Modulation of the zinc(II) center in protein farnesyltransferase by mutagenesis of the zinc(II) ligands

Protein farnesyltransferase (PFTase) is a zinc-containing metalloenzyme that catalyzes the alkylation of cysteine (C) in protein substrates containing a C-terminal "CaaX" motif by farnesyl diphosphate (FPP). In yeast PFTase Zn(II) is coordinated to D307, C309, and H363 in the beta-subunit. The inner coordination sphere of the metal also contains a water molecule to give a net charge of 0 for the tetracoordinate Zn(II) center. When the protein substrate binds, the water molecule is replaced by the thiol of the cysteine residue, and the thiol is deprotonated to generate a Zn(II)-stabilized thiolate in the PFTase.FPP.protein ternary complex for the ensuing prenyl transfer reaction. An expression system was constructed for yeast PFTase containing a His(6) tag at the C-terminus of the beta-subunit to facilitate purification of the wild-type enzyme and site-directed mutants. The amino acids that coordinate Zn(II) were substituted to give a series of mutant PFTases with net charges of +1, 0, -1, and -2 at the Zn(II) center of the ternary enzyme.substrate complexes. Wild-type PFTase and the site-directed mutants were purified as alpha,beta-heterodimers, and each was found to contain an equivalent of Zn(II). All of the mutants were less reactive than wt PFTase (net charge of -1), with the greatest losses of activity seen for the mutants with net charges of 0 and +1. Equilibrium binding experiments with dGCVIA peptide and an unreactive analogue of FPP, (E,E)-2-[2-oxo-2-[[(3,7,11-trimethyl-2,6,10-dodecatrienyl)oxy]amino]ethyl]phosphonate (FNP), established that all of the mutants bound an equivalent of the peptide substrate. Like wt PFTase, the pH dependence of K(D) for the mutants did not change significantly between pH 5 and pH 9, indicating that pK(A)s for the thiol moiety in the (mutant PFTase).FNP.peptide complexes were <5. dGSVIA and dG(beta-NH2-Ala)VIA, where the sulfhydryl moiety was replaced by hydroxyl and amino groups, respectively, were not substrates. These experiments suggest a direct relationship between the net charge of the Zn(II) center in PFTase and the reactivity of the peptide thiolate that is alkylated by FPP.     

Role of metals in the reaction catalyzed by protein farnesyltransferase

Protein farnesyltransferase catalyzes the posttranslational farnesylation of several proteins involved in signal transduction, including Ras, and is a target enzyme for antitumor therapies. Efficient product formation catalyzed by protein farnesyltransferase requires an enzyme-bound zinc cation and high concentrations of magnesium ions. In this work, we have measured the pH dependence of the chemical step of product formation, determined under single-turnover conditions, and have demonstrated that the prenylation rate constant is enhanced by two deprotonations. Substitution of the active site zinc by cadmium demonstrated that one of the ionizations reflects deprotonation of the metal-coordinated thiol of the peptide "CaaX" motif, pK(a1) = 6.0. These data provide additional evidence for the direct involvement of a metal-coordinated sulfur nucleophile in catalysis. The second ionization was assigned to a hydroxyl on the pyrophosphate moiety of farnesyl pyrophosphate, pK(a2) = 7.4. Deprotonation of this group is important for binding of magnesium. This second ionization is not observed for catalysis in the absence of magnesium or when the substrate is farnesyl monophosphate. These data indicate that the maximal rate constant for prenylation requires formation of a zinc-coordinated thiolate nucleophile and enhancement of the electrophilic character at C1 of the farnesyl chain by magnesium ion coordination of the pyrophosphate leaving group.     

Biochemical and structural studies with prenyl diphosphate analogues provide insights into isoprenoid recognition by protein farnesyl transferase

