Inhibition of aminopeptidases by amastatin and bestatin derivatives. Effect of inhibitor structure on slow-binding processes

Amastatin [(2S,3R)-3-amino-2-hydroxy-5-methylhexanoyl-L-valyl-L-valyl-L- aspartic acid] and bestatin [(2S,3R)-3-amino-2-hydroxy-4-phenylbutanoyl-L-leucine] are slow-binding, competitive inhibitors of aminopeptidase M (AP-M) with net inhibition constants (Ki) of 1.9 X 10(-8) and 4.1 X 10(-6) M, respectively. The effect of inhibitor structure on net Ki and on slow-binding inhibition was evaluated for analogues of both inhibitors on AP-M and leucine aminopeptidase (LAP). The (2S)-hydroxyl group contributes to the stabilization of a collision complex [EI], which is formed rapidly. In contrast, increasing the peptide chain length of the inhibitor produces more potent inhibitors as a consequence of a slower binding process. A statine analogue of amastatin [(3S,4S)-Sta-Val-Val-Asp] stimulated rather than inhibited LAP. AP-M binds tri- and tetrapeptide inhibitors more strongly than dipeptide inhibitors, whereas LAP binds dipeptide inhibitors more strongly. The difference in binding can be used to distinguish cytosolic from membrane-bound aminopeptidases.     

alpha-Keto amide inhibitors of aminopeptidases.

The design and synthesis of 3-amino-2-oxo-4-phenylbutanoic acid amides (alpha-keto amides), a new class of aminopeptidase inhibitor, are described. These compounds, illustrated by the Phe-Leu analogue 2, are effective inhibitors of arginyl aminopeptidase (Ki = 1.5 microM), cytosol aminopeptidase (Ki = 1.0 microM), and microsomal aminopeptidase (Ki = 2.5 microM). The ketone carbonyl of the alpha-keto amide was found to hydrate readily in an aqueous DMSO solution, due to the electron-withdrawing effect of the neighboring amide group. A mechanism of inhibition is proposed for the alpha-keto amides that is similar to that proposed for the structurally related aminopeptidase inhibitor bestatin and its analogues, wherein the inhibitor may interact with the S1'-S2' subsite of the enzyme rather than the S1-S1' subsite. Like bestatin, the alpha-keto amides are slow-binding inhibitors of all three enzymes.     

Phosphorus amino acid analogues as inhibitors of leucine aminopeptidase

A variety of phosphorus amino acid and dipeptide analogues have been synthesized and evaluated as inhibitors of the metalloenzyme leucine aminopeptidase from porcine kidney. Two phosphonate dipeptides were found to be modest inhibitors of the enzyme (8e, Ki = 58 microM; 8h, Ki = 340 microM). The phosphinic acid (17-OH) and phosphinamide (17-NH2) analogues related to bestatin were prepared by condensation of the phosphinate amino acid derivative 11, via a trivalent phosphonite ester 12, with leucine isocyanate derivatives 13. These compounds also proved to be unexceptional in their inhibition of LAP (17-O-, Ki = 56 microM; 17-NH2, Ki = 40 microM). A series of simple (alpha-aminoalkyl)phosphonic acid and -phosphinic acids were also evaluated, and the most potent inhibitors were found to be the phosphonic acid analogues of L-Leu and L-Phe [R)-3e, Ki = 0.23 microM; (R)-3h, Ki = 0.42 microM). Slow-binding behavior was observed for (R)-3e (kon = 400 +/- 55 M-1 s-1) and (R)-3h (kon = 445 +/- 50 M-1 s-1). The phosphinic acid analogues of Leu and Phe are 100-fold less potent than the phosphonate derivatives. The fact that tetrahedral phosphorus analogues are less potent inhibitors of LAP than they are of other zinc peptidases suggests that the mechanism of LAP may be fundamentally different than that of the latter enzymes.     

