Crystallographic analysis of transition state mimics bound to penicillopepsin: difluorostatine- and difluorostatone-containing peptides.

Difluorostatine- and difluorostatone-containing peptides have been evaluated as potent inhibitors of penicillopepsin, a member of the aspartic proteinase family of enzymes. Isovaleryl-Val-Val-StaF2NHCH3 [StaF2 = (S)-4-amino-2,2-difluoro-(R)-3-hydroxy-6-methylheptanoic acid] and isovaleryl-Val-Val-StoF2NHCH3 [StoF2 = (S)-4-amino-2,2-difluoro-3-oxo-6-methylheptanoic acid] have measured Ki's of 10 x 10(-9) and 1 x 10(-9) M, respectively, with this fungal proteinase. The StoF2-containing peptide binds 32-fold more tightly to the enzyme than the analogous peptide containing the non-fluorinated statine ethyl ester. Each compound was cocrystallized with penicillopepsin, intensity data were collected to 1.8-A resolution, and the atomic coordinates were refined to an R factor [formula: see text] of 0.131 for both complexes. The inhibitors bind in the active site of penicillopepsin in much the same fashion as do other statine-containing inhibitors of penicillopepsin analyzed earlier [James, M. N. G., Sielecki, A. Salituro, F., Rich, D. H., & Hofmann, T. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 6137-6141; James, M.N.G., Sielecki, A., & Hofmann, T. (1985) in Aspartic Proteinases and their Inhibitors (Kosta, V., Ed.) pp 163-177, Walter deGruyter, Berlin]. The (R)-3-hydroxyl group in StaF2 binds between the active site carboxyl groups of Asp33 and Asp213, making hydrogen-bonding contacts to each one. The ketone functional group of the StoF2 inhibitor is bound as a hydrated species, with the gem-diol situated between the two aspartic acid carboxyl groups in a manner similar to that predicted for the tetrahedral intermediate expected during the catalytic hydrolysis of a peptide bond [James, M. N. G., & Sielecki, A. (1985) Biochemistry 24, 3701-3713]. One hydrogen-bonding interaction from the "outer" hydroxyl group is made to O delta 1 of Asp33, and the "inner" hydroxyl group forms two hydrogen-bonding contacts, one to each of the carboxyl groups of Asp33 (O delta 2) and Asp213 (O delta 2). The only structural difference between the StaF2 and StoF2 inhibitors that accounts for the factor of 10 in their Ki's is the additional (R)-3-OH group on the tetrahedral sp3 carbon atom of the hydrated StoF2 inhibitor. The intermolecular interactions involving the fluorine atoms of each inhibitor are normal van der Waals contacts to one of the carboxyl oxygen atoms of Asp213 (F2-O delta 2 Asp213, 2.9 A). The observed stereochemistry of the bound StoF2 group in the active site of penicillopepsin has stimulated our reappraisal of the catalytic pathway for the aspartic proteinases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Possible role for water dissociation in the slow binding of phosphorus-containing transition-state-analogue inhibitors of thermolysin

A number of phosphonamidate and phosphonate tripeptide analogues have been studied as transition-state-analogue inhibitors of the zinc endopeptidase thermolysin. Those with the form Cbz-GlyP(Y)Leu-X [ZGP(Y)LX, X = NH2 or amino acid, Y = NH or O linkage] are potent (Ki = 9-760 nM for X = NH, 9-660 microM for X = O) but otherwise ordinary in their binding behavior, with second-order rate constants for association (kon) greater than 10(5) M-1 s-1. Those with the form Cbz-XP(Y)-Leu-Ala [ZXP(Y)LA,XP = alpha-substituted phosphorus amino acid analogue] are similarly potent (Ki for ZFPLA = 68 pM) but slow binding (kon less than or equal to 1300 M-1 s-1). Several kinetic mechanisms for slow binding behavior are considered, including two-step processes and those that require prior isomerization of inhibitor or enzyme to a rare form. The association rates of ZFPLA and ZFP(O)LA are first order in inhibitor concentration up to 1-2 mM, indicating that any loose complex along the binding pathway must have a dissociation constant above this value. The crystallographic investigation described in the preceding paper [Holden, H. M., Tronrud, D. E., Monzingo, A. F., Weaver, L. H., & Matthews, B. W. (1987) Biochemistry (preceding paper in this issue)] identifies a specific water molecule in the active site that may hinder binding of the alpha-substituted inhibitors. The implication of this observation for a mechanism for slow binding is discussed.     

Catalytic strategy of citrate synthase: effects of amino acid changes in the acetyl-CoA binding site on transition-state analog inhibitor complexes.