Protein farnesyl transferase (PFTase) catalyzes the reaction between farnesyl diphosphate and a protein substrate to form a thioether-linked prenylated protein. The fact that many prenylated proteins are involved in signaling processes has generated considerable interest in protein prenyl transferases as possible anticancer targets. While considerable progress has been made in understanding how prenyl transferases distinguish between related target proteins, the rules for isoprenoid discrimination by these enzymes are less well understood. To clarify how PFTase discriminates between FPP and larger prenyl diphosphates, we have examined the interactions between the enzyme and several isoprenoid analogues, GGPP, and the farnesylated peptide product using a combination of biochemical and structural methods. Two photoactive isoprenoid analogues were shown to inhibit yeast PFTase with K(I) values as low as 45 nM. Crystallographic analysis of one of these analogues bound to PFTase reveals that the diphosphate moiety and the two isoprene units bind in the same positions occupied by the corresponding atoms in FPP when bound to PFTase. However, the benzophenone group protrudes into the acceptor protein binding site and prevents the binding of the second (protein) substrate. Crystallographic analysis of geranylgeranyl diphosphate bound to PFTase shows that the terminal two isoprene units and diphosphate group of the molecule map to the corresponding atoms in FPP; however, the first and second isoprene units bulge away from the acceptor protein binding site. Comparison of the GGPP binding mode with the binding of the farnesylated peptide product suggests that the bulkier isoprenoid cannot rearrange to convert to product without unfavorable steric interactions with the acceptor protein. Taken together, these data do not support the "molecular ruler hypotheses". Instead, we propose a "second site exclusion model" in which PFTase binds larger isoprenoids in a fashion that prevents the subsequent productive binding of the acceptor protein or its conversion to product.     

Reactivity and pH dependence of thiol conjugation to N-ethylmaleimide: detection of a conformational change in chalcone isomerase

The reactivity of simple alkyl thiolates with N-ethylmaleimide (NEM) follows the Br?nsted equation, log kS- = log G + beta pK, with G = 790 M-1 min-1 and beta = 0.43. The rate constant for the reaction of the thiolate of 2-mercaptoethanol with NEM is 10(7) M-1 min-1, whereas the rate constant for the reaction of the protonated thiol is less than 0.0002 M-1 min-1. The intrinsic reactivity of the protonated thiol (SH) is over (5 X 10(10]-fold less than the thiolate (S-) and makes a negligible contribution to the reactivity of thiols toward NEM. The rate of NEM modification of chalcone isomerase was conveniently measured by following the concomitant loss in enzymatic activity. The pseudo-first-order rate constants for inactivation show a linear dependence on the concentration of NEM up to 200 mM and yield no evidence for noncovalent binding of NEM to the enzyme. Evidence is presented demonstrating that the modification of chalcone isomerase by NEM is limited to a single cysteine residue over a wide range of pH. Kinetic protection against inactivation and modification by NEM is provided by competitive inhibitors and supports the assignment of this cysteine residue to be at or near the active site of chalcone isomerase. The pH dependence of inactivation of the enzyme by NEM indicates a pK of 9.2 for the cysteine residue in chalcone isomerase. At high pH, the enzymatic thiolate is only (3 X 10(-5))-fold as reactive as a low molecular weight alkyl thiolate of the same pK, suggesting a large steric inhibition of reaction on the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

The basis for K-Ras4B binding specificity to protein farnesyltransferase revealed by 2 A resolution ternary complex structures

Background: The protein farnesyltransferase (FTase) catalyzes addition of the hydrophobic farnesyl isoprenoid to a cysteine residue fourth from the C terminus of several protein acceptors that are essential for cellular signal transduction such as Ras and Rho. This addition is necessary for the biological function of the modified proteins. The majority of Ras-related human cancers are associated with oncogenic variants of K-RasB, which is the highest affinity natural substrate of FTase. Inhibition of FTase causes regression of Ras-mediated tumors in animal models. Results: We present four ternary complexes of rat FTase co-crystallized with farnesyl diphosphate analogs and K-Ras4B peptide substrates. The Ca(1)a(2)X portion of the peptide substrate binds in an extended conformation in the hydrophobic cavity of FTase and coordinates the active site zinc ion. These complexes offer the first view of the polybasic region of the K-Ras4B peptide substrate, which confers the major enhancement of affinity of this substrate. The polybasic region forms a type I beta turn and binds along the rim of the hydrophobic cavity. Removal of the catalytically essential zinc ion results in a dramatically different peptide conformation in which the Ca(1)a(2)X motif adopts a beta turn. A manganese ion binds to the diphosphate mimic of the farnesyl diphosphate analog. Conclusions: These ternary complexes provide new insight into the molecular basis of peptide substrate specificity, and further define the roles of zinc and magnesium in the prenyltransferase reaction. Zinc is essential for productive Ca(1)a(2)X peptide binding, suggesting that the beta-turn conformation identified in previous nuclear magnetic resonance (NMR) studies reflects a state in which the cysteine is not coordinated to the zinc ion. The structural information presented here should facilitate structure-based design and optimization of inhibitors of Ca(1)a(2)X protein prenyltransferases.     

