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.     

Phosphonamidates as transition-state analogue inhibitors of thermolysin

Six phosphorus-containing peptide analogues of the form Cbz-NHCH2PO2--L-Leu-Y (Y = D-Ala, NH2, Gly, L-Phe, L-Ala, L-Leu) have been prepared and evaluated as inhibitors of thermolysin. The Ki values for these compounds range from 1.7 microM to 9.1 nM and correlate well with the Km/kcat values for the corresponding peptide substrates [Morihara, K., & Tsuzuki, H. (1970) Eur. J. Biochem. 15, 374-380] but not with the Km values alone. The correlation noted between inhibitor Ki and substrate Km/kcat is the most extensive one of this type, providing strong evidence that the phosphonamidates are transition-state analogues and not simply multisubstrate ground-state analogues. Cbz-NH2CH2PO2--L-Leu-L-Leu (Ki = 9.1 nM) is the most potent inhibitor yet reported for thermolysin.     

Binding energetics of phosphorus-containing inhibitors of thermolysin

The importance of a specific hydrogen bond between thermolysin and a phosphonamidate inhibitor, Z-NHCH2-PO(O-)-Leu-Leu (1) [Bartlett, P. A., & Marlowe, C. K. (1987) Science (Washington D.C.) 235, 569-571], has been reevaluated. We have determined the inhibition constants (binding free energies) for thermolysin of phosphonamidate n-hexyl-P(O)(O-)-Leu-Trp-NHMe (4), phosphonate n-hexyl-P-(O)(O-)OCH(iBu)CO-Trp-NHMe (5), and phosphinates n-hexyl-P(O)(O-)CH2CH(iBu)CO-Trp-NHMe (6) and Z-NHCH2PO(O-)CH2CH(iBu)CO-Leu (3). Replacement of the P-NH group by P-CH2 (1----3 and 4----6) weakens the overall binding free energy by about 1.5 kcal/mol. A negligible difference in solvation energy has been measured for these pairs, and the basicity of the P-O- ligand for zinc in each pair remains nearly unchanged as determined by pH titration of their 31P NMR resonances. Therefore, this value of 1.5 kcal/mol can be assigned to the specific hydrogen bond known to exist between the P-NH of 1 and thermolysin [Tronrud, D. E., Holden, H. M., & Matthews, B. W. (1987) Science (Washington, D.C.) 235, 871-574] and inferred to exist between 4 and the enzyme. Substitution of P-O for P-NH (1----2 [Bartlett, P. A., & Marlowe, C. K. (1987) Science (Washington, D.C.) 235, 569-571] and 4----5) weakens the overall binding free energy by 4.1 kcal/mol for each pair as the basicity of the P-O- ligand decreases by about 1.6 pH units. The measured solvation energy difference between 4 and 5 (and by inference between 1 and 2) is negligible.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural insights for designed alanine-rich helices: comparing NMR helicity measures and conformational ensembles from molecular dynamics simulation

The temperature dependence of helical propensities for the peptides Ac-ZGG-(KAAAA)(3)X-NH(2) (Z = Y or G, X = A, K, and D-Arg) were studied both experimentally and by MD simulations. Good agreement is observed in both the absolute helical propensities as well as relative helical content along the sequence; the global minimum on the calculated free energy landscape corresponds to a single alpha-helical conformation running from K4 to A18 with some terminal fraying, particularly at the C-terminus. Energy component analysis shows that the single helix state has favorable intramolecular electrostatic energy due to hydrogen bonds, and that less-favorable two-helix globular states have favorable solvation energy. The central lysine residues do not appear to increase helicity; however, both experimental and simulation studies show increasing helicity in the series X = Ala --> Lys --> D-Arg. This C-capping preference was also experimentally confirmed in Ac-(KAAAA)(3)X-GY-NH(2) and (KAAAA)(3)X-GY-NH(2) sequences. The roles of the C-capping groups, and of lysines throughout the sequence, in the MD-derived ensembles are analyzed in detail.     