Acetyl-CoA enol has been proposed as an intermediate in the citrate synthase (CS) reaction with Asp375 acting as a base, removing a proton from the methyl carbon of acetyl-CoA, and His274 acting as an acid, donating a proton to the carbonyl [Karpusas, M., Branchaud, B., & Remington, S.J. (1990) Biochemistry 29, 2213]. CS-oxaloacetate (OAA) complexes with the transition-state analog inhibitor, carboxymethyl-CoA (CMCoA), mimic those with acetyl-CoA enol. Asp375 and His274 interact intimately with the carboxyl of the bound inhibitor. While enzymes in which these residues have been changed to other amino acids have very low catalytic activity, we find that they retain their ability to form complexes with substrates and the transition-state analog inhibitor. In comparison with the value of the chemical shift of the protonated CMCoA carboxyl in acidic aqueous solutions or its value in the wild-type ternary complex, the values in the Asp375 mutants are unusually low. Model studies suggest that these low values result from complete absence of one hydrogen bond partner for the Gly mutant and distortions in the active site hydrogen bond systems for the Glu mutant. The high affinity of Asp375Gly-OAA for CMCoA suggests that the unfavorable proton uptake required to stabilize the CMCoA-OAA ternary complex of the wild-type enzyme [Kurz, L.C., Shah, S., Crane, B.R., Donald, L.J., Duckworth, H.W., & Drysdale, G.R. (1992) Biochemistry (preceding paper in this issue)] is not required by this mutant; the needed proton is most likely provided by His274. This supports the proposed role of His274 as a general acid.(ABSTRACT TRUNCATED AT 250 WORDS)     

A CLN2-related and thermostable serine-carboxyl proteinase, kumamolysin: cloning, expression, and identification of catalytic serine residue

The gene encoding kumamolysin, a thermostable pepstatin-insensitive carboxyl proteinase, was cloned and expressed. (i) Kumamolysin was synthesized as a large precursor consisting of two regions: amino-terminal prepro (188 amino acids) and mature proteins (384 amino acids). (ii) The deduced amino acid sequence of the mature region exhibited high similarity to those of such bacterial pepstatin-insensitive enzymes as Pseudomonas carboxyl proteinase (PSCP; EC 3.4.23.37, identity = 37%), Xanthomonas carboxyl proteinase (XCP; EC 3.4.23.33, identity = 36%), and human CLN2 gene product (identity = 36%), which is related to a fatal neurodegenerative disease. (iii) The presumed catalytic triad, Glu78, Asp82, Ser278 [three-dimensional structure of PSCP: Wlodawer, A. et al. (2001) Nature Struct. Biol., 8, 442-446], was found to be conserved in the amino acid sequence of kumamolysin. (iv) Kumamolysin was inactivated by such aldehyde-type inhibitors as Ac-Ile-Pro-Phe-CHO (K(i) = 0.7 0.14 microM). In PSCP, it has been clarified that these inhibitors form a hemiacetal linkage with the catalytic serine residue and inactivate the enzyme. (v) Mutational analysis of the Ser278 residue revealed that the mutant lost both auto-processing activity and proteolytic activity. These results strongly suggest that kumamolysin has a unique catalytic triad consisting of Glu78, Asp82, and Ser278 residues, as previously observed for PSCP.     

Inhibition of serine proteases by peptidyl fluoromethyl ketones

We have synthesized peptidyl fluoromethyl ketones that are specific inhibitors of the serine proteases alpha-chymotrypsin and porcine pancreatic elastase. By analogy with the corresponding aldehydes it is assumed that the fluoromethyl ketones react with the gamma-OH group of the active site serine to form a stable hemiacetal [Lowe, G., & Nurse, D. (1977) J. Chem. Soc., Chem. Commun., 815; Chen, R., Gorenstein, D.G., Kennedy, W.P., Lowe, G., Nurse, D., & Schultz, R.M. (1979) Biochemistry 18, 921; Shah, D.O., Lai, K., & Gorenstein, D.G. (1984) J. Am. Chem. Soc. 106, 4272]. 19F NMR studies of the chymotrypsin-bound trifluoromethyl ketone inhibitors Ac-Leu-ambo-Phe-CF3 and Ac-ambo-Phe-CF3 clearly indicate that the carbonyl carbon is tetrahedral at the active site of the enzyme. The inhibitor is bound as either the stable hydrate or the hemiacetal, involving the active site serine. The effect of varying the number of amino acid residues in the peptidyl portion of the inhibitor and the number of fluorines in the fluoromethyl ketone moiety is examined. In the series of trifluoromethyl ketone elastase inhibitors, the lowering of Ki concomitant with the change from a dipeptide analogue to a tetrapeptide analogue (Ac-Pro-ambo-Ala-CF3, Ki = 3 X 10(-3) M; Ac-Ala-Ala-Pro-ambo-Ala-CF3, Ki = 0.34 X 10(-6) M) correlates well with the variation in V/K for hydrolysis of the corresponding amide substrates. This trend is indicative of the inhibitors acting as transition-state analogues [Bartlett, P.A., & Marlowe, C.K. (1983) Biochemistry 22, 4618; Thompson, R.C. (1973) Biochemistry 12, 47].(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanism-based inactivation of dopamine beta-hydroxylase by p-cresol and related alkylphenols