Systematic modulation of Michael-type reactivity of thiols through the use of charged amino acids.

A quantitative structure-reactivity relationship for the Michael-type addition of thiols onto acrylates was determined. Several thiol-containing peptides were investigated by examining the correlation between the second-order rate constant of their addition onto PEG-diacrylate and the pK(a) of the thiols within a peptide. By introducing charged amino acids in close proximity to a cysteine, the pK(a) of the thiol was systematically modulated by electrostatic interactions. Positive charges from the amino acid arginine decreased the pK(a) of the thiol and accelerated the reaction with acrylates while negative charges from aspartic acids showed the opposite effect. A linear correlation between thiolate concentrations and kinetic constants was found, confirming the role of thiolates as the reactive species in this Michael-type reaction. The relevant factors influencing the reactivity were the sign and the number of the neighboring charges, while the position of these charges had little effect on reactivity. These results provide a basis for the rational design of peptides, where the kinetics and thus selectivity of protein/peptide conjugation with polymeric structures via Michael-type addition reactions can be controlled.     

Reactivity of the two essential cysteine residues of the periplasmic mercuric ion-binding protein, MerP

Reactivities of the two essential cysteine residues in the heavy metal binding motif, MTC(14)AAC(17), of the periplasmic Hg(2+)-binding protein, MerP, have been examined. While Cys-14 and Cys-17 have previously been shown to be Hg(2+)-binding residues, MerP is readily isolated in an inactive Cys-14-Cys-17 disulfide form. In vivo results demonstrated that these cysteine residues are reduced in the periplasm of Hg(2+)-resistant Escherichia coli. Denaturation and redox equilibrium studies revealed that reduced MerP is thermodynamically favored over the oxidized form. The relative stability of reduced MerP appears to be related to the lowered thiol pK(a) (5.5) of the Cys-17 side chain. Despite its much lower pK(a), the Cys-17 thiol is far less accessible than Cys-14, reacting 45 times more slowly with iodoacetamide at pH 7.5. This is reminiscent of proteins such as thioredoxin and DsbA, which contain a similar C-X-X-C motif, except in those cases the more exposed thiol has the lowered pK(a). In terms of MerP function, electrostatic attraction between Hg(2+) and the buried Cys-17 thiolate may be important for triggering the structural change that MerP has been reported to undergo upon Hg(2+) binding. Control of cysteine residue reactivity in heavy metal binding motifs may generally be important in influencing specific metal-binding properties of proteins containing them.     

Structure, dynamics and electrostatics of the active site of glutaredoxin 3 from Escherichia coli: comparison with functionally related proteins.

The chemistry of active-site cysteine residues is central to the activity of thiol-disulfide oxidoreductases of the thioredoxin superfamily. In these reactions, a nucleophilic thiolate is required, but the associated pK(a) values differ vastly in the superfamily, from less than 4 in DsbA to greater than 7 in Trx. The factors that stabilize this thiolate are, however, not clearly established. The glutaredoxins (Grxs), which are members of this superfamily, contain a Cys-Pro-Tyr-Cys motif in their active site. In reduced Grxs, the pK(a) of the N-terminal active-site nucleophilic cysteine residue is lowered significantly, and the stabilization of the corresponding thiolate is expected to influence the redox potential of these enzymes. Here, we use a combination of long molecular dynamics (MD) simulations, pK(a) calculations, and experimental investigations to derive the structure and dynamics of the reduced active site from Escherichia coli Grx3, and investigate the factors that stabilize the thiolate. Several different MD simulations converged toward a consensus conformation for the active-site cysteine residues (Cys11 and Cys14), after a number of local conformational changes. Key features of the model were tested experimentally by measurement of NMR scalar coupling constants, and determination of pK(a) values of selected residues. The pK(a) values of the Grx3 active-site residues were calculated during the MD simulations, and support the underlying structural model. The structure of Grx3, in combination with the pK(a) calculations, indicate that the pK(a) of the N-terminal active-site cysteine residue in Grx3 is intermediate between that of its counterpart in DsbA and Trx. The pK(a) values in best agreement with experiment are obtained with a low (<4) protein dielectric constant. The calculated pK(a) values fluctuate significantly in response to protein dynamics, which underscores the importance of the details of the underlying structures when calculating pK(a) values. The thiolate of Cys11 is stabilized primarily by direct hydrogen bonding with the amide protons of Tyr13 and Cys14 and the thiol proton of Cys14, rather than by long-range interactions from charged groups or from a helix macrodipole. From the comparison of reduced Grx3 with other members of the thioredoxin superfamily, a unifying theme for the structural basis of thiol pK(a) differences in this superfamily begins to emerge.     

