Inhibitors of human heart chymase based on a peptide library.

We have synthesized two sets of noncleavable peptide-inhibitor libraries to map the S and S' subsites of human heart chymase. Human heart chymase is a chymotrypsin-like enzyme that converts angiotensin I to angiotensin II. The first library consists of peptides with 3-fluorobenzylpyruvamides in the P1 position. (Amino acid residues of substrates numbered P1, P2, etc., are toward the N-terminal direction, and P'1, P'2, etc., are toward the C-terminal direction from the scissile bond.) The P'1 and P'2 positions were varied to contain each one of the 20 naturally occurring amino acids and P'3 was kept constant as an arginine. The second library consists of peptides with phenylalanine keto-amides at P1, glycine in P'1, and benzyloxycarbonyl (Z)-isoleucine in P4. The P2 and P3 positions were varied to contain each of the naturally occurring amino acids, except for cysteine and methionine. The peptides of both libraries are attached to a solid support (pins). The peptides are evaluated by immersing the pins in a solution of the target enzyme and evaluating the amount of enzyme absorbed. The pins with the best inhibitors will absorb most enzyme. The libraries select the best and worst inhibitors within each group of peptides and provide an approximate ranking of the remaining peptides according to Ki. Through this library, we determined that Z-Ile-Glu-Pro-Phe-CO2Me and (F)-Phe-CO-Glu-Asp-ArgOMe should be the best inhibitors of chymase in this collection of peptide inhibitors. We synthesized the peptides and found Ki values were 1 nM and 1 microM, respectively. The corresponding Ki values for chymotrypsin were 10 nM and 100 microM. The use of libraries of inhibitors has advantages over the classical method of synthesis of potential inhibitors in solution: the libraries are reusable, the same libraries can be used with a variety of different serine proteases, and the method allows the screening of hundreds of compounds in short periods of time.     

Purification and characterization of yeast myristoyl CoA:protein N-myristoyltransferase.

Myristoyl CoA:protein N-myristoyltransferase (NMT) catalyzes the addition of myristic acid to the amino-terminal glycine residues of a number of eukaryotic proteins. Recently, we developed a cell-free system for analyzing NMT activity and have begun to characterize the substrate specificity of this enzyme by using a series of synthetic peptides. We have now purified NMT from Saccharomyces cerevisiae to apparent homogeneity. The native enzyme is a 55-kDa protein, exhibits no requirement for divalent cation, and appears to contain a histidine residue critical for enzyme activity. A total of 42 synthetic peptides have been used to define structure/activity relationships in NMT substrates. An amino-terminal glycine is required for acylation; substitution with glycine analogues produces peptides that are inactive as substrates or inhibitors of NMT. A broad spectrum of amino acids is permitted at positions 3 and 4, while strict amino acid requirements are exhibited at position 5. Replacement of Ala5 in the peptide Gly-Asn-Ala-Ala-Ala-Ala-Arg-Arg with Asp ablates the peptide's myristoyl-accepting activity. A serine at this position results in a decrease by a factor of approximately equal to 500 in the apparent Km in the context of three different sequences. Penta- and hexa-peptides are substrates, but with decreased affinity. These studies establish that structural information important for NMT-ligand interaction exists beyond the first two amino acids in peptide substrates and that the side chains of residue 5 play a critical role in the binding of substrates to this enzyme.     

Glu-192----Gln substitution in thrombin mimics the catalytic switch induced by thrombomodulin.

In serine proteases, residue 192, three residues prior to the active site Ser-195, plays an important role in determining substrate specificity. In trypsin (EC 3.4.21.4) and most trypsin-like enzymes with relatively broad specificity, this position is occupied by Gln. In thrombin (EC 3.4.21.5), an enzyme with restricted specificity, position 192 is occupied by Glu. The potential importance of Glu-192 in restricting the specificity of thrombin was investigated by isosterically replacing Glu-192 with Gln. Unlike trypsin, thrombin cleavage of peptides with acidic residues in positions P3 and P'3 [where P3 and P'3 refer to three residues removed from the Arg (P1) cleavage site on the amino and carboxyl side, respectively] is inefficient. Protein C, an anticoagulant zymogen, has Asp residues in positions P3 and P'3. Thrombomodulin, an endothelial cell protein, complexes with thrombin to activate protein C rapidly thus altering the specificity of thrombin. Compared to thrombin, the Glu-192----Gln mutant thrombin activates protein C 22 times more rapidly and cleaves the P7-P'5 peptide from the protein C activation site 19 times faster. Enhanced protein C activation results primarily from an increase in the catalytic rate constant rather than an improved Michaelis constant, a property that is shared by the thrombin-thrombomodulin complex. The Glu-192----Gln mutation does not influence fibrinopeptide A release and only increases the rate of fibrinopeptide B release 2.7-fold. These results demonstrate that Glu-192 plays a critical role in restricting the specificity of thrombin and suggest that thrombomodulin may function in part by altering the enzyme-substrate interaction near residue 192 in thrombin.     