The mechanism-based inhibition of dopamine beta-hydroxylase (DBH; EC 1.14.17.1) by p-cresol (4-methylphenol) and other simple structural analogues of dopamine, which lack a basic side-chain nitrogen, is reported. p-Cresol binds DBH by a mechanism that is kinetically indistinguishable from normal dopamine substrate binding [DeWolf, W. E., Jr., & Kruse, L. I. (1985) Biochemistry 24, 3379]. Under conditions (pH 6.6) of random oxygen and phenethylamine substrate addition [Ahn, N., & Klinman, J. P. (1983) Biochemistry 22, 3096] p-cresol adds randomly, whereas at pH 4.5 or in the presence of fumarate "activator" addition of p-cresol precedes oxygen binding as is observed with phenethylamine substrate. p-Cresol is shown to be a rapid (kinact = 2.0 min-1, pH 5.0) mechanism-based inactivator of DBH. This inactivation exhibits pseudo-first-order kinetics, is irreversible, is prevented by tyramine substrate or competitive inhibitor, and is dependent upon oxygen and ascorbic acid cosubstrates. Inhibition occurs with partial covalent incorporation of p-cresol into DBH. A plot of -log kinact vs. pH shows maximal inactivation occurs at pH 5.0 with dependence upon enzymatic groups with apparent pK values of 4.51 +/- 0.06 and 5.12 +/- 0.06. p-Cresol and related alkylphenols, unlike other mechanism-based inhibitors of DBH, lack a latent electrophile. These inhibitors are postulated to covalently modify DBH by a direct insertion of an aberrant substrate-derived benzylic radical into an active site residue.     

Development of the first potent and specific inhibitors of endocannabinoid biosynthesis

Enzymes for the biosynthesis and degradation of the endocannabinoid 2-arachidonoyl glycerol (2-AG) have been cloned and are the sn-1-selective-diacylglycerol lipases alpha and beta (DAGLalpha and beta) and the monoacylglycerol lipase (MAGL), respectively. Here, we used membranes from COS cells over-expressing recombinant human DAGLalpha to screen new synthetic substances as DAGLalpha inhibitors, and cytosolic fractions from wild-type COS cells to look for MAGL inhibitors. DAGLalpha and MAGL activities were assessed by using sn-1-[14C]-oleoyl-2-arachidonoyl-glycerol and 2-[3H]-arachidonoylglycerol as substrates, respectively. We screened known compounds as well as new phosphonate derivatives of oleic acid and fluoro-phosphinoyl esters of different length. Apart from the general lipase inhibitor tetrahydrolipstatin (orlistat) (IC50 approximately 60 nM), the most potent inhibitors of DAGLalpha were O-3640 [octadec-9-enoic acid-1-(fluoro-methyl-phosphoryloxymethyl)-propylester] (IC50 = 500 nM), and O-3841 [octadec-9-enoic acid 1-methoxymethyl-2-(fluoro-methyl-phosphinoyloxy)-ethyl ester] (IC50 = 160 nM). Apart from being almost inactive on MAGL, these two compounds showed high selectivity over rat liver triacylglycerol lipase, rat N-acylphosphatidyl-ethanolamine-selective phospholipase D (involved in anandamide biosynthesis), rat fatty acid amide hydrolase and human recombinant cannabinoid CB1 and CB2 receptors. Methylarachidonoyl-fluorophosphonate and the novel compound UP-101 [O-ethyl-O-p-nitro-phenyl oleylphosphonate] inhibited both DAGLalpha and MAGL with similar potencies (IC50 = 0.8-0.1 and 3.7-3.2 microM, respectively). Thus, we report the first potent and specific inhibitors of the biosynthesis of 2-AG that may be used as pharmacological tools to investigate the biological role of this endocannabinoid.     