Reactivity of small thiolate anions and cysteine-25 in papain toward methyl methanethiosulfonate

The dependence on thiol pK of the second-order rate constant (kS) for reaction of thiolate anions with MMTS was shown to follow the Br?nsted equation log kS = log G + beta pK with log G = 1.44 and 3.54 and beta = 0.635 and 0.309 for aryl and alkyl thiols, respectively. The reactivity toward MMTS of the protonated thiol group was found to be negligible in comparison to that of the thiolate anion. For 2-mercaptoethanol the reactivity toward MMTS of the protonated form of the thiol group was shown to be at least 5 X 10(9) smaller than that of the thiolate anion. The pH dependence of the second-order rate constant for reaction of the thiolate group of Cys-25 at the active site of papain was determined and shown to be consistent with the previously determined low pK for Cys-25 and its electrostatic interaction with His-159. The small dependence of the reactivity of Cys-25 on thiol pK (beta approximately 0.09) suggested that the charge-charge interactions that act through space to perturb the pK of the nucleophile at the active site of papain and perhaps other enzymes may serve to increase the fraction of nucleophile present in the reactive basic form without introducing the decrease in nucleophilic reactivity seen in model systems where pK's are lowered primarily by charge-dipole interactions.     

Proton equilibria in the binding of Zn2+ and of methylmercuric iodide to papain.

The proton liberation on the binding of zinc chloride and methylmercuric iodide to the (essential) thiol group of papain has been examined as a function of pH. This was carried out by (a) direct titration of the protons on the addition of the metal compound to active papain and (b) measurement of the extent of inhibition of enzyme activity by the metal compound as a function of pH. It was found that in the neutral pH range the thiol group or the neighbouring imidazole group in the free enzyme carries one proton, at low pH both groups do so, whereas at high pH neither group carries a proton. The pK values of the free enzyme that govern the proton release, 4.2 and 8.5, correspond to those that govern overall activity. Both from the experiments with methylmercuric iodide and from fluorescence measurements of methylmercuric papain, it was established that the imidazole group in the latter compound exhibits a pK of 5.4. Taking recent data into account, it was considered that the ion pair of thiolate anion and imidazolium cation, proposed by Polgar, is the best approximation to describe the charge distribution in the active centre and to explain the reaction mechanism.     

Modulation of the reactivity of the thiol of human serum albumin and its sulfenic derivative by fatty acids

The single cysteine residue of human serum albumin (HSA-SH) is the most abundant plasma thiol. HSA transports fatty acids (FA), a cargo that increases under conditions of diabetes, exercise or adrenergic stimulation. The stearic acid-HSA (5/1) complex reacted sixfold faster than FA-free HSA at pH 7.4 with the disulfide 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) and twofold faster with hydrogen peroxide and peroxynitrite. The apparent pK(a) of HSA-SH decreased from 7.9±0.1 to 7.4±0.1. Exposure to H(2)O(2) (2mM, 5min, 37°C) yielded 0.29±0.04mol of sulfenic acid (HSA-SOH) per mole of FA-bound HSA. The reactivity of HSA-SOH with low molecular weight thiols increased ～threefold in the presence of FA. The enhanced reactivity of the albumin thiol at neutral pH upon FA binding can be rationalized by considering that the corresponding conformational changes that increase thiol exposure both increase the availability of the thiolate due to a lower apparent pK(a) and also loosen steric constraints for reactions. Since situations that increase circulating FA are associated with oxidative stress, this increased reactivity of HSA-SH could assist in oxidant removal.     

