Identification of Novel Peptide Substrates for Protein Farnesyltransferase Reveals Two Substrate Classes with Distinct Sequence Selectivities

Prenylation is a posttranslational modification essential for the proper localization and function of many proteins. Farnesylation, the attachment of a 15-carbon farnesyl group near the C-terminus of protein substrates, is catalyzed by protein farnesyltransferase (FTase). Farnesylation has received significant interest as a target for pharmaceutical development, and farnesyltransferase inhibitors are in clinical trials as cancer therapeutics. However, as the total complement of prenylated proteins is unknown, the FTase substrates responsible for farnesyltransferase inhibitor efficacy are not yet understood. Identifying novel prenylated proteins within the human proteome constitutes an important step towards understanding prenylation-dependent cellular processes. Based on sequence preferences for FTase derived from analysis of known farnesylated proteins, we selected and screened a library of small peptides representing the C-termini of 213 human proteins for activity with FTase. We identified 77 novel FTase substrates that exhibit multiple-turnover (MTO) reactivity within this library; our library also contained 85 peptides that can be farnesylated by FTase only under single-turnover (STO) conditions. Based on these results, a second library was designed that yielded an additional 29 novel MTO FTase substrates and 45 STO substrates. The two classes of substrates exhibit different specificity requirements. Efficient MTO reactivity correlates with the presence of a nonpolar amino acid at the a₂ position and a Phe, Met, or Gln at the terminal X residue, consistent with the proposed Ca₁a₂X sequence model. In contrast, the sequences of the STO substrates vary significantly more at both the a₂ and the X residues and are not well described by current farnesylation algorithms. These results improve the definition of prenyltransferase substrate specificity, test the efficacy of substrate algorithms, and provide valuable information about therapeutic targets. Finally, these data illuminate the potential for in vivo regulation of prenylation through modulation of STO versus MTO peptide reactivity with FTase.     

Mutagenesis studies of protein farnesyltransferase implicate aspartate beta 352 as a magnesium ligand

Protein farnesyltransferase (FTase) catalyzes the addition of a farnesyl chain onto the sulfur of a C-terminal cysteine of a protein substrate. Magnesium ions enhance farnesylation catalyzed by FTase by several hundred-fold, with a KMg value of 4 mM. The magnesium ion is proposed to coordinate the diphosphate leaving group of farnesyldiphosphate (FPP) to stabilize the developing charge in the farnesylation transition state. Here we further investigate the magnesium binding site using mutagenesis and biochemical studies. Free FPP binds Mg2+ with a Kd of 120 microM. The 10-fold weaker affinity for Mg2+ observed for the FTase.FPP.peptide ternary complex is probably caused by the positive charges in the diphosphate binding pocket of FTase. Furthermore, mutation of aspartate beta 352 to alanine (D beta 352A) or lysine (D beta 352K) in FTase drastically alters the Mg2+ dependence of FTase catalysis without dramatically affecting the rate constant of farnesylation minus magnesium or the binding affinity of either substrate. In D beta 352A FTase, the KMg increases 28-fold to 110 +/- 30 mM, and the farnesylation rate constant at saturating Mg2+ decreases 27-fold to 0.30 +/- 0.05 s-1. Substitution of a lysine for Asp-beta 352 removes the magnesium activation of farnesylation catalyzed by FTase but does not significantly enhance the rate constant for farnesylation in the absence of Mg2+. In wild type FTase, Mg2+ can be replaced by Mn2+ with a 2-fold lower KMn (2 mM). These results suggest both that Mg2+ coordinates the side chain carboxylate of Asp-beta 352 and that the role of magnesium in the reaction includes positioning the FPP prior to catalysis.     

Peptide specificity of protein prenyltransferases is determined mainly by reactivity rather than binding affinity