Analgesic dipeptide derivatives. 7. 3,7-Diamino-2-hydroxyheptanoic acid (DAHHA) containing dipeptide analogues of the analgesic compound H-Lys-Trp(Nps)-OMe.

A series of diastereomeric dipeptides, analogues of the analgesic compound H-Lys-Trp(Nps)-OMe (2), containing 3,7-diamino-2-hydroxyheptanoic acid (DAHHA) and 2-[(o-nitrophenyl)sulfenyl]tryptophan [Trp(Nps)] has been synthesized. These compounds were tested as enkephalin-degrading aminopeptidases (APs), AP-M and AP-B inhibitors, and analgesics. The inhibitory potencies and the antinociceptive effects depended on the stereochemistry of the compounds. (2S,3R)-DAHHA-L-Trp(Nps)-OMe (26d) was a highly potent and selective enkephalin-degrading APs inhibitor, with an IC50 value in the 10(-8) M range. Although this derivative was about 10(3)-fold more potent than 2 against these enzymes, their antinociceptive effects were completely similar. These results indicate that the inhibitory capacity of this series of Trp(Nps)-containing dipeptides against enkephalin-degrading enzymes is not an important factor for their antinociceptive effects.     

Inhibition of aminopeptidases N, A and W. A re-evaluation of the actions of bestatin and inhibitors of angiotensin converting enzyme.

The effects of a range of metallopeptidase inhibitors on the activities of the porcine kidney cell surface zinc aminopeptidases, aminopeptidase A (AP-A; EC 3.4.11.2), aminopeptidase N (AP-N; EC 3.4.11.7) and aminopeptidase W (AP-W; EC 3.4.11.16), have been directly compared. Amastatin and probestin were effective against all three aminopeptidases, with the concentration of inhibitor required to cause 50% inhibition (I50) in the low micromolar range (I50 = 1.5-20 microM), except for probestin with AP-N which displayed an I50 of 50 nM. Actinonin failed to inhibit significantly either AP-A or AP-W, and thus can be considered a relatively selective inhibitor (I50 = 2.0 microM) of AP-N. In contrast, bestatin was a relatively poor inhibitor of AP-N (I50 = 89 microM) and failed to inhibit AP-A, but was more potent towards AP-W (I50 = 7.9 microM). Thus, some of the observed chemotherapeutic actions of bestatin may be due to inhibition of cell-surface AP-W. A number of other metallopeptidase inhibitors, including inhibitors of endopeptidase-24.11 (EC 3.4.24.11) and membrane dipeptidase (EC 3.4.13.11), and the carboxylalkyl and phosphoryl inhibitors of angiotensin converting enzyme (EC 3.4.15.1) failed to inhibit significantly AP-A, AP-N or AP-W. However, AP-W was inhibited with I50 values in the micromolar range by the sulphydryl converting enzyme inhibitors rentiapril (I50 = 1.6 microM), zofenoprilat (I50 = 7.0 microM) and YS 980 (I50 = 17.7 microM). Neither AP-A nor AP-N were affected by these sulphydryl compounds. Inhibition of AP-W may account for some of the side effects noted with the clinical use of the sulphydryl converting enzyme inhibitors. The availability of compounds which are totally selective for AP-W over any of the other mammalian cell surface zinc aminopeptidases may aid in identifying endogenous substrates, and thus physiological or pathophysiological role(s) of AP-W.     

Leuhistin, a new inhibitor of aminopeptidase M, produced by Bacillus laterosporus BMI156-14F1. I. Taxonomy, production, isolation, physico-chemical properties and biological activities.

Leuhistin has been isolated from the culture broth of Bacillus laterosporus BMI156-14F1 as part of a program designed to find microorganism-produced inhibitors of aminopeptidase M (AP-M). It was purified by use of column chromatography on Sepabeads SP206, Amberlite IRC-50, MCI gel CHP-20P and Sephadex G-10 and then isolated as colorless needles. Leuhistin inhibits AP-M strongly and it also inhibits AP-A and AP-B weakly. It is competitive with the substrate, and the inhibition constant (Ki) was 2.3 x 10(-7) M.     