Calculation of HyHel10-lysozyme binding free energy changes: Effect of ten point mutations

The change in free energy of binding of hen egg white lysozyme (HEL) to the antibody HyHel-10 arising from ten point mutations in HEL (D101K, D101G, K96M, K97D, K97G, K97G, R21E, R21K, W62Y, and W63Y) was calculated using a combination of the finite difference Poisson-Boltzmann method for the electrostatic contribution, a solvent accessible surface area term for the non-polar contribution, and rotamer counting for the sidechain entropy contribution. Comparison of experimental and calculated results indicate that because of pKa shifts in some of the mutated residues, primarily those involving Aspartate or Glutamate, proton uptake or release occurs in binding. When this effect was incorporated into the binding free energy calculations, the agreement with experiment improved significantly, and resulted in a mean error of about 1.9 kcal/mole. Thus these calculations predict that there should be a significant pH dependence to the change in binding caused by these mutations. The other major contributions to binding energy changes comes from solvation and charge charge interactions, which tend to oppose each other. Smaller contributions come from nonpolar interactions and sidechain entropy changes. The structures of the HyHel-10-HEL complexes with mutant HEL were obtained by modeling, and the effect of the modeled structure on the calculations was also examined. “Knowledge based” modeling and automatic generation of models using molecular mechanics produced comparable results. Proteins 33:39–48, 1998. © 1998 Wiley-Liss, Inc.     

Comparison of end-point continuum-solvation methods for the calculation of protein-ligand binding free energies

We have compared the predictions of ligand‐binding affinities from several methods based on end‐point molecular dynamics simulations and continuum solvation, that is, methods related to MM/PBSA (molecular mechanics combined with Poisson–Boltzmann and surface area solvation). Two continuum‐solvation models were considered, viz., the Poisson–Boltzmann (PB) and generalised Born (GB) approaches. The nonelectrostatic energies were also obtained in two different ways, viz., either from the sum of the bonded, van der Waals, nonpolar solvation energies, and entropy terms (as in MM/PBSA), or from the scaled protein–ligand van der Waals interaction energy (as in the linear interaction energy approach, LIE). Three different approaches to calculate electrostatic energies were tested, viz., the sum of electrostatic interaction energies and polar solvation energies, obtained either from a single simulation of the complex or from three independent simulations of the complex, the free protein, and the free ligand, or the linear‐response approximation (LRA). Moreover, we investigated the effect of scaling the electrostatic interactions by an effective internal dielectric constant of the protein (?_int). All these methods were tested on the binding of seven biotin analogues to avidin and nine 3‐amidinobenzyl‐1H‐indole‐2‐carboxamide inhibitors to factor Xa. For avidin, the best results were obtained with a combination of the LIE nonelectrostatic energies with the MM+GB electrostatic energies from a single simulation, using ?_int = 4. For fXa, standard MM/GBSA, based on one simulation and using ?_int = 4–10 gave the best result. The optimum internal dielectric constant seems to be slightly higher with PB than with GB solvation. © Proteins 2012; © 2012 Wiley Periodicals, Inc.     

Monomeric sarcosine oxidase: 1. Flavin reactivity and active site binding determinants