Protein farnesyltransferase (FTase) and protein geranylgeranyltransferase type I (GGTase I) catalyze the attachment of lipid groups from farnesyl diphosphate and geranylgeranyl diphosphate, respectively, to a cysteine near the C-terminus of protein substrates. FTase and GGTase I modify several important signaling and regulatory proteins with C-terminal CaaX sequences ("C" refers to the cysteine residue that becomes prenylated, "a" refers to any aliphatic amino acid, and "X" refers to any amino acid). In the CaaX paradigm, the C-terminal X-residue of the protein/peptide confers specificity for FTase or GGTase I. However, some proteins, such as K-Ras, RhoB, and TC21, are substrates for both FTase and GGTase I. Here we demonstrate that the C-terminal amino acid affects the binding affinity of K-Ras4B-derived hexapeptides (TKCVIX) to FTase and GGTase I modestly. In contrast, reactivity, as indicated by transient and steady-state kinetics, varies significantly and correlates with hydrophobicity, volume, and structure of the C-terminal amino acid. The reactivity of FTase decreases as the hydrophobicity of the C-terminal amino acid increases whereas the reactivity of GGTase I increases with the hydrophobicity of the X-group. Therefore, the hydrophobicity, as well as the structure of the X-group, determines whether peptides are specific for farnesylation, geranylgeranylation, or dual prenylation.     

Crystallographic analysis of CaaX prenyltransferases complexed with substrates defines rules of protein substrate selectivity

Post-translational modifications are essential for the proper function of many proteins in the cell. The attachment of an isoprenoid lipid (a process termed prenylation) by protein farnesyltransferase (FTase) or geranylgeranyltransferase type I (GGTase-I) is essential for the function of many signal transduction proteins involved in growth, differentiation, and oncogenesis. FTase and GGTase-I (also called the CaaX prenyltransferases) recognize protein substrates with a C-terminal tetrapeptide recognition motif called the Ca1a2X box. These enzymes possess distinct but overlapping protein substrate specificity that is determined primarily by the sequence identity of the Ca1a2X motif. To determine how the identity of the Ca1a2X motif residues and sequence upstream of this motif affect substrate binding, we have solved crystal structures of FTase and GGTase-I complexed with a total of eight cognate and cross-reactive substrate peptides, including those derived from the C termini of the oncoproteins K-Ras4B, H-Ras and TC21. These structures suggest that all peptide substrates adopt a common binding mode in the FTase and GGTase-I active site. Unexpectedly, while the X residue of the Ca1a2X motif binds in the same location for all GGTase-I substrates, the X residue of FTase substrates can bind in one of two different sites. Together, these structures outline a series of rules that govern substrate peptide selectivity; these rules were utilized to classify known protein substrates of CaaX prenyltransferases and to generate a list of hypothetical substrates within the human genome.     

Protein farnesyl transferase target selectivity is dependent upon peptide stimulated product release

Protein farnesyl transferase (FTase) catalyzes transfer of a 15 carbon farnesyl lipid to cysteine in the C-terminal Ca1a2X sequence of numerous proteins including Ras. Previous studies have shown that product release is rate limiting and is dependent on binding of either a new peptide or isoprenoid diphosphate substrate. While considerable progress has been made in understanding how FTase distinguishes between related target proteins, the relative importance of the two pathways for product release on substrate selectivity is unclear. A detailed analysis of substrate stimulated product release has now been performed and provides new insights into the mechanism of FTase target selectivity. To clarify how FTase selects between different Ca1a2X sequences, we have examined the competition of various peptide substrates for modification with the isoprenoids farnesyl diphosphate (FPP) and anilinogeranyl diphosphate (AGPP). We find that reactivity of some competing peptides is correlated with apparent Kmpeptide, while the reactivity of others is predicted by the selectivity factor apparent kcat/Kmpeptide. The peptide target selectivity also depends on the structure of the isoprenoid donor. Additionally, we observe two peptide substrate concentration dependent maxima and substrate inhibition in the steady-state reaction which require a minimum of three peptide binding states for the steady-state FTase reaction mechanism. We propose a model for the FTase reaction mechanism that, in addition to FPP stimulated product release, incorporates peptide binding to the FTase-FPP complex and the formation of an FTase-product-peptide complex followed by product release leading to an inhibitory FTase-peptide complex as a natural consequence of catalysis to explain these results.     

Interplay of isoprenoid and peptide substrate specificity in protein farnesyltransferase

Protein farnesyltransferase (FTase) catalyzes the post-translational modification of many important cellular proteins, and is a potential anticancer drug target. Crystal structures of the FTase ternary complex illustrate an unusual feature of this enzyme, the fact that the isoprenoid substrate farnesyl diphosphate (FPP) forms part of the binding site for the peptide substrate. This implies that changing the structure of FPP could alter the specificity of the FPP-FTase complex for peptide substrates. We have found that this is the case; a newly synthesized FPP analogue, 3-MeBFPP, is a substrate with three peptide cosubstrates, but is not an effective substrate with a fourth peptide (dansyl-GCKVL). Addition of this analogue also inhibits farnesylation of dansyl-GCKVL by FPP. Surprisingly, the differential substrate abilities of these four peptides with FPP-FTase and 3-MeBFPP-FTase complexes do not correlate with their binding affinities for these isoprenoid-enzyme complexes. The possible mechanistic rationales for this observation, along with its potential utility for the study of protein prenylation, are discussed.     