Aminopeptidase inhibitory properties and analgesic activity of (2S,3R)-3,7-diamino-2-hydroxy-heptanoic acid containing tripeptide analogues of the N-terminal tripeptide of probestin.

(2S,3R)-3,7-Diamino-2-hydroxy-heptanoyl-Leu-Pro-OH [(2S,3R)-DAHHA-Leu-Pro-OH, 4], analogue of the N-terminal tripeptide of probestin, has been synthesized, and tested as inhibitor of AP-B, Leu-AP, AP-M, and enkephalin-degrading APs, and as analgesic. In order to establish structure-activity relationships the dipeptide (2S,3R)-DAHHA-Pro-OH (5) and the tripeptide (2S,3R)-DAHHA-Ala-Pro-OH (6) were also prepared. Compounds 4 and 6 were potent and selective inhibitors of enkephalin-degrading APs and showed a prolonged antinociceptive effect.     

Synthesis and evaluation of 3-substituted analogues of 1,2,3,4-tetrahydroisoquinoline as inhibitors of phenylethanolamine N-methyltransferase

1,2,3,4-Tetrahydroisoquinoline (THIQ) and aryl-substituted derivatives of THIQ are potent inhibitors of the enzyme that catalyzes the formation of epinephrine--phenylethanolamine N-methyltransferase (PNMT, E.C. 2.1.1.28). In previous studies, we found that substitution of the 3-position of THIQ with a methyl group resulted in enhanced activity as an inhibitor for 3-methyl-THIQ with respect to THIQ itself. To more fully delineate this region of the PNMT active site, we have synthesized and evaluated other 3-substituted THIQ analogues that vary in both steric and electronic character. Extension of the methyl side chain in 8 by a single methylene unit results in diminished potency for 3-ethyl-THIQ, suggesting that this zone of the active site is spatially compact; furthermore, the region of steric intolerance may be located principally on only "one side" of the 3-position of bound THIQs, since the carbonyl containing (bent) analogues 3-(methoxycarbonyl)-THIQ and 3-(aminocarbonyl)-THIQ are much less capable of forming a strong enzyme-inhibitor dissociable complex compared to straight-chain derivatives possessing a similar steric component. The good activity of 3-(hydroxymethyl)-THIQ as a PNMT inhibitor cannot be explained solely by steric tolerance for this side chain. We believe that an active-site amino acid residue capable of specific (i.e., hydrogen bond) interactions is located in close proximity to the 3-position of bound THIQs and that association of the OH functionality with this active-site residue results in the enhanced in vitro potency of this analogue (Ki = 2.4 microM) compared to that of THIQ (Ki = 10.3 microM). Incorporation of a hydroxymethyl substituent onto the 3-position of the potent PNMT inhibitor 7,8-dichloro-THIQ (SKF 64139, Ki = 0.24 microM) did not result in the same enhancement in inhibitor potency for 17 (Ki = 0.38 microM). This result suggests that simultaneous binding in an optimal orientation of the aromatic halogens, secondary amine, and side-chain hydroxyl functionalities to the PNMT active site is not allowed in this analogue.     

Conformational and steric aspects of phenylethanolamine and phenylethylamine analogues as substrates or inhibitors of phenylethanolamine N-methyltransferase

