAAX geranylgeranyl transferase transfers farnesyl as efficiently as geranylgeranyl to RhoB

RhoB, a small GTP-binding protein, was shown previously to contain farnesyl (C-15) as well as geranylgeranyl (C-20) groups (Adamson, P., Marshall, C. J., Hall, A., and Tilbrook, P. A. (1992) J. Biol. Chem. 267, 20033-20038). The COOH-terminal sequence of the protein is CCKVL. According to current rules of prenylation, the COOH-terminal leucine should render the protein a substrate for CAAX geranylgeranyl transferase (GGTase-1), but not for CAAX farnesyltransferase (FTase). To determine the mechanism of farnesylation, we prepared recombinant RhoB and incubated it with recombinant preparations of either FTase or GGTase-1. RhoB was neither farnesylated nor geranylgeranylated efficiently by FTase, but it was farnesylated as well as geranylgeranylated by GGTase-1. The enzyme attached farnesyl more efficiently than geranylgeranyl to RhoB. Neither farnesylation nor geranylgeranylation required the cysteine at the fifth position from the COOH terminus. However, replacement of the cysteine at the fourth position abolished attachment of both prenyl groups. We conclude that the previously observed farnesylation of RhoB is attributable to the FTase activity of GGTase-1. These data, and other accumulating data, indicate that GGTase-1 is a highly unusual enzyme that efficiently transfers both farnesyl and geranylgeranyl groups and that the choice of prenyl group is dictated by the nature of the protein acceptor.

Depalmitoylation of CAAX motif proteins. Protein structural determinants of palmitate turnover rate

In the present study, we examined the effect of amino acid substitutions on the rate of turnover of palmitate bound to a model "CAAX" motif protein H-Ras. These experiments were designed to shed light on the specificity of the process that removes palmitate from prenylated proteins. H-Ras, protein A-Ras fusion constructs, and constructs with amino acid substitutions in the H-Ras hypervariable region were transfected into COS cells, and the turnover rate of palmitate bound to each expressed protein was measured. We found no evidence for strict sequence specificity for palmitate removal, but found a strong inverse correlation between palmitate turnover rate and the degree of membrane association for any given construct, with slower turnover rates associated with stronger membrane binding. These data support a model in which the palmitate turnover rate is determined by access to a depalmitoylating enzyme and argue against a more complex model in which specific recognition of palmitoylated proteins is required.

Polylysine and CVIM sequences of K-RasB dictate specificity of prenylation and confer resistance to benzodiazepine peptidomimetic in vitro

BZA-5B, a benzodiazepine peptidomimetic, inhibits CAAX farnesyltransferase (FTase) and blocks attachment of farnesyl groups to oncogenic and wild-type H-Ras in animal cells. This compound slows the growth of cells transformed with oncogenic H-Ras at concentrations that do not affect the growth of nontransformed cells. This finding suggested that nontransformed cells may produce a form of Ras whose prenylation is resistant to BZA-5B. In the current studies, we found that FTase had a 50-fold higher affinity for K-RasB than for H-Ras in vitro. Farnesylation of K-RasB was inhibited by BZA-2B, the active form of BZA-5B, but only at concentrations that were 8-fold higher than those that inhibited farnesylation of H-Ras. K-RasB, but not H-Ras, was also a substrate for CAAX geranylgeranyltransferase-1 (GGTase-1), and its affinity for the enzyme was equal to that of Rap1B, an authentic leucine-terminated substrate for GGTase-1. Inhibition of the geranylgeranylation of K-RasB occurred only at high concentrations of BZA-2B. All of these properties of K-RasB were traced to the combined effects of its COOH-terminal CVIM sequence and the adjacent polylysine sequence, neither of which is present in H-Ras. These studies provide a potential explanation for the resistance of nontransformed cells to growth inhibition by BZA-5B. Inasmuch as the majority of Ras-related human cancers contain oncogenic versions of K-RasB rather than H-Ras, the current data suggest that in vitro studies of FTase inhibitors with potential anti-cancer activity should use authentic K-RasB as a substrate.

Lipid modifications of G proteins

Covalent attachment of lipids is a near-universal mechanism through which eukaryotic cells direct and, in some cases, control membrane localization of G proteins. Studies conducted over the past year have substantially advanced our understanding of both the molecular mechanisms and the functional consequences of these modifications. Of particular note are the processes of palmitoylation of the alpha-subunits of heterotrimeric G proteins, and prenylation of members of the Ras superfamily of monomeric G proteins, where recent findings point to unexpected roles for lipid modifications in signaling through these proteins.