Position-dependent interactions between cysteine residues and the helix dipole

A protein model was developed for studying the interaction between cysteine residues and the helix dipole. Site-directed mutagenesis was used to introduce cysteine residues at the N-terminus of helix H in recombinant sperm whale myoglobin. Based on the difference in thiol pK(a) between folded proteins and an unfolded peptide, the energy of interaction between the thiolate and the helix dipole was determined. Thiolates at the N1 and N2 positions of the helix were stabilized by 0.3 kcal/mole and 0.7 kcal/mole, respectively. A thiolate at the Ncap position was stabilized by 2.8 kcal/mole, and may involve a hydrogen bond. In context with other studies, an experimentally observed helix dipole effect may be defined in terms of two distinct components. A charge-dipole component involves electrostatic interactions with peptide bond dipoles in the first two turns of the helix and affects residues at all positions of the terminus; a hydrogen bond component involves one or more backbone amide groups and is only possible at the capping position due to conformational restraints elsewhere. The nature and magnitude of the helix dipole effect is, therefore, position-dependent. Results from this model system were used to interpret cysteine reactivity in rodent hemoglobins and the thioredoxin family.     

Spectroscopic and kinetic evidence for the thiolate anion of glutathione at the active site of glutathione S-transferase

Ultraviolet difference spectroscopy of the binary complex of isozyme 4-4 of rat liver glutathione S-transferase with glutathione (GSH) and the enzyme alone or as the binary complex with the oxygen analogue, gamma-L-glutamyl-L-serylglycine (GOH), at neutral pH reveals an absorption band at 239 nm (epsilon = 5200 M-1 cm-1) that is assigned to the thiolate anion (GS-) of the bound tripeptide. Titration of this difference absorption band over the pH range 5-8 indicates that the thiol of enzyme-bound GSH has a pKa = 6.6, which is about 2.4 pK units less than that in aqueous solution and consistent with the kinetically determined pKa previously reported [Chen et al. (1988) Biochemistry 27, 647]. The observed shift in the pKa between enzyme-bound and free GSH suggests that about 3.3 kcal/mol of the intrinsic binding energy of the peptide is utilized to lower the pKa into the physiological pH range. Apparent dissociation constants for both GSH and GOH are comparable and vary by a factor of less than 2 over the same pH range. Site occupancy data and spectral band intensity reveal large extinction coefficients at 239 nm (epsilon = 5200 M-1 cm-1) and 250 nm (epsilon = 1100 M-1 cm-1) that are consistent with the existence of either a glutathione thiolate (E.GS-) or ion-paired thiolate (EH+.GS-) in the active site. The observation that GS- is likely the predominant tripeptide species bound at the active site suggested that the carboxylate analogue of GSH, gamma-L-glutamyl-(D,L-2-aminomalonyl)glycine, should bind more tightly than GSH.(ABSTRACT TRUNCATED AT 250 WORDS)     

Keap1, the sensor for electrophiles and oxidants that regulates the phase 2 response, is a zinc metalloprotein

Induction of the phase 2 response, a major cellular reaction to oxidative/electrophile stress depends on a protein triad: actin-tethered Keap1 that binds to Nrf2. Inducers react with Keap1 releasing Nrf2 for nuclear translocation and activation of the antioxidant response element (ARE), which regulates phase 2 genes. The primary sensors for inducers are certain uniquely reactive cysteine thiols of Keap1. Recombinant murine Keap1 contains 0.9 zinc atoms per monomer as determined by inductively coupled plasma-optical emission spectrometry: its zinc content depends on the metal composition of the overexpression medium. Simultaneous direct measurement of bound zinc using a pyridazoresorcinol chelator and protein thiol groups using 4,4'-dipyridyl disulfide has established that (i) zinc is bound to reactive cysteine thiols of Keap1 and is displaced stoichiometrically by inducers, (ii) with these cysteines mutated to alanine, the affinity for zinc is reduced by nearly 2 orders of magnitude, and (iii) the association constant of Keap1 for zinc is 1.02 (+/-0.19) x 10(11) M(-)(1), consistent with a Zn(2+) metalloprotein. Co(2+) substitution for Zn(2+) yields an optical spectrum consistent with tetrahedral metal coordination. Coincident binding of inducers and release of zinc alters the conformation of Keap1, as shown by a profound decline of its tryptophan fluorescence and depression of fluorescence of a hydrophobicity probe. Thus, regulation of the phase 2 response involves chemical modification of critical cysteine residues of Keap1, whose reactivity is modulated by zinc binding. Keap1 is a zinc-thiol protein endowed with a delicate switch controlled by both metal-binding and thiol reactivity.     

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.     