Time-dependent inhibition of Bacillus stearothermophilus alanine racemase by (1-aminoethyl)phosphonate isomers by isomerization to noncovalent slowly dissociating enzyme-(1-aminoethyl)phosphonate complexes

An alanine racemase encoded by a gene from the thermophilic Gram-positive bacterium Bacillus stearothermophilus is overproduced to 0.3% of the soluble protein when carried on plasmid pICR4 in Escherichia coli [Inagaki, K., Tanizawa, K., Badet, B., Walsh, C. T., Tanaka, H., & Soda, K. (1986) Biochemistry (third paper of four in this issue)]. Purification of large quantities (50 mg) of racemase permits study of time-dependent inactivation by D and L isomers of the antibacterial (1-aminoethyl)phosphonate (Ala-P), the phosphonate analogue of alanine. The time-dependent activity loss by this compound now appears general to Gram-positive but not to Gram-negative racemases [Badet, B., & Walsh, C. (1985) Biochemistry 24, 1333] and is shown to occur by extremely slow dissociation of a noncovalent E X Ala-P complex. Ala-P binds initially in a weak, reversible (KI = 1 mM) competitive manner but is slowly isomerized (kinact = 6-9 min-1) to a stoichiometric enzyme complex, which in turn dissociates extremely slowly, with a half-time about 25 days. Thus, Ala-P is a slow but not a tight-binding inhibitor. The E X Ala-P complex is not reducible by borohydride but does perturb the fluorescence of bound pyridoxal 5'-phosphate coenzyme. Determination of the sequence of an active site octapeptide of the B. stearothermophilus alanine racemase shows homology with the sequence of a Gram-negative Salmonella typhimurium alanine racemase that is not susceptible to time-dependent inhibition by Ala-P. Studies with Ala-P analogues suggest the phosphonate dianion is crucial for stable formation of an isomerized long-lived E X Ala-P-inhibited complex.     

Structure and refinement of penicillopepsin at 1.8 A resolution

Penicillopepsin, the aspartyl protease from the mould Penicillium janthinellum, has had its molecular structure refined by a restrained-parameter least-squares procedure at 1.8 Å resolution to a conventional R-factor of 0.136. The estimated co-ordinate accuracy for the majority of the 2363 atoms of the enzyme is better than 0.12 Å. The average atomic thermal vibration parameter, B, for the atoms of the enzyme is 14.5 Ų. One determining factor of this low average B value is the large central hydrophobic core, in which there are two prominent clusters of aromatic residues, one of nine, the other of seven residues. The N and C-terminal domains of penicillopepsin display an approximate 2-fold symmetry: 70 residue pairs are topologically equivalent, related by a rotation of 177 ° and a translation of 1.2 Å. The analysis of the secondary structural features of the molecule reveals non-linear hydrogen bonding. In penicillopepsin, there is no difference in the mean hydrogen-bond parameters for the elements of α-helix, parallel or antiparallel β-pleated sheet. The mean values for these structural elements are: NO, 2.90 Å; NHO, 1.95 Å; N?O, 160 °. The average hydrogen-bond parameters of the reverse β-turns and the 3₁₀ helices are distinctly different from the above values. The analysis of sidechain conformational angles χ¹ and χ² penicillopepsin and other enzyme structures refined in this laboratory shows much narrower distributions as compared with those compiled from unrefined protein structures. The close proximity of the carboxyl groups of Asp33 and Asp213 suggests that they share a proton in a tight hydrogen-bonded environment (Asp33OD2 to Asp213OD1 is 2.87 Å). There are several solvent molecules in the active site region and, in particular, O39 forms hydrogen-bonded interactions with both aspartate residues. The disposition of the two carboxyl groups suggests that neither is likely to be involved in a direct nucleophilic attack on the scissile bond of a substrate. The average atomic B-factors of the residues in this region of the molecule are between 5 and 8 Ų, confirming the proposal that conformational mobility of the active site residues has no role in the enzymatic mechanism. However, conformational mobility of neighbouring regions of the molecule e.g. the “flap” containing Tyr75, is verified by the high B-factors for those residues. The positions of 319 solvent sites per asymmetric unit have been selected from difference electron density maps and refined. Thirteen have been classified as internal, and several of these may have key roles during catalysis. The positively charged N^ζ atom of Lys304 forms hydrogen bonds to the carboxylate of Asp14 (internal ion pair) and to two internal water molecules O5 and O25. The protonated side-chain of Asp300 forms a hydrogen bond to Thr214O, 2.78 Å, and is the recipient of a hydrogen bond from a surface pocket water molecule O46. There is no possibility for direct interaction between Asp300 and Lys304 without large conformational changes of their environment. The intermolecular packing involves many protein-protein contacts (66 residues) with a large number of solvent molecules involved in bridging between polar residues at the contact surface. The penicillopepsin molecules resemble an approximate hexagonal close-packing of spheres with each molecule having 12 “nearest” neighbours.     