Binding specificity of Escherichia coli trigger factor

The ribosome-associated chaperone trigger factor (TF) assists the folding of newly synthesized cytosolic proteins in Escherichia coli. Here, we determined the substrate specificity of TF by examining its binding to 2842 membrane-coupled 13meric peptides. The binding motif of TF was identified as a stretch of eight amino acids, enriched in basic and aromatic residues and with a positive net charge. Fluorescence spectroscopy verified that TF exhibited a comparable substrate specificity for peptides in solution. The affinity to peptides in solution was low, indicating that TF requires ribosome association to create high local concentrations of nascent polypeptide substrates for productive interaction in vivo. Binding to membrane-coupled peptides occurred through the central peptidyl-prolyl-cis/trans isomerase (PPIase) domain of TF, however, independently of prolyl residues. Crosslinking experiments showed that a TF fragment containing the PPIase domain linked to the ribosome via the N-terminal domain is sufficient for interaction with nascent polypeptide substrates. Homology modeling of the PPIase domain revealed a conserved FKBP(FK506-binding protein)-like binding pocket composed of exposed aromatic residues embedded in a groove with negative surface charge. The features of this groove complement well the determined substrate specificity of TF. Moreover, a mutation (E178V) in this putative substrate binding groove known to enhance PPIase activity also enhanced TF's association with a prolyl-free model peptide in solution and with nascent polypeptides. This result suggests that both prolyl-independent binding of peptide substrates and peptidyl-prolyl isomerization involve the same binding site.     

Global analysis of proteasomal substrate specificity using positional-scanning libraries of covalent inhibitors

The proteasome is a large protease complex consisting of multiple catalytic subunits that function simultaneously to digest protein substrates. This complexity has made deciphering the role each subunit plays in the generation of specific protein fragments difficult. Positional scanning libraries of peptide vinyl sulfones were generated in which the amino acid located directly at the site of hydrolysis (P1 residue) was held constant and sequences distal to that residue (P2, P3, and P4 positions) were varied across all natural amino acids (except cysteine and methionine). Binding information for each of the individual catalytic subunits was obtained for each library under a variety of different conditions. The resulting specificity profiles indicated that substrate positions distal to P1 are critical for directing substrates to active subunits in the complex. Furthermore, specificity profiles of IFN-gamma-regulated subunits closely matched those of their noninducible counterparts, suggesting that subunit swapping may modulate substrate processing by a mechanism that does require a change in the primary sequence specificity of individual catalytic subunits in the complex. Finally, specificity profiles were used to design specific inhibitors of a single active site in the complex. These reagents can be used to further establish the role of each subunit in substrate processing by the proteasome.     

Isolation and primary structure of tumor-derived peptides related to human pancreastatin and chromogranin A.

Using an antiserum raised against a synthetic C-terminal peptide of porcine pancreastatin, we detected pancreastatin-like immunoreactivity (PLI) in human pancreatic islets, adrenal medulla, and endocrine tumors. From a carcinoid liver metastasis, human PLI was extracted and purified by HPLC. Two C-terminally amidated peptides were isolated and characterized by sequence analysis. The first peptide, hCgA-210-301, consists of 92 amino acid residues with glycinamide as C terminus. It is identical to the cDNA-derived sequence of human chromogranin A, positions 210-301, which is preceded by two basic residues indicating a putative processing site. The C-terminal part, positions 250-301, shows 70% sequence identity to porcine pancreastatin and represents the human pancreastatin-like sequence. The second peptide, hCgA-273-301, represents a C-terminally amidated fragment of the human pancreastatin sequence, generated by an Asp-Pro cleavage at the N terminus. Peptide hCgA-273-301 was synthesized to confirm the structure of the natural peptide. Two other peptides derived from human chromogranin A were isolated and partially characterized. They are generated by proteolytic cleavage after dibasic amino acids Lys-Arg (positions 338-339) and after Trp-376 of the human chromogranin A sequence, respectively. These results indicate that chromogranin A may represent the precursor for pancreastatin-related and possibly other yet-unidentified peptides of unknown physiological function.     