Monomeric sarcosine oxidase (MSOX) is an inducible bacterial flavoenzyme that catalyzes the oxidative demethylation of sarcosine (N-methylglycine) and contains covalently bound FAD [8alpha-(S-cysteinyl)FAD]. This paper describes the spectroscopic and thermodynamic properties of MSOX as well as the X-ray crystallographic characterization of three new enzyme.inhibitor complexes. MSOX stabilizes the anionic form of the oxidized flavin (pK(a) = 8.3 versus 10.4 with free FAD), forms a thermodynamically stable flavin radical, and stabilizes the anionic form of the radical (pK(a) < 6 versus pK(a) = 8.3 with free FAD). MSOX forms a covalent flavin.sulfite complex, but there appears to be a significant kinetic barrier against complex formation. Active site binding determinants were probed in thermodynamic studies with various substrate analogues whose binding was found to perturb the flavin absorption spectrum and inhibit MSOX activity. The carboxyl group of sarcosine is essential for binding since none is observed with simple amines. The amino group of sarcosine is not essential, but binding affinity depends on the nature of the substitution (CH(3)XCH(2)CO(2)(-), X = CH(2) < O < S < Se < Te), an effect which has been attributed to differences in the strength of donor-pi interactions. MSOX probably binds the zwitterionic form of sarcosine, as judged by the spectrally similar complexes formed with dimethylthioacetate [(CH(3))(2)S(+)CH(2)CO(2)(-)] and dimethylglycine (K(d) = 20.5 and 17.4 mM, respectively) and by the crystal structure of the latter. The methyl group of sarcosine is not essential but does contribute to binding affinity. The methyl group contribution varied from -3.79 to -0.65 kcal/mol with CH(3)XCH(2)CO(2)(-) depending on the nature of the heteroatom (NH(2)(+) > O > S) and appeared to be inversely correlated with heteroatom electron density. Charge-transfer complexes are formed with MSOX and CH(3)XCH(2)CO(2)(-) when X = S, Se, or Te. An excellent linear correlation is observed between the energy of the charge transfer bands and the one-electron reduction potentials of the ligands. The presence of a sulfur, selenium, or telurium atom identically positioned with respect to the flavin ring is confirmed by X-ray crystallography, although the increased atomic radius of S < Se < Te appears to simultaneously favor an alternate binding position for the heavier atoms. Although L-proline is a poor substrate, aromatic heterocyclic carboxylates containing a five-membered ring and various heteroatoms (X = NH, O, S) are good ligands (K(d, X=NH) = 1.37 mM) and form charge-transfer complexes with MSOX. The energy of the charge-transfer bands (S > O > NH) is linearly correlated with the one-electron ionization potentials of the corresponding heterocyclic rings.     

Thiorphan and retro-thiorphan display equivalent interactions when bound to crystalline thermolysin

The three-dimensional structures of (S)-thiorphan and (R)-retro-thiorphan bound to thermolysin have been determined crystallographically and refined to residuals of 0.183 and 0.187 at 1.7-A resolution. Thiorphan [N-[(S)-2-(mercaptomethyl)-1-oxo-3-phenylpropyl]glycine] [HSCH2CH(CH2C6H5)CONHC-H2COOH] and retro-thiorphan [[[(R)-1-(mercaptomethyl)-2-phenylethyl] amino]-3-oxopropanoic acid] [HSCH2CH(CH2C6H5)NHCOCH2COOH] are isomeric thiol-containing inhibitors of endopeptidase EC 24-11 (also called "enkephalinase"). The mode of binding of thiorphan to thermolysin is similar to that of (2-benzyl-3-mercaptopropanoyl)-L-alanylglycinamide [Monzingo, A.F., & Matthews, B.W. (1982) Biochemistry 21, 3390-3394] with the inhibitor sulfur atom coordinated to the active site zinc and the peptide portion forming substrate-like interactions with the enzyme. The isomeric inhibitor retro-thiorphan, which differs from thiorphan by the inversion of an amide bond, utilizes very similar interactions with enzyme. Despite the inversion of the -CO-NH- linkage the carbonyl oxygen and amide nitrogen display very similar hydrogen bonding, as anticipated by B.P. Roques et al. [(1983) Proc. Natl. Acad. Sci. U.S.A. 80, 3178-3182]. These results explain why thermolysin and possibly other zinc endopeptidases such as endopeptidase EC 24-11 fail to discriminate between these retro-inverso inhibitors.     

Deciphering the role of the electrostatic interactions involving Gly70 in eglin C by total chemical protein synthesis

Eglin c from the leech Hirudo medicinalis is a potent protein inhibitor of many serine proteinases including chymotrypsin and subtilisins. Unlike most small protein inhibitors whose solvent-exposed enzyme-binding loop is stabilized primarily by disulfide bridges flanking the reactive-site peptide bond, eglin c possesses an enzyme-binding loop supported predominantly by extensive electrostatic/H-bonding interactions involving three Arg residues (Arg48, Arg51, and Arg53) projecting from the scaffold of the inhibitor. As an adjacent residue, the C-terminal Gly70 participates in these interactions via its alpha-carboxyl group interacting with the side chain of Arg51 and the main chain of Arg48. In addition, the amide NH group of Gly70 donates an H-bond to the carbonyl C=O groups of Arg48 and Arg51. To understand the structural and functional relevance of the electrostatic/H-bonding network, we chemically synthesized wild-type eglin c and three analogues in which Gly70 was either deleted or replaced by glycine amide (NH(2)CH(2)CONH(2)) or by alpha-hydroxylacetamide (HOCH(2)CONH(2)). NMR analysis indicated that the core structure of eglin c was maintained in the analogues, but that the binding loop was significantly perturbed. It was found that deletion or replacement of Gly70 destabilized eglin c by an average of 2.7 kcal/mol or 20 degrees C in melting temperature. As a result, these inhibitors become substrates for their target enzymes. Binding assays on these analogues with a catalytically incompetent subtilisin BPN' mutant indicated that loss or weakening of the interactions involving the carboxylate of Gly70 caused a decrease in binding by approximately 2 orders of magnitude. Notably, for all four synthetic inhibitors, the relative free energy changes (DeltaDeltaG) associated with protein destabilization are strongly correlated (slope = 0.94, r(2) = 0. 9996) with the DeltaDeltaG values derived from a decreased binding to the enzyme.     