Linkage of thioredoxin stability to titration of ionizable groups with perturbed pKa

The highly conserved, buried, Asp 26 in Escherichia coli thioredoxin has a pKa = 7.5, and its titration is associated with a sizable destabilization of the protein [Langsetmo, K., Fuchs, J., & Woodward, C. (1991) Biochemistry (preceding paper in this issue)]. A fit of the experimental pH dependence of thioredoxin stability to a theoretical expression for the pH/stability relation in proteins agrees closely with a pKa value of 7.5 for Asp 26. The agreement between the experimental and theoretical changes in protein stability due to substitution of Asp 26 by alanine is also good. The local structure in the vicinity of Asp 26 in the low-pH crystal structure (with uncharged Asp 26) is hydrophobic, indicating that the aspartate would be highly destabilized. In theoretical calculations, the desolvation penalty for deprotonating Asp 26 in this environment is similar to the total protein folding energy. As a consequence, the Asp 26 pKa would be much greater than 7.5, and/or the protein might not fold. This suggests that a compensating process partially stabilizes the Asp 26 carboxyl group when it is charged. A simple model for this proposed, whereby the Lys 57 side chain rotates to form a salt bridge with Asp 26 when it is deprotonated.     

Peptidic phosphonylating agents as irreversible inhibitors of serine proteases and models of the tetrahedral intermediates

Peptide analogues incorporating an electrophilic phosphorus moiety (2-6) have been synthesized and studied as inhibitors of a variety of serine proteases. Inhibition is irreversible and, for alpha-lytic protease (ALP), shown to result from covalent binding to the active site serine hydroxyl [Bone, R., Sampson, N. S., Bartlett, P.A., & Agard, D. A. (1991) Biochemistry (following paper in this issue)]. For reaction of human leukocyte elastase (HLE) with the thiophenyl esters 6s-V (Boc-AAPV psi [P = O(SPh)O]AA-OMe), 4s-V (BocAAPV psi [P = O(SPh)O]-Me), and 3s-V (Boc-V psi [P = O(SPh)O]AA-OMe), evidence is presented to suggest that the S4-S1 subsites, but not the S1' and S2' positions, are occupied by the inhibitors during the inactivation process. The selectivity that is observed between the proteases and the hexapeptide phosphonates 6o-V (Boc-AAPV psi [P = O(OPh)O]AA-OMe) and 6o-F (Boc-AAPF psi [P = O(OPh)O]AA-OMe) parallels that between these enzymes and their substrates: ALP and HLE are selectively inactivated by the ValP-containing analogue 6o-V, while subtilisin (SUB) shows a preference for the PheP derivative 6o-F. A detailed kinetic analysis of the enzyme-inhibitor interactions was complicated by the susceptibility of the inhibitors to enzymatic degradation. The configuration at phosphorus was found not to have a significant influence on the rate at which the inhibitors react with the peptidases. Moreover, in the case of inactivation of ALP by the hexapeptide 6o-V, the same covalent adduct is formed from both stereoisomers (Bone et al., 1991), indicating that one of these diastereomers undergoes substitution with retention of configuration.     

Phosphonate analogues of carboxypeptidase A substrates are potent transition-state analogue inhibitors

Analogues of tri- and tetrapeptide substrates of carboxypeptidase A in which the scissile peptide linkage is replaced with a phosphonate moiety (-PO2--O-) were synthesized and evaluated as inhibitors of the enzyme. The inhibitors terminated with either L-lactate or L-phenyllactate [designated (O) Ala and (O) Phe, respectively] in the P1' position. Transition-state analogy was shown for a series of 14 tri- and tetrapeptide derivatives containing the structure RCO-AlaP-(O)Ala [RCO-AP(O)A, AP indicates the phosphonic acid analogue of alanine] by the correlation of the Ki values for the inhibitors and the Km/kcat values for the corresponding amide substrates. This correlation supports a transition state for the enzymatic reaction that resembles the tetrahedral intermediate formed upon addition of water to the scissile carbonyl group. The inhibitors containing (O) Phe at the P1' position proved to be the most potent reversible inhibitors of carboxypeptidase A reported to date: the dissociation constants of ZAFP(O)F, ZAAP(O)F, and ZFAP(O)F are 4, 3, and 1 pM, respectively. Because of the high affinity of these inhibitors, their dissociation constants could not be determined by steady-state methods. Instead, the course of the association and dissociation processes was monitored for each inhibitor as its equilibrium with the enzyme was established in both the forward and reverse directions. A phosphonamidate analogue, ZAAPF, in which the peptide linkage is replaced with a -PO2-NH- moiety, was prepared and shown to hydrolyze rapidly at neutral pH (t1/2 = 20 min at pH 7.5). This inhibitor is bound an order of magnitude less tightly than the corresponding phosphonate, ZAAP(O)F, a result that contrasts with the 840-fold higher affinity of phosphonamidates for thermolysin [Bartlett, P. A., & Marlowe, C. K. (1987) Science 235, 569-571], a zinc peptidase with a similar arrangement of active-site catalytic residues.     