Activity of purified biosynthetic proteinase of human immunodeficiency virus on natural substrates and synthetic peptides.

Retroviral capsid proteins and replication enzymes are synthesized as polyproteins that are proteolytically processed to the mature products by a virus-encoded proteinase. We have purified the proteinase of human immunodeficiency virus (HIV), expressed in Escherichia coli, to approximately 90% purity. The purified enzyme at a concentration of approximately 20 nM gave rapid, efficient, and specific cleavage of an in vitro synthesized gag precursor protein. Purified HIV proteinase also induced specific cleavage of five decapeptide substrates whose amino acid sequences corresponded to cleavage sites in the HIV polyprotein but not of a peptide corresponding to a cleavage site in another retrovirus. Competition experiments with different peptides allowed a ranking of cleavage sites. Inhibition studies indicated that the HIV proteinase was inhibited by pepstatin A with an IC50 of 0.7 microM.     

Identification of highest-affinity ligands by affinity selection from equimolar peptide mixtures generated by robotic synthesis

A fully automated peptide synthesizer has been constructed that is capable of the simultaneous synthesis of up to 36 individual peptides and the synthesis of equimolar peptide mixtures. The instrument consists of an array of reaction vessels, a series of solenoid valves to control liquid flow, and a Zymark robot to deliver solvents and reagents; all components are computer controlled and coordinated. Equimolar peptide mixtures are obtained by algorithms that automate the mixing and distribution of peptide-resin particles. This technology was used to synthesize a library of 361 peptides, generated by randomizing two critical binding residues of a 10-mer epitope known to bind an anti-human immuno-deficiency virus gp120 monoclonal antibody. Each critical residue was substituted with 19 amino acids consisting of all the natural amino acids except cysteine. The library was synthesized as 19 pools, each containing 19 peptides. Each pool was screened in a solution-phase competition ELISA assay. The 12 most inhibitory peptides in the library were isolated by a rapid affinity-selection method and were identified by mass spectrometry and amino acid analysis. The binding properties of these 12 selected peptides were verified by synthesis and assay of the individual peptides. The two critical residues investigated were found to contribute independently to antibody binding.     

A novel assay for factor XIII based on cross-linking of synthetic peptides: analysis of different substrates.

A novel assay for factor XIII is described that utilizes exclusively small synthetic peptides as substrates for the cross-linking reaction catalyzed by activated factor XIII (FXIIIa). The acyl donor substrate (selection peptide) is immobilized on a microplate via biotin while the acyl acceptor substrate (detection peptide) is labeled with the fluorochrome Oregon green to allow sensitive detection without the need for secondary enzyme systems for signal amplification. Starting with an amino acid sequence from the fibrin gamma-chain (GQQHHLGGAKQAGDV) as a prototype peptide, the influence of amino acid exchanges were investigated with respect to their impact on the FXIIIa-catalyzed reaction. It was found that FXIIIa readily accepts a broad range of substrate peptides, with a proline neighboring the essential lysine having the most detrimental effect. The assay appears to be valuable for the molecular characterization of factor XIII and may be used for a deeper investigation into the substrate requirements of this final enzyme of wound repair, and eventually also for the characterization of other transglutaminases.     

Substrate specificity of trypsin investigated by using a genetic selection.

The structural determinants of the primary substrate specificity of rat anionic trypsin were examined by using oligonucleotide-directed mutagenesis coupled to a genetic selection. A library was created that encoded trypsins substituted at amino acid positions 189 and 190 at the base of the substrate binding pocket. A genetic selection, with a dynamic range of 5 orders of proteolytic activity, was used to search 90,000 transformants of the library. Rapid screening for arginyl amidolysis and esterolysis confirmed the activity of the purified isolates. Trypsin and 15 mutant trypsins with partially preserved function were identified and characterized kinetically on arginyl and lysyl peptide substrates. Alternative arrangements of amino acids in the substrate binding pocket sustained efficient catalysis. A negative charge at amino acid position 189 or 190 was shown to be essential for high-level catalysis. With the favored aspartic acid residue at position 189, several amino acids could replace serine at position 190. Modulation of the specificity for arginine and lysine substrates was shown to depend on the amino acid at position 190. The regulatory effect of the amino acid side chain at position 190 on the substrate specificity is also reflected in substrate binding pockets of naturally occurring trypsin homologs.     