Preventing farnesylation of the dynein adaptor Spindly contributes to the mitotic defects caused by farnesyltransferase inhibitors

The clinical interest in farnesyltransferase inhibitors (FTIs) makes it important to understand how these compounds affect cellular processes involving farnesylated proteins. Mitotic abnormalities observed after treatment with FTIs have so far been attributed to defects in the farnesylation of the outer kinetochore proteins CENP-E and CENP-F, which are involved in chromosome congression and spindle assembly checkpoint signaling. Here we identify the cytoplasmic dynein adaptor Spindly as an additional component of the outer kinetochore that is modified by farnesyltransferase (FTase). We show that farnesylation of Spindly is essential for its localization, and thus for the proper localization of dynein and its cofactor dynactin, to prometaphase kinetochores and that Spindly kinetochore recruitment is more severely affected by FTase inhibition than kinetochore recruitment of CENP-E and CENP-F. Molecular replacement experiments show that both Spindly and CENP-E farnesylation are required for efficient chromosome congression. The identification of Spindly as a new mitotic substrate of FTase provides insight into the causes of the mitotic phenotypes observed with FTase inhibitors.     

Farnesylation of nonpeptidic thiol compounds by protein farnesyltransferase

Protein farnesyltransferase catalyzes the modification of protein substrates containing specific carboxyl-terminal Ca(1)a(2)X motifs with a 15-carbon farnesyl group. The thioether linkage is formed between the cysteine of the Ca(1)a(2)X motif and C1 of the farnesyl group. Protein substrate specificity is essential to the function of the enzyme and has been exploited to find enzyme-specific inhibitors for antitumor therapies. In this work, we investigate the thiol substrate specificity of protein farnesyltransferase by demonstrating that a variety of nonpeptidic thiol compounds, including glutathione and dithiothreitol, are substrates. However, the binding energy of these thiols is decreased 4-6 kcal/mol compared to a peptide derived from the carboxyl terminus of H-Ras. Furthermore, for these thiol substrates, both the farnesylation rate constant and the apparent magnesium affinity decrease significantly. Surprisingly, no correlation is observed between the pH-independent log(k(max)) and the thiol pK(a); model nucleophilic reactions of thiols display a Br?nsted correlation of approximately 0.4. These data demonstrate that zinc-sulfur coordination is a primary criterion for classification as a FTase substrate, but other interactions between the peptide and the FTase.isoprenoid complex provide significant enhancement of binding and catalysis. Finally, these results suggest that the mechanism of FTase provides in vivo selectivity for the farnesylation of protein substrates even in the presence of high concentrations of intracellular thiols.     

Novel limonene phosphonate and farnesyl diphosphate analogues: design, synthesis, and evaluation as potential protein-farnesyl transferase inhibitors

Limonene and its metabolite perillyl alcohol are naturally-occurring isoprenoids that block the growth of cancer cells both in vitro and in vivo. This cytostatic effect appears to be due, at least in part, to the fact that these compounds are weak yet selective and non-toxic inhibitors of protein prenylation. Protein-farnesyl transferase (FTase), the enzyme responsible for protein farnesylation, has become a key target for the rational design of cancer chemotherapeutic agents. Therefore, several alpha-hydroxyphosphonate derivatives of limonene were designed and synthesized as potentially more potent FTase inhibitors. A noteworthy feature of the synthesis was the use of trimethylsilyl triflate as a mild, neutral deprotection method for the preparation of sensitive phosphonates from the corresponding tert-butyl phosphonate esters. Evaluation of these compounds demonstrates that they are exceptionally poor FTase inhibitors in vitro (IC50 > or = 3 mM) and they have no effect on protein farnesylation in cells. In contrast, farnesyl phosphonyl(methyl)phosphinate, a diphosphate-modified derivative of the natural substrate farnesyl diphosphate, is a very potent FTase inhibitor in vitro (Ki=23 nM).     