Evidence for hemiketals as intermediates in the inactivation of serine proteinases with halomethyl ketones

The mechanism of inactivation of serine proteinases by peptide halomethyl ketone inhibitors was studied through the inhibition of trypsin with a series of model peptide ketones (Lys-Ala-LysCH2X). In this series, X is a poor leaving group with increasing electron-withdrawing capacity (X = H, CH2CO2CH3, COCH3, OCOCH3, and F), and as expected, the peptide ketones are reversible, competitive inhibitors of trypsin. The strength of binding of these inhibitors to trypsin increases with the electron-withdrawing ability of X, indicating that the inhibition constant Ki obtained is a measure of reversible hemiketal formation between the inhibitor ketone carbonyl group and the hydroxyl group of the active site serine. A Hammett plot of -log Ki vs. sigma I, the inductive substituent constant of X, reveals a linear relationship between the free energy of binding and the electron-withdrawing power of X. The reversible binding constant obtained for the corresponding chloromethyl ketone Lys-Ala-LysCH2Cl falls on this line, indicating that the reversible binding involves hemiketal formation, which is followed by alkylation of the enzyme.     

Electrostatic interaction-mediated conformational changes of adipocyte fatty acid binding protein probed by molecular dynamics simulation

Abstract

Adipocyte fatty acid binding protein (A-FABP) is a potential drug target for treatment of diabetes, obesity and atherosclerosis. Molecular dynamics (MD) simulations, principal component (PC) analysis and binding free energy calculations were combined to probe effect of electrostatic interactions of residues R78, R106 and R126 with inhibitors ZGB, ZGC and IBP on structural stability of three inhibitor/A-FABP complexes. The results indicate that mutation R126A produces significant influence on polar interactions of three inhibitors with A-FABP and these interactions are main force for driving the conformational change of A-FABP. Analyses on hydrogen bond interactions show that the decrease in hydrogen bonding interactions of residues R126 and Y128 with three inhibitors and the increase in that of K58 with inhibitors ZGC and IBP in the R126A mutated systems mostly regulate the conformational changes of A-FABP. This work shows that R126A can generate a significant perturbation on structural stability of A-FABP, which implies that R126 is of significance in inhibitor bindings. We expect that this study can provide a theoretical guidance for design of potent inhibitors targeting A-FABP.

Communicated by Ramaswamy H. Sarma     

Novel phosphorus-containing glycosphingolipids from the blowfly Calliphora vicina Meigen. Structural analysis by 1H and 1H[31P]-edited NMR spectroscopy at 600 and 500 megahertz

Two novel phosphorus-containing neutral glycosphingolipids of the arthro series were isolated from the blowfly Calliphora vicina Meigen: GalNAc alpha 1----4GalNAc beta 1----(X---- 6)4GlcNAc beta 1----3Man beta 1----4Glc beta 1----1-ceramide and GalNAc beta 1----(X----6)4GlcNAc beta 1----3Man beta 1----4Glc beta 1----1- ceramide (X = -O-P(O)(O-)-OC-H2CH2NH3+). The primary structure of the ceramide pentasaccharide was elucidated de novo using two-dimensional 1H NMR correlation spectroscopy at 500 MHz and multistep relayed coherence transfer spectroscopy at 600 MHz. Localization of the 2'-aminoethyl phosphate substituent was established with the aid of 1H-detected, 31P-edited NMR spectroscopy at 500/202 MHz.     

Two-step binding mechanism for HIV protease inhibitors.