A herpesvirus maturational proteinase, assemblin: identification of its gene, putative active site domain, and cleavage site.

A herpesvirus proteinase activity has been identified and partially characterized by using the cloned enzyme and substrate genes in transient transfection assays. Evidence is presented that the proteinase gene of cytomegalovirus strain Colburn encodes a 590-amino acid protein whose N-terminal 249 residues contain the proteolytic activity and two domains that are highly conserved in the homologous protein of other herpesviruses. Insertion of a short amino acid sequence between these domains abolished proteinase activity, suggesting that this region constitutes part or all of the enzyme active site. Plasma desorption mass spectrometry was used to identify the C terminus of the mature assembly protein as alanine, enabling the recognition of a consensus proteinase cleavage sequence of V/L-X-A decreases S/V, near the C-terminal end of all herpesvirus assembly protein homologs. Interestingly, the proteinase and its substrate, the assembly protein precursor, are encoded by opposite halves of the same open reading frame.     

Structural effects of substitutions on the p21 proteins.

The conformational effects of different amino acid substitutions (lysine, serine, proline, and D-valine) for glycine at position 12 in the p21 oncogene-encoded proteins have been investigated by using conformational energy calculations. The normal cellular gene codes for a glycine at position 12 in the amino acid sequence, in the middle of a hydrophobic p21-(6-15)-decapepetide from Leu-6 to Gly-15. Mutations that cause amino acid substitutions for Gly-12 result in a protein product that produces malignant transformation of cells. We now find that not only are the preferred structures for the lysine- and serine-containing peptides more restricted and more helical than those for the glycine-containing peptide, but the lowest-energy structure for each substituted peptide is exactly the same as that previously found for the peptide with Val-12, suggesting the existence of a "malignancy-causing" conformation. None of the preferred conformations for the valine-, lysine-, and serine-containing peptides contain chain reversals at positions 11 and 12. However, we find that proline, unlike these residues but like glycine, at position 12 causes helix termination at positions 11 and 12, a result that suggests that the p21 protein product with proline at position 12 may exhibit lowered transforming potential, in agreement with the results of recent genetic recombination experiments.     

A protein geranylgeranyltransferase from bovine brain: implications for protein prenylation specificity.

A protein geranylgeranyltransferase (PGT) that catalyzes the transfer of a 20-carbon prenyl group from geranylgeranyl pyrophosphate to a cysteine residue in protein and peptide acceptors was detected in bovine brain cytosol and partially purified. The enzyme was shown to be distinct from a previously characterized protein farnesyltransferase (PFT). The PGT selectively geranylgeranylated a synthetic peptide corresponding to the C terminus of the gamma 6 subunit of bovine brain G proteins, which have previously been shown to contain a 20-carbon prenyl modification. Likewise, a peptide corresponding to the C terminus of human lamin B, a known farnesylated protein, selectively served as a substrate for farnesylation by the PFT. However, with high concentrations of peptide acceptors, both prenyl transferases were able to use either peptide as substrates and the PGT was able to catalyze farnesyl transfer. Among the prenyl acceptors tested, peptides and proteins with leucine or phenylalanine at their C termini served as geranylgeranyl acceptors, whereas those with C-terminal serine were preferentially farnesylated. These results suggest that the C-terminal amino acid is an important structural determinant in controlling the specificity of protein prenylation.     

Comparison of oral feeding of peptide and amino acid meals to normal human subjects