Crystal structure of the complex of carboxypeptidase A with a strongly bound phosphonate in a new crystalline form: comparison with structures of other complexes

O-[[(1R)-[[N-(Phenylmethoxycarbonyl)-L-alanyl]amino]ethyl] hydroxyphosphinyl]-L-3-phenyllacetate [ZAAP(O)F], an analogue of (benzyloxycarbonyl)-Ala-Ala-Phe or (benzyloxycarbonyl)-Ala-Ala-phenyllactate, binds to carboxypeptidase A with great affinity (Ki = 3 pM). Similar phosphonates have been shown to be transition-state analogues of the CPA-catalyzed hydrolysis [Hanson, J. E., Kaplan, A. P., & Bartlett, P. A. (1989) Biochemistry 28, 6294-6305]. In the present study, the structure of the complex of this phosphonate with carboxypeptidase A has been determined by X-ray crystallography to a resolution of 2.0 A. The complex crystallizes in the space group P2(1)2(1)2(1) with cell dimensions a = 61.9 A, b = 67.2 A, and c = 76.2 A. The structure of the complex was solved by molecular replacement. Refinement of the structure against 20,776 unique reflections between 10.0 and 2.0 A yields a crystallographic residual of 0.193, including 140 water molecules. The two phosphinyl oxygens of the inhibitor bind to the active-site zinc at 2.2 A on the electrophilic (Arg-127) side and 3.1 A on the nucleophilic (Glu-270) side. Various features of the binding mode of this phosphonate inhibitor are consistent with the hypothesis that carboxypeptidase A catalyzed hydrolysis proceeds through a general-base mechanism in which the carbonyl carbon of the substrate is attacked by Zn-hydroxyl (or Zn-water). An unexpected feature of the bound inhibitor, the cis carbamoyl ester bond at the benzyloxycarbonyl linkage to alanine, allows the benzyloxycarbonyl phenyl ring of the inhibitor to interact favorably with Tyr-198. This complex structure is compared with previous structures of carboxypeptidase A, including the complexes with the potato inhibitor, a hydrated keto methylene substrate analogue, and a phosphonamidate inhibitor. Comparisons are also made with the complexes of thermolysin with some phosphonamidate inhibitors.     

Enzymatic synthesis and inhibitory characteristics of tartronate semialdehyde phosphate

The immediate product of the pyruvate kinase catalyzed phosphorylation of beta-hydroxypyruvate is the enol of tartronate semialdehyde phosphate (TSP). The reaction has the same pH profile as that for the phosphorylation of pyruvate with pK's of 8.2 and 9.7 observed in H2O. This enol tautomerizes in solution to the aldehyde, which in turn becomes hydrated. 31P NMR spectra indicate that the enol resonates approximately 1 ppm upfield from the hydrated aldehyde. By following the tautomerization spectrophotometrically at 240 nm, we have found it to be independent of pH (0.2 min-1 below pH 6 in water), except that it is 2-fold slower above the pK of the phosphate group (6.3 in H2O and 6.7 in D2O). It is 3.6-fold slower in D2O. When this TSP is reduced with NaBH4, approximately 50% of the product is D-2-phosphoglyceric acid (substrate for enolase). Thus, while the immediate product of the phosphorylation rection is the enol of TSP, the eventual product is D,L-TSP. Both the enol and the aldehyde forms of TSP were found to be potent inhibitors of yeast enolase with apparent Ki values of 100 nM and 5 microM, respectively. However, since the aldehyde form is 95-99% hydrated [Stubbe, J., & Abeles, R. (1980) Biochemistry 19, 5505], the true Ki for the aldehyde species is 50-250 nM. The enol of TSP shows slow binding behavior, as expected for an intermediate analogue, with a t1/2 for this process of approximately 15 s (k = 0.046 s-1) and an initial Ki of approximately 200 nM.     