Rate constants for binding of five inhibitors of human immunodeficiency virus (HIV) protease were determined by stopped-flow spectrofluorometry. The two isomers of quinoline-2-carbonyl-Asn-Phe psi-[CH(OH)CH2N]Pro-O-t-Bu (R diastereomer = 1R; S diastereomer = 1S) quenched the protein fluorescence of HIV protease and thus provided a spectrofluorometric method to determine their binding rate constants. The dissociation rate constants for acetyl-Thr-Ile-Leu psi(CH2NH)Leu-Gln-Arg-NH2 (2), (carbobenzyloxy)-Phe psi[CH(OH)CH2N]Pro-O-t-Bu (3), and pepstatin were determined by trapping free enzyme with 1R as 2, 3, and pepstatin dissociated from the respective enzyme.inhibitor complex. Association rate constants of 1R, 2, and pepstatin were calculated from the time-dependent inhibition of protease-catalyzed hydrolysis of the fluorescent substrate (2-aminobenzoyl)-Thr-Ile-Nle-Phe(NO2)-Gln-Arg-NH2 (4). The kinetic data for binding of 1S to the protease fit a two-step mechanism. Kd values for these inhibitors were calculated from the rate constants for binding and were similar to the respective steady-state Ki values.     

The environment of amide groups in protein–ligand complexes: H-bonds and beyond

A comprehensive structural analysis of interactions involving amide NH and C=O groups in protein-ligand complexes has been performed based on 3,275 published crystal structures (resolution < or =2.5 A). Most of the amide C=O and NH groups at the protein-ligand interface are highly buried within the binding site and involved in H-bonds with corresponding counter-groups. Small percentages of C=O and NH groups are solvated or embedded in hydrophobic environments. In particular, C=O groups show a higher propensity to be solvated or embedded in a hydrophobic environment than NH groups do. A small percentage of carbonyl groups is involved in weak hydrogen bonds with CH. Cases of dipolar interactions, involving carbonyl oxygen and electrophilic carbon atoms, such as amide, amidinium, guanidium groups, are also identified. A higher percentage of NH are in contact with aromatic carbons, interacting either through hydrogen bonds (preferably with the NH group pointing towards a ring carbon atom) or through stacking between amide plane and ring plane. Comprehensive studies such as the present one are thought to be important for future improvements in the molecular design area, in particular for the development of new scoring functions. [Figure: see text].     

Interaction of new sulfaphenazole derivatives with human liver cytochrome p450 2Cs: structural determinants required for selective recognition by CYP 2C9 and for inhibition of human CYP 2Cs

A series of new derivatives of sulfaphenazole (SPA), in which the NH(2) and phenyl substituents of SPA are replaced by various groups or in which the sulfonamide function of SPA is N-alkylated, were synthesized in order to further explore CYP 2C9 active site and to determine the structural factors explaining the selectivity of SPA for CYP 2C9 within the human P450 2C subfamily. Compounds in which the NH(2) group of SPA was replaced with R(1) = CH(3), Br, CH = CH(2), CH(2)CH = CH(2), and CH(2)CH(2)OH exhibited a high affinity for CYP 2C9, as shown by the dissociation constant of their CYP 2C9 complexes, K(s), which was determined by difference visible spectroscopy (K(s) between 0.1 and 0.4 microM) and their constant of CYP 2C9 inhibition (K(i) between 0.3 and 0.6 microM). This indicates that the CYP 2C9-iron(III)-NH(2)R bond previously described to exist in the CYP 2C9-SPA complex does not play a key role in the high affinity of SPA for CYP 2C9. Compounds in which the phenyl group of SPA was replaced with various aryl or alkyl R(2) substituents only exhibited a high affinity for CYP 2C9 if R(2) is a freely rotating and sufficiently electron-rich aryl substituent. Finally, compounds resulting from a N-alkylation of the SPA sulfonamide function (R(3) = CH(3), C(2)H(5), or C(3)H(7)) did not retain the selective inhibitory properties of SPA toward CYP 2C9. However, they are reasonably good inhibitors of CYP 2C8 and CYP 2C18 (IC(50) approximately 20 microM). These data allow one to better understand the structural factors that are important for selective binding in the CYP 2C9 active site. They also provide us with clues towards new selective inhibitors of CYP 2C8 and CYP 2C18.     