Intestinal perfusion studies performed in man have suggested that amino acid nitrogen may be absorbed more rapidly from peptides than free amino acids. The aim of the present study was to compare the effects of the oral administration of peptides and free amino acids. Two isonitrogenous liquid test meals, one containing 50 g of a partial enzymic hydrolysate of fish protein in which approximately 80% of the nitrogen content was present as small peptides (peptide meal), and the other a mixture of free amino acids (amino acid meal) the composition and molar pattern of which simulated that of the peptide meal, were administered on separate occasions to six normal subjects intubated with a triple lumen tube. Both meals contained the reference marker polyethylene glycol. Fractional absorption of amino acid residues one and two hours after ingestion of the two meals was similar at three intestinal locations situated 120, 160, and 200 cm from the mouth of each subject, and at two hours 73·8% and 72·0% of the amino acid residues had been absorbed respectively by the time the contents of the peptide and amino acid meals reached the middle sampling port of the tube. The total sum of individual amino acid increments in plasma was significantly greater 30 minutes (p < 0·025) and one hour (p < 0·05) after ingestion of the peptide than amino acid meals. By three hours the total area under the two plasma curves was similar. Normal human subjects thus appeared to be capable of assimilating orally administered mixtures of peptides and free amino acids with equal efficiency. Secretion of fluid into the lumen of the upper small intestine, assessed by reference to dilution of the polyethylene glycol, was less after ingestion of the peptide meal. In clinical situations characterised by fluid and electrolyte malabsorption consideration might be given to using small peptides rather than free amino acids as the nitrogen source in nutritional diets.     

Fabry disease: isolation of a cDNA clone encoding human alpha-galactosidase A.

Fabry disease is an X-linked inborn error of metabolism resulting from the deficient activity of the lysosomal hydrolase, alpha-galactosidase A (alpha-Gal A; alpha-D-galactoside galactohydrolase, EC 3.2.1.22). To investigate the structure, organization, and expression of alpha-Gal A, as well as the nature of mutations in Fabry disease, a clone encoding human alpha-Gal A was isolated from a lambda gt11 human liver cDNA expression library. To facilitate screening, an improved affinity purification procedure was used to obtain sufficient homogeneous enzyme for production of monospecific antibodies and for amino-terminal and peptide microsequencing. On the basis of an amino-terminal sequence of 24 residues, two sets of oligonucleotide mixtures were synthesized corresponding to adjacent, but not overlapping, amino acid sequences. In addition, an oligonucleotide mixture was synthesized based on a sequence derived from an alpha-Gal A internal tryptic peptide isolated by reversed-phase HPLC. Four positive clones were initially identified by antibody screening of 1.4 X 10(7) plaques. Of these, only one clone (designated lambda AG18) demonstrated both antibody binding specificity by competition studies using homogeneous enzyme and specific hybridization to synthetic oligonucleotide mixtures corresponding to amino-terminal and internal amino acid sequences. Nucleotide sequencing of the 5' end of the 1250-base-pair EcoRI insert of clone lambda AG18 revealed an exact correspondence between the predicted and known amino-terminal amino acid sequence. The insert of clone lambda AG18 appears to contain the full-length coding region of the processed, enzymatically active alpha-Gal A, as well as sequences coding for five amino acids of the amino-terminal propeptide, which is posttranslationally cleaved during enzyme maturation.     

Primary structure of the gamma-carboxyglutamic acid-containing protein from bovine bone.

The amino-acid sequence of the gamma-carboxyglutamic acid-containing protein of bovine bone is presented. The sequence of 43 of the 49 residues was determined automatically on the intact protein and on a tryptic peptide. The remainder was determined by conventional procedures on tryptic and chymotrytic peptides. Residue 9 in the sequence has been identified as 4-hydroxyproline. The protein contains three gamma-carboxyglutamic acid residues, which are located at positions 17, 21, and 24. The role of these unusual amino acids in the binding interaction between the protein and hydroxyapatite crystals is discussed.     

Identification of an inhibitory region of the heat-stable protein inhibitor of the cAMP-dependent protein kinase.

The present study was undertaken in order to identify the inhibitory site of the heat-stable inhibitor of cAMP-dependent protein kinase (PKI) and to synthesize a peptide that could serve as a useful inhibitor of the enzyme. Digestion of purified PKI by mast cell proteinase II yielded a peptide fragment that retained inhibitory activity. A sequence of 20 amino acids of the peptide, (sequence in text) revealed the presence of a "pseudosubstrate site" (Arg-Arg-Asn-Ala-Ile) for the cAMP-dependent protein kinase in which alanine replaces the seryl or threonyl residue that is normally phosphorylated. Digestion of PKI with various other proteinases implicated the involvement of arginyl and hydrophobic residues as determinants for the inhibitory activity. The assumption that this region is part of the inhibitory site was confirmed by the synthesis of a corresponding duodecapeptide that displayed strong inhibitory activity. Inhibition by the peptide was competitive with a Ki of 0.8 microM as measured against a number of protein substrates. The sequence of this fragment bears a strong resemblance to the autophosphorylation site in the type II regulatory subunit of cAMP-dependent protein kinase, a region also postulated to interact with the catalytic subunit, and the analogous region of type I regulatory subunit. Neither intact PKI nor the synthetic peptide inhibit the cGMP-dependent protein kinase, phosphorylase kinase, myosin light-chain kinase, casein kinase II, or protein kinase C.     