Selective modification of CaaX peptides with ortho-substituted anilinogeranyl lipids by protein farnesyl transferase: competitive substrates and potent inhibitors from a library of farnesyl diphosphate analogues

Protein farnesyl transferase (FTase) catalyzes transfer of a 15-carbon farnesyl group from farnesyl diphosphate (FPP) to a conserved cysteine in the C-terminal Ca1a2X motif of a range of proteins ("C" refers to the cysteine, "a" to any aliphatic amino acid, and "X" to any amino acid), and the lipid chain interacts with, and forms part of, the Ca1a2X peptide binding site. Here, we employed a library of anilinogeranyl diphosphate (AGPP) derivatives to examine whether altering the interacting surface between the two substrates could be exploited to generate Ca1a2X peptide selective FPP analogues. Analysis of transfer kinetics to dansyl-GCVLS peptide revealed that AGPP analogues with substituents smaller than or equal in size to a thiomethyl group supported FTase function, while analogues with larger substituents did not. Analogues with small meta-substitutions on the aniline ring such as iodo and cyano increased reactivity with dansyl-GCVLS and provided analogues that were effective FPP competitors. Other analogues with ortho-substitutions on the aniline were potent dansyl-GCVLS modification FTase inhibitors (Ki in the 2.4-18 nM range). Both meta- and para-trifluoromethoxy-AGPP are transferred to dansyl-GCVLS while the ortho-substituted isomer was a potent farnesyl transferase inhibitor (FTI) with an inhibition constant Ki = 3.0 nM. In contrast, ortho-trifluoromethoxy-AGPP was efficiently transferred to dansyl-GCVIM. Competition for dansyl-GCVLS and dansyl-GCVIM peptides by FPP and ortho-trifluoromethoxy-AGPP gave both analogue and farnesyl modified dansyl-GCVIM but only farnesylated dansyl-GCVLS. We provide evidence that competitive modification of dansyl-GCVIM by ortho-trifluoromethoxy-AGPP stems from a prechemical step discrimination between the competing peptides by the FTase-analogue complex. These results show that subtle changes engineered into the isoprenoid structure can alter the reactivity and FPP competitiveness of the analogues, which may be important for the development of prenylated protein function inhibitors.     

A probe of the active site acidity of carboxypeptidase A

The substrate analogue 2-(1-carboxy-2-phenylethyl)-4-phenylazophenol is a potent competitive inhibitor of carboxypeptidase A. Upon ligation to the active site, the azophenol moiety undergoes a shift of pKa from a value of 8.76 to a value of 4.9; this provides an index of the Lewis acidity of the active site zinc ion. Examination of the pH dependence of Ki for the inhibitor shows maximum effectiveness in neutral solution (limiting Ki = 7.6 X 10(-7) M), with an increase in Ki in acid (pK1 = 6.16) and in alkaline solution (pK2 = 9.71, pK3 = 8.76). It is concluded that a proton-accepting enzymic functional group with the lower pKa (6.2) controls inhibitor binding, that ionization of this group is also manifested in the hydrolysis of peptide substrates (kcat/Km), and that the identity of this group is the water molecule that binds to the active site metal ion in the uncomplexed enzyme (H2OZn2+L3). Reverse protonation state inhibition is demonstrated, and conventional concepts regarding the mechanism of peptide hydrolysis by the enzyme are brought into question.     

Evaluation of geranylazide and farnesylazide diphosphate for incorporation of prenylazides into a CAAX box-containing peptide using protein farnesyltransferase.

Protein farnesyltransferase (PFTase) catalyzes the attachment of a geranylazide (C10) or farnesylazide (C15) moiety from the corresponding prenyldiphosphates to a model peptide substrate, N-dansyl-Gly-Cys-Val-Ile-Ala-OH. The rates of incorporation for these two substrate analogs are comparable and approximately twofold lower than that using the natural substrate farnesyl diphosphate (FPP). Reaction of N-dansyl-Gly-Cys(S-farnesylazide)-Val-Ile-Ala-OH with 2-diphenylphosphanylbenzoic acid methyl ester then gives a stable alkoxy-imidate linked product. This result suggests future generations whereby azide groups introduced using this enzymatic approach are functionalized using a broad range of azide-reactive reagents. Thus, chemistry has been developed that could be used to achieve highly specific peptide and protein modification. The farnesylazide analog may be useful in certain biological studies, whereas the geranylazide group may be more useful for general protein modification and immobilization.