Synthesis and biological activity of new conformationally restricted analogues of pepstatin.

A new statine derivative, 3-hydroxy-4-amino-5-mercaptopentanoic acid; cysteinylstatine (CySta), was synthesized and used to prepare a series of conformationally restricted analogues of pepstatin (Iva-Val-Val-Sta-Ala-Sta) in which the conformational constraint was introduced via a bis-sulfide connecting the appropriately substituted residues in the P1 and the P3 inhibitor side chains. The precursor peptide, Iva-Cys-Val-CySta-Ala-Iaa, was synthesized and alkylated with a series of dibromoalkanes and alkenes to produce the cyclic structures. This strategy permitted the carbon atom spacing between the P1 and the P3 inhibitor side chains to be systematically varied so as to produce inhibitors with 15-, 16-, and 17-membered ring systems. Additional non-cyclic analogues were synthesized as controls by alkylating the bisthiol intermediates with methyl iodide. The inhibitory potency of the analogues were determined against porcine pepsin and penicillopepsin by using standard enzyme kinetic assays. The cyclic inhibitor were found to be potent inhibitors of both aspartic proteases; inhibitor that contained a trans-2-butene link between the two sulfur atoms was found to be the most potent inhibitor with a Ki less than 1 nM against pepsin and 3.94 nM against penicillopepsin. This series of compounds illustrates a new type of conformational restriction that can be used to probe for the bioactive conformation of peptides.     

Possible involvement of the A20-A21 peptide bond in the expression of the biological activity of insulin. 2. [21-Asparagine diethylamide-A]insulin

We have synthesized [21-asparagine diethylamide-A]insulin, which differs from the parent molecule in that the free carboxyl group of the C-terminal amino acid residue, asparagine, of the A chain moiety has been converted to a diethylamide group. The analogue displays equivalent potency in receptor binding and biological activity, 48% and 56%, respectively, relative to bovine insulin. In contrast, we have reported previously [Burke, G. T., Chanley, J. D., Okada, Y., Cosmatos, A., Ferderigos, N., & Katsoyannis, P. G. (1980) Biochemistry 19, 4547-4556] that [21-asparaginamide-A]insulin exhibits a divergence in these properties, ca. 60% in receptor binding and ca. 13% in biological activity. The disparity in the biological behavior of these analogues is discussed, and we ascribe the modulation of biological activity independent of receptor binding activity observed between these analogues to the difference in the negativity of the carbonyl oxygen of the A chain moiety C-terminal amino acid residue.     

Roles of adjoining Asp and Cys residues of first matrix-facing loop in transport activity of yeast and bovine mitochondrial ADP/ATP carriers

The mitochondrial ADP/ATP carrier (AAC) transports substrate by interconversion of its conformation between m- and c-states. The 1st loop facing the matrix (LM1) is extruded into the matrix in the m-state and is suggested to intrude into the mitochondrial membrane on conversion to the c-state conformation [Hashimoto, M., Majima, E., Goto, S., Shinohara, Y., and Terada, H. (1999) Biochemistry 38, 1050-1056]. To elucidate the mechanism of the translocation of LM1, we examined the effects of site-directed mutagenesis of two adjoining residues, Cys56 and Asp55 in the bovine type 1 AAC and Cys73 and Asp72 in the yeast type 2 AAC, on the substrate transport activity. We found that (i) replacement of the Cys by bulky and hydrophilic residues was unfavorable for efficient transport activity, (ii) the carboxyl groups of the Asp residues of the bovine and yeast AACs were essential and strictly position-specific, and (iii) hence, the mutation to Glu showed transport activity comparable to that of the native AACs. Based on these results, we discussed the functional role of LM1 in the transport activity of AAC.     

Design, synthesis, and metal binding of novel Pseudo- oligopeptides containing two phosphinic acid groups