Upstream polybasic region in peptides enhances dual specificity for prenylation by both farnesyltransferase and geranylgeranyltransferase type I

Protein farnesyltransferase (FTase) and protein geranylgeranyltransferase type I (GGTase I) catalyze the attachment of a farnesyl or geranylgeranyl lipid, respectively, near the C-terminus of their protein substrates. FTase and GGTase I differ in both their substrate specificity and magnesium dependence, where the activity of FTase, but not GGTase I, is activated by magnesium. Many protein substrates of these enzymes contain an upstream polybasic region that is proposed to increase the affinity of the substrate and aid in plasma membrane association. Here, we demonstrate that the addition of an upstream polybasic region to a peptide substrate enhances the binding affinity of FTase approximately 4-fold for the peptide but diminishes the catalytic efficiency of the reaction, reflected by decreases in both the prenylation rate constant and kcat/KM. Specifically, the prenylation rate constant decreases 7-fold at 5 mM MgCl2 for the peptide KKKSKTKCVIM (C-terminal sequence of K-Ras4B) in comparison to TKCVIM. This decrease is accompanied by an alteration in the dependence on magnesium, as the K(Mg) increases from 2.2 +/- 0.1 mM for TKCVIM to 11.5 +/- 0.1 mM for KKKSKTKCVIM. The presence of an upstream polybasic region does not significantly affect GGTase I-catalyzed reactions, as only minimal changes are seen in Kd, kcat/KM, and k(chem) values. Thus, the presence of an upstream polybasic region enhances the dual prenylation of these substrates, by decreasing the catalytic efficiency of farnesylation catalyzed by FTase to a level comparable to that of geranylgeranylation catalyzed by GGTase I.     

Genetic evidence for in vivo cross-specificity of the CaaX-box protein prenyltransferases farnesyltransferase and geranylgeranyltransferase-I in Saccharomyces cerevisiae.

Two protein prenyltransferase enzymes, farnesyltransferase (FTase) and geranylgeranyltransferase-I (GGTase-I), catalyze the covalent attachment of a farnesyl or geranylgeranyl lipid group to the cysteine of a CaaX sequence (cysteine [C], two aliphatic amino acids [aa], and any amino acid [X]. In vitro studies reported here confirm previous reports that CaaX proteins with a C-terminal serine are farnesylated by FTase and those with a C-terminal leucine are geranylgeranylated by GGTase-I. In addition, we found that FTase can farnesylate CaaX proteins with a C-terminal leucine and can transfer a geranylgeranyl group to some CaaX proteins. Genetic data indicate that FTase and GGTase-I have the same substrate preferences in vivo as in vitro and also show that each enzyme can prenylate some of the preferred substrates of the other enzyme in vivo. Specifically, the viability of yeast cells lacking FTase is due to prenylation of Ras proteins by GGTase-I. Although this GGTase-I dependent prenylation of Ras is sufficient for growth, it is not sufficient for mutationally activated Ras proteins to exert deleterious effects on growth. The dependence of the activated Ras phenotype on FTase can be bypassed by replacing the C-terminal serine with leucine. This altered form of Ras appears to be prenylated by both GGTase-I and FTase, since it produces an activated phenotype in a strain lacking either FTase or GGTase-I. Yeast cells can grow in the absence of GGTase-I as long as two essential substrates are overexpressed, but their growth is slow. Such strains are dependent on FTase for viability and are able to grow faster when FTase is overproduced, suggesting that FTase can prenylate the essential substrates of GGTase-I when they are overproduced.     

Kinetic studies of protein farnesyltransferase mutants establish active substrate conformation