Periodicity of polar and nonpolar amino acids is the major determinant of secondary structure in self-assembling oligomeric peptides.

The tendency of a polypeptide chain to form alpha-helical or beta-strand secondary structure depends upon local and nonlocal effects. Local effects reflect the intrinsic propensities of the amino acid residues for particular secondary structures, while nonlocal effects reflect the positioning of the individual residues in the context of the entire amino acid sequence. In particular, the periodicity of polar and nonpolar residues specifies whether a given sequence is consistent with amphiphilic alpha-helices or beta-strands. The importance of intrinsic propensities was compared to that of polar/nonpolar periodicity by a direct competition. Synthetic peptides were designed using residues with intrinsic propensities that favored one or the other type of secondary structure. The polar/nonpolar periodicities of the peptides were designed either to be consistent with the secondary structure favored by the intrinsic propensities of the component residues or in other cases to oppose these intrinsic propensities. Characterization of the synthetic peptides demonstrated that in all cases the observed secondary structure correlates with the periodicity of the peptide sequence--even when this secondary structure differs from that predicted from the intrinsic propensities of the component amino acids. The observed secondary structures are concentration dependent, indicating that oligomerization of the amphiphilic peptides is responsible for the observed secondary structures. Thus, for self-assembling oligomeric peptides, the polar/nonpolar periodicity can overwhelm the intrinsic propensities of the amino acid residues and serves as the major determinant of peptide secondary structure.     

An HLA-A11-specific motif in nonamer peptides derived from viral and cellular proteins.

T lymphocytes recognize their antigenic targets as peptides associated with major histocompatibility complex molecules. The HLA-A11 allele, a preferred restriction element for Epstein-Barr virus (EBV)-specific cytotoxic T-lymphocyte responses, presents an immunodominant epitope derived from the EBV nuclear antigen 4. Subpicomolar concentrations of a synthetic nonamer peptide, IVTDFSVIK, corresponding to amino acids 416-424 of the EBV nuclear antigen 4 sequence, can sensitize phytohemagglutinin-stimulated blasts to lysis by EBV-specific HLA-A11-restricted cytotoxic T-lymphocytes. We show that micromolar concentrations of this peptide induce assembly and surface expression of HLA-A11 in an A11-transfected subline of the peptide transporter mutant cell line T2. Using the IVTDFSVIK peptide and a series of synthetic nonamer peptides, differing from the original sequence by single amino acid substitutions, we have defined a motif for HLA-A11-binding peptides. This predicts the presence of a hydrophobic amino acid in position 2, amino acids with small side chains in positions 3 and 6, and a lysine in position 9. Using this motif, we have identified a peptide in the carboxyl-terminal end of wild-type p53, ELNEALELK, which is able to induce HLA-A11 assembly as efficiently as the IVTDFSVIK viral peptide.     

Tetrapeptide inhibitors of protein farnesyltransferase: amino-terminal substitution in phenylalanine-containing tetrapeptides restores farnesylation.

Protein farnesyltransferase from rat brain transfers farnesyl residues to cysteine residues in tetrapeptides that conform to the sequence CA1A2X, where C is cysteine, A1 and A2 are aliphatic amino acids, and X is methionine or serine. When the A2 residue is aromatic [e.g., phenylalanine as in Cys-Val-Phe-Met (CVFM)], the tetrapeptide continues to bind to the enzyme, but it can no longer accept a farnesyl group, and it becomes a pure inhibitor. The current studies show that this resistance to farnesylation also requires a positive charge on the cysteine amino group. Derivatization of this group with acetyl, octanoyl, or cholic acid residues or extension of the peptide with an additional amino acid restores the ability of phenylalanine-containing peptides to accept a farnesyl residue. The same result was obtained when the amino group of cysteine was deleted (mercaptopropionyl-VFM). These data suggest that the positive change on the cysteine amino group acts in concert with an aromatic residue in the A2 position to render peptides resistant to farnesylation by the rat brain enzyme.