Effect of hydrophobic structure on the catalysis of nitric oxide release from zwitterionic diazeniumdiolates in surfactant and liposome media.

The effect of phospholipid liposomes and surfactant micelles on the rate of nitric oxide release from zwitterionic diazeniumdiolates, R1R2N[N(O)NO]-, with significant hydrophobic structure, has been explored. The acid-catalyzed dissociation of NO has been examined in phosphate-buffered solutions of sodium dodecylsulfate (SDS) micelles and 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1,2-dipalmitoyl-sn-glycero-3-[phospho-(1-glycerol)] sodium salt (DPPG) phospholipid liposomes. The reaction behavior of dibenzylamine-, monobenzylamine-, and dibutylamine-derived substrates [1]: R1 = C6H5CH2, R2 = C6H5CH2 NH2+(CH2)2, 2: R1 = C6H5CH2, R2 = NH3+(CH2)2, and 3: R1 = n-butyl, R2 = n-butyl-NH2+(CH2)6] has been compared with that of SPER/NO, 4: R1 = H2N(CH2)3, R2 = H2N(CH2) 3NH2+(CH2)4]. Catalysis of NO release is observed in both micellar and liposome media. Hydrophobic interactions contribute to micellar binding for 1-3 and appear to be the main factor facilitating catalysis by charge neutral DPPC liposomes. Binding constants for the association of 1 and 3 with SDS micelles were 3-fold larger than those previously obtained with comparable zwitterionic substrates lacking their hydrophobic structure. Anionic DPPG liposomes were much more effective in catalyzing NO release than either DPPC liposomes or SDS micelles. DPPG liposomes (at 10 mM total lipid) induced a 30-fold increase in the NO dissociation rate of SPER/NO compared to 12- and 14-fold increases in that of 1 and 3.     

Requirements for mammalian carboxylesterase inhibition by substituted ethane-1,2-diones

Carboxylesterases (CE) are ubiquitous enzymes found in both human and animal tissues and are responsible for the metabolism of xenobiotics. This includes numerous natural products, as well as a many clinically used drugs. Hence, the activity of these agents is likely dependent upon the levels and location of CE expression. We have recently identified benzil is a potent inhibitor of mammalian CEs, and in this study, we have assessed the ability of analogues of this compound to inhibit these enzymes. Three different classes of molecules were assayed: one containing different atoms vicinal to the carbonyl carbon atom and the benzene ring [PhXC(O)C(O)XPh, where X=CH?, CHBr, N, S, or O]; a second containing a panel of alkyl 1,2-diones demonstrating increasing alkyl chain length; and a third consisting of a series of 1-phenyl-2-alkyl-1,2-diones. In general, with the former series of molecules, heteroatoms resulted in either loss of inhibitory potency (when X=N), or conversion of the compounds into substrates for the enzymes (when X=S or O). However, the inclusion of a brominated methylene atom resulted in potent CE inhibition. Subsequent analysis with the alkyl diones [RC(O)C(O)R, where R ranged from CH? to C?H??] and 1-phenyl-2-alkyl-1,2-diones [PhC(O)C(O)R where R ranged from CH? to C?H??], demonstrated that the potency of enzyme inhibition directly correlated with the hydrophobicity (clogP) of the molecules. We conclude from these studies that that the inhibitory power of these 1,2-dione derivatives depends primarily upon the hydrophobicity of the R group, but also on the electrophilicity of the carbonyl group.     

A gastrin-releasing peptide antagonist containing A psi (CH2O) amide bond surrogate

The [Leu26-psi(CH2O)Leu27] derivative of N-Ac-GRP20-27-peptide amide was prepared and evaluated as a gastrin-releasing peptide antagonist. This psi(CH2O) derivative was found to be a more potent inhibitor of [3H-Phe15]GRP15-24NH2 binding and N-Ac-GRP20-27NH2 induced mitogenesis in Swiss 3T3 fibroblasts than the related nitrogen analog [Leu13-psi(CH2NH)Leu14] bombesin. Possible reasons for the improved activity of the (CH2O) insert relative to the (CH2NH) group include increased hydrophobicity and a reduced tendency of the oxygen derivative to form hydrogen bonds.