The zinc metalloenzyme protein farnesyltransferase (FTase) catalyzes the transfer of a 15-carbon farnesyl moiety from farnesyl diphosphate (FPP) to a cysteine residue near the C-terminus of a protein substrate. Several crystal structures of inactive FTase.FPP.peptide complexes indicate that K164alpha interacts with the alpha-phosphate and that H248beta and Y300beta form hydrogen bonds with the beta-phosphate of FPP [Strickland, C. L., et al. (1998) Biochemistry 37, 16601-16611]. Mutations K164Aalpha, H248Abeta, and Y300Fbeta were prepared and analyzed by single turnover kinetics and ligand binding studies. These mutations do not significantly affect the enzyme affinity for FPP but do decrease the farnesylation rate constant by 30-, 10-, and 500-fold, respectively. These mutations have little effect on the pH and magnesium dependence of the farnesylation rate constant, demonstrating that the side chains of K164alpha, Y300beta, and H248beta do not function either as general acid-base catalysts or as magnesium ligands. Mutation of H248beta and Y300beta, but not K164alpha, decreases the farnesylation rate constant using farnesyl monophosphate (FMP). These data suggest that, contrary to the conclusions derived from analysis of the static crystal structures, the transition state for farnesylation is stabilized by interactions between the alpha-phosphate of the isoprenoid substrate and the side chains of Y300beta and H248beta. These results suggest an active substrate conformation for FTase wherein the C1 carbon of the FPP substrate moves toward the zinc-bound thiolate of the protein substrate to react, resulting in a rearrangement of the diphosphate group relative to its ground state position in the binding pocket.     

Sequence dependence of protein isoprenylation

Several proteins have been shown to be post-translationally modified on a specific C-terminal cysteine residue by either of two isoprenoid biosynthetic pathway metabolites, farnesyl diphosphate or geranylgeranyl diphosphate. Three enzymes responsible for protein isoprenylation were resolved chromatographically from the cytosolic fraction of bovine brain: a farnesyl-protein transferase (FTase), which modified the cell-transforming Ras protein, and two geranyl-geranyl-protein transferases, one (GGTase-I) which modified a chimeric Ras having the C-terminal amino acid sequence of the gamma-6 subunit of heterotrimeric GTP-binding proteins, and the other (GGTase-II) which modified the Saccharomyces cerevisiae secretory GTPase protein YPT1. In a S. cerevisiae strain lacking FTase activity (ram1), both GGTases were detected at wild-type levels. In a ram2 S. cerevisiae strain devoid of FTase activity, GGTase-I activity was reduced by 67%, suggesting that GGTase-I and FTase activities derive from different enzymes but may share a common genetic feature. For the FTase and the GGTase-I activities, the C-terminal amino acid sequence of the protein substrate, the CAAX box, appeared to contain all the critical determinants for interaction with the transferase. In fact, tetrapeptides with amino acid sequences identical to the C-terminal sequences of the protein substrates for FTase or GGTase-I competed for protein isoprenylation by acting as alternative substrates. Changes in the CAAX amino acid sequence of protein substrates markedly altered their ability to serve as substrates for both FTase and GGTase-I. In addition, it appeared that FTase and GGTase-I had complementary affinities for CAAX protein substrates; that is, CAAX proteins that were good substrates for FTase were, in general, poor substrates for GGTase-I, and vice versa. In particular, a leucine residue at the C terminus influenced whether a CAAX protein was either farnesylated or geranylgeranylated preferentially. The YPT1 C terminus peptide, TGGGCC, did not compete or serve as a substrate for GGTase-II, indicating that the interaction between GGTase-II and YPT1 appeared to depend on more than the 6 C-terminal residues of the protein substrate sequence. These results identify three different isoprenyl-protein transferases that are each selective for their isoprenoid and protein substrates.     

Molecular dynamics analysis of a series of 22 potential farnesyltransferase substrates containing a CaaX-motif

Protein farnesyltransferase (FTase) is an important target in many research fields, more markedly so in cancer investigation since several proteins known to be involved in human cancer development are thought to serve as substrates for FTase and to require farnesylation for proper biological activity. Several FTase inhibitors (FTIs) have advanced into clinical testing. Nevertheless, despite the progress in the field several functional and mechanistic doubts on the FTase catalytic activity have persisted. This work provides some crucial information on this important enzyme by describing the application of molecular dynamics simulations using specifically designed molecular mechanical parameters for a variety of 22 CaaX peptides known to work as natural substrates or inhibitors for this enzyme. The study involves a comparative analysis of several important molecular aspects, at the mechanistic level, of the behavior of substrates and inhibitors at the dynamic level, including the behavior of the enzyme and peptides, as well as their interaction, together with the effect of the solvent. Properties evaluated include the radial distribution function of the water molecules around the catalytically important zinc metal atom and cysteine sulfur of CaaX, the conformations of the substrate and inhibitor and the corresponding RMSF values, critical hydrogen bonds, and several catalytically relevant distances. These results are discussed in light of recent experimental and computational evidence that provides new insights into the activity of this enzyme.