Phosphinic compounds have potential as amide-bond mimetics in the development of novel peptidomimetics, enzyme inhibitors, and metal-binding ligands. Novel pseudo-oligopeptides with two phosphinic acid groups embedded in the peptide backbone serving as amide-bond surrogates, Psi[P(O,OH)--CH(2)], were targeted. A series of linear and cyclic pseudo-oligopeptides with two phosphinic acid groups arrayed at different positions in the peptide sequence were designed, including Ac--Phe--{(R,S)--AlaPsi[P(O,OH)--CH(2)]Gly}(2)--NH(2) (P2), Ac--NH--(R,S)--AlaPsi[P(O,OH)--CH(2)]Gly--Phe--(R,S)--AlaPsi[P(O,OH)--CH(2)]Gly--NH(2) (P3), Ac--NH--(R,S)--AlaPsi[P(O,OH)--CH(2)]Gly--Phe--Phe--(R,S) --AlaPsi[P(O,OH)--CH(2)]Gly--NH(2) (P4), cyclo{NH--(R,S)--AlaPsi[P(O,OH)--CH(2)]Gly--Phe}(2) (P5), and cyclo[NH--(R,S)--AlaPsi[P(O,OH)--CH(2)]Gly--Phe--Phe](2) (P6). They were synthesized via conventional Fmoc chemistry on solid support utilizing Fmoc-protected phosphinic acid-containing pseudo-dipeptide fragment, i.e. Fmoc--(R,S)--AlaPsi[P(O,OCH(3))--CH(2)]Gly--OH. The pseudo-peptides containing two phosphinic acid groups exhibited the highest binding affinity and selectivity for Fe(III) among the 10-metal ions screened by ESI-MS analysis--Cu(II), Zn(II), Co(II), Ni(II), Mn(II), Fe(II), Fe(III), Al(III), Ga(III), and Gd(III). P4 and P6 with 11-atom linkages between the two phosphinic acids preferred intramolecular metal binding to form 1:1 ligand/metal complexes. As revealed by competition experiments, P4 showed the highest relative binding affinity among the six compounds tested. Noteworthy, P4 also showed higher relative binding affinity than similar dihydroxamate-containing pseudo-peptides reported previously. The novel structural prototype and facile synthesis along with selective and potent Fe(III) binding strongly suggest that pseudo-peptides containing the two or more phosphinic groups as amide-bond surrogates deserve further exploration in medicinal chemistry.     

Reaction intermediate analogues for enolase

A number of compounds that appear to be analogues of the aci form of the normal carbanion intermediate are good inhibitors of yeast enolase. These include (3-hydroxy-2-nitropropyl)phosphonate (I), the ionized (pK = 8.1) nitronate form of which in the presence of 5 mM Mg2+ has a Ki of 6 nM, (nitroethyl)phosphonate (III) (pK = 8.5; Ki of the nitronate in the presence of 5 mM Mg2+ = 1 microM), phosphonoacetohydroxamate (IV) (pK = 10.2; Ki with saturating Mg2+ for the ionized form = 15 pM), and (phosphonoethyl)nitrolate (VII) (Ki at 1 mM Mg2+ = 14 nM). The oxime of phosphonopyruvate (VI) has a pH-independent Ki of 75 microM. I, IV, VI, and VII are slow binding inhibitors. All of these compounds are trigonal at the position analogous to C-2 of 2-phosphonoglycerate and contain a phosphono group, but a negatively charged metal ligand at the position isosteric with the hydroxyl attached to C-3 of 2-phosphoglycerate (as in IV) appears to contribute more to binding than a nitro group isosteric with the carboxyl of 2-phosphoglycerate (I and III). These data support the carbanion mechanism for enolase and suggest that the 3-hydroxyl of 2-phosphoglycerate is directly coordinated to Mg2+ prior to being eliminated to give phosphoenolpyruvate.     

Mechanism of inactivation of gamma-aminobutyrate aminotransferase by 4-amino-5-fluoropentanoic acid. First example of an enamine mechanism for a gamma-amino acid with a partition ratio of 0

The mechanism of inactivation of pig brain gamma-aminobutyric acid aminotransferase (GABA-T) by (S)-4-amino-5-fluoropentanoic acid (1, R = CH2CH2COOH, X = F) previously proposed [Silverman, R. B., & Levy, M. A. (1981) Biochemistry 20, 1197-1203] is revised. apo-GABA-T is reconstituted with [4-3H]pyridoxal 5'-phosphate and inactivated with 1 (R = CH2CH2COOH, X = F). Treatment of inactivated enzyme with base followed by acid denaturation leads to the complete release of radioactivity as 6-[2-hydroxy-3-methyl-6-(phosphonoxymethyl)-4-pyridinyl]-4-oxo-5-+ ++hexenoic acid (4, R = CH2CH2COOH). Alkaline phosphatase treatment of this compound produces dephosphorylated 4 (R = CH2CH2COOH). These results support a mechanism that was suggested by Metzler and co-workers [Likos, J. J., Ueno, H., Feldhaus, R. W., & Metzler, D. E. (1982) Biochemistry 21, 4377-4386] for the inactivation of glutamate decarboxylase by serine O-sulfate (Scheme I, pathway b, R = COOH, X = OSO3-).