Chemical cytometry for monitoring metabolism of a Ras-mimicking substrate in single cells.

BACKGROUND: Chemical cytometry is an emerging technology that analyzes chemical contents of single cells by means of capillary electrophoresis or capillary chromatography. It has a potential to become an indispensable tool in analyses of heterogeneous cell populations such as those in tumors. Ras oncogenes are found in 30% of human cancers. To become fully functional products, oncogenic Ras proteins require at least three posttranslational modifications: farnesylation, endoproteolysis, and carboxyl-methylation. Therefore, enzymes that catalyze the three reactions, farnesyltransferase (FTase), endoprotease (EPase), and methyltransferase (MTase), are considered highly attractive therapeutic targets. In this work, we used chemical cytometry to study the metabolism of a pentapeptide substrate that can mimic Ras proteins with respect to their posttranslational modifications in solution. METHODS: Mouse mammary gland tumor cells (4T1) and mouse embryo fibroblasts (NIH3T3) were incubated with a fluorescently labeled pentapeptide substrate, 2',7'-difluorofluorescein-5-carboxyl-Gly-Cys-Val-Ilu-Ala. Cells were washed from the substrate and resuspended in phosphate buffered saline. Uptake of the substrate by the cells was monitored by laser scanning confocal microscopy. Single cells were injected into the capillary, lysed, and subjected to capillary electrophoresis. Fluorescent metabolic products were detected by laser-induced fluorescence and compared with products obtained by the conversion of the substrate by FTase, EPase, and MTase in solution. Co-sampling of single cells with the in-vitro products was used for such comparison. RESULTS: Confocal microscopy data showed that the substrate permeated the plasma membrane and clustered in the cytoplasm. Further capillary electrophoresis and chemical cytometry analyses showed that the substrate was converted into three fluorescently labeled products, two of which were secreted in the culture medium and one remained in the cells. The intracellular product was present at approximately 100,000 molecules per cell. The three metabolic products of the substrate were found to be different from the products of its processing by FTase, EPase, and MTase in solution. CONCLUSIONS: This is the first report of chemical cytometry in the context of Ras-signaling studies. The chemical cytometry method used in this work will find applications in the development of suitable peptide substrates for monitoring enzyme activities in single cells.     

Protein farnesylation is critical for maintaining normal cell morphology and canavanine resistance in Schizosaccharomyces pombe

Protein farnesyltransferase (FTase) plays important roles in the growth and differentiation of eukaryotic cells. In this paper, we report the identification of the Schizosaccharomyces pombe gene cpp1(+) encoding the beta-subunit of FTase. The predicted amino acid sequence of the cpp1(+) gene product shares significant similarity with FTase beta-subunits from a variety of organisms. S. pombe FTase purified from E. coli exhibits high enzymatic activity toward the CAAX farnesylation motif substrates (where C represents cysteine, A represents aliphatic amino acid, and X is preferentially methionine, cysteine, serine, alanine, or glutamine) while showing little preference for CAAL geranylgeranylation motif substrates (where L represents leucine or phenylalanine). cpp1(+) is not essential for growth as shown by gene disruption; however, mutant cells exhibit rounded or irregular cell morphology. Expression of a geranylgeranylated mutant form, Ras1-CVIL, which can bypass farnesylation, rescues these morphological defects. We also identify a novel phenotype of cpp1(-) mutants, hypersensitivity to canavanine. This appears to be due to a 3-4-fold increase in the rate of arginine uptake as compared with wild-type cells. Expression of the geranylgeranylated mutant form of a novel farnesylated small GTPase, SpRheb, is able to suppress the elevated arginine uptake rate. These results demonstrate that protein farnesylation is critical for maintaining normal cell morphology through Ras1 and canavanine resistance through SpRheb.     

运用 mRNA 体外展示技术筛选胸苷酸合成酶 RNA 亲和肽

以体外选择方法筛选不同功能的核酸、肽和蛋白质是近年的研究热点, mRNA 体外展示是一种新兴的高效多肽选择技术,其基本原理是通过含嘌呤霉素寡核苷酸的 Linker 使 mRNA 与它编码的肽或蛋白质共价结合,形成 mRNA- 蛋白质融合体,这一方法已用于多种功能肽的鉴定 . 以 mRNA 体外展示技术进行了由大容量多肽库中 (>1013) 筛选胸苷酸合成酶 (thymidylate synthase , TS) RNA 亲和肽的研究,通过精密的实验设计,建立了一套完整有效的筛选方法,并对实验条件进行了优化 . 已进行了 8 轮筛选,结果表明,以 mRNA 体外展示技术获得的多肽分子,可以与 TS mRNA 亲和 . 将测序结果与初始肽库进行比较,发现亲和肽中碱性氨基酸及芳香族氨基酸含量明显增加,说明其在与 RNA 结合中具有重要作用 . mRNA 展示技术作为一种大容量文库的体外筛选方法,将广泛应用于与固定化靶物质具高度亲和性及特异性的多肽和蛋白质的筛选 .     

Investigation of S-farnesyl transferase substrate specificity with combinatorial tetrapeptide libraries

Using biased tetrapeptide libraries made up of proteinogenic amino acids of the general formula Cys-O2-X3-X4, we searched for new substrates of partly purified rat brain S-farnesyl transferase (FTase). To achieve this task, an assay was developed in which the consumption of the co-substrate (farnesyl pyrophosphate) was measured. After three steps of deconvolution including each synthesis and enzymatic assay, the most efficient substrates found under these particular conditions were Cys-Lys-Gln-Gln (peptide I) and Cys-Lys-Gln-Met (peptide II). As a control, we used another tetrapeptide library (Cys-Val-O3-X4) in which the valine position was arbitrarily fixed, corresponding to Cys-Val-Ile-Met in the CAAX box of K-RasB, although this sublibrary was only marginally active compared with Cys-Lys-X3-X4 in the first round of deconvolution. The best substrate sublibrary was Cys-Val-Thr-X4, threonine being more favourable than the aliphatic amino acids (Val, Ile, Leu, Ala) in this position. Deconvolution finally led to Cys-Val-Thr-Gln, -Met, -Thr and -Ser as the most efficient substrates of FTase. Those tetrapeptides were not substrates of a partly purified geranylgeranyl transferase 1 (GGTase1). We also investigated the influence of the -1 position (at the N-terminus of cysteine) on the specificity of the enzyme, by using a series of pentapeptides constructed on the basis of the best tetrapeptide core (peptide 1). Among this family of analogues, only His-Cys-Lys-Gln-Gln did not behave as a substrate, whereas all the other pentapeptides were measurable substrates, with Gly-, Asn- and Thr-Cys-Lys-Gln-Gln displaying kinetic constants similar to that of Cys-Lys-Gln-Gln. The present work provides strong evidence that the best tetrapeptide substrates of FTase do not necessarily belong to the classical CAAX box, in which A's are lipophilic residues, but rather contain hydrophilic amino acids in the middle of their sequences. Among them, peptides I and II are potent FTase in vitro substrates that are not recognised by GGTase1 and might be new starting points for the design of FTase inhibitors.     

A mutant form of human protein farnesyltransferase exhibits increased resistance to farnesyltransferase inhibitors.

Protein farnesyltransferase (FTase) is a key enzyme responsible for the lipid modification of a large and important number of proteins including Ras. Recent demonstrations that inhibitors of this enzyme block the growth of a variety of human tumors point to the importance of this enzyme in human tumor formation. In this paper, we report that a mutant form of human FTase, Y361L, exhibits increased resistance to farnesyltransferase inhibitors, particularly a tricyclic compound, SCH56582, which is a competitive inhibitor of FTase with respect to the CAAX (where C is cysteine, A is an aliphatic amino acid, and X is the C-terminal residue that is preferentially serine, cysteine, methionine, glutamine or alanine) substrates. The Y361L mutant maintains FTase activity toward substrates ending with CIIS. However, the mutant also exhibits an increased affinity for peptides terminating with CIIL, a motif that is recognized by geranylgeranyltransferase I (GGTase I). The Y361L mutant also demonstrates activity with Ha-Ras and Cdc42Hs proteins, substrates of FTase and GGTase I, respectively. In addition, the Y361L mutant shows a marked sensitivity to a zinc chelator HPH-5 suggesting that the mutant has altered zinc coordination. These results demonstrate that a single amino acid change at a residue at the active site can lead to the generation of a mutant resistant to FTase inhibitors. Such a mutant may be valuable for the study of the effects of FTase inhibitors on tumor cells.