The conformational and steric aspects of binding to phenylethanolamine N-methyltransferase (PNMT; EC 2.1.1.28) for phenylethanolamine substrates and phenylethylamine inhibitors were probed with three conformationally defined analogues (11, 12, and 13) of phenylethylamine (1) and phenylethanolamine (6) containing the benzobicyclo[3.2.1]octane skeleton. The 2-aminotetralin (2AT) moiety in conformationally defined analogues 11, 12, and 13 exists in a half-chair conformation with an equatorial amino group. Although conformationally restricted phenylethylamine analogue 2AT (3, Ki = 6.8 microM) and conformationally restricted phenylethanolamine analogues (cis)- and (trans)-2-amino-1-tetralol (9, Km = 22 microM; Vmax = 0.15; 100 X Vmax/Km = 0.68; 10, Ki = 9.4 microM) are good ligands for PNMT, none of the analogues 11, 12, and 13 showed activity as a substrate of PNMT. The fact that 11 (Ki = 206 microM) is more potent than analogues 4 (Ki = 1296 microM) and 5 (Ki = 479 microM), with a half-boat 2AT moiety, suggests that PNMT preferentially binds the half-chair conformation of 2AT at the active site. This is consistent with previous findings that a fully extended conformation for the aminoethyl side chain of phenylethylamine inhibitors is optimal for PNMT binding. The reduced activity of 11, 12 (Ki = 1246 microM), and 13 (Ki = 3000 microM), compared with 2AT and (cis)- and (trans)-2-amino-1-tetralol (9 and 10) is consistent with a negative steric interference from the extra ethano bridge in 11, 12, and 13. The results from 11, 12, and 13, combined with previous findings, suggest that PNMT interacts better with relatively planar ligands.     

Probing binding requirements of type I and type II isoforms of inosine monophosphate dehydrogenase with adenine-modified nicotinamide adenine dinucleotide analogues

Novel tiazofurin adenine dinucleotide (TAD) analogues 25-33 containing a substituent at C2 of the adenine ring have been synthesized as inhibitors of the two isoforms of human IMP-dehydrogenase. The 2-ethyl TAD analogue 33 [Ki = 1 nM (type I), Ki = 14 nM (type II)] was found to be the most potent. It did not inhibit three other cellular dehydrogenases up to 50 microM. Mycophenolic adenine bis(phosphonate)s containing a 2-phenyl (37) or 2-ethyl group (38), were prepared as metabolically stable compounds, both nanomolar inhibitors. Compound 38 [Ki = 16 nM (type I), Ki = 38 nM (type II)] inhibited proliferation of leukemic K562 cells (IC50 = 1.1 microM) more potently than tiazofurin (IC50 = 12.4 microM) or mycophenolic acid (IC50 = 7.7 microM).     

Conformationally restricted and conformationally defined tyramine analogues as inhibitors of phenylethanolamine N-methyltransferase

In a search for a selective inhibitor for the epinephrine synthesizing enzyme phenylethanolamine N-methyltransferase (PNMT; EC 2.1.1.28), phenolic 2-aminotetralins (12-15 as conformationally restricted analogues of tyramine) and phenolic benzobicyclo[3.2.1]octylamines (22-24 as conformationally defined analogues of tyramine) were used to gain information about the binding interactions of the catecholic hydroxyl groups in the natural substrate norepinephrine at the active site of PNMT. In addition, these analogues provided information about the effects of conformational flexibility on active-site interaction of the aminoethyl side chain in phenolic phenylethylamines that may aid in learning the manner in which norepinephrine binds at the active site of PNMT. Analogues 22-24 were synthesized by a nine-step sequence, in which a Friedel-Crafts type intramolecular cyclization was the key step in the construction of the benzobicyclo[3.2.1]octane skeleton. p-Tyramine (10, Ki = 294 microM) was more potent than phenylethylamine (1, Ki = 854 microM) but m-tyramine (9, Ki = 1250 microM) was less potent than phenylethylamine as an inhibitor of PNMT. Similarly, in the conformationally restricted and conformationally defined tyramine analogues (12-15 and 22-24, respectively), the analogues with the p-tyramine moiety (14, Ki = 4.7 microM; 23, Ki = 111 microM) bind to PNMT better than do the corresponding unsubstituted compounds (16, Ki = 6.8 microM; 25, Ki = 206 microM) while the analogues with the m-tyramine moiety (13, 15, 22, and 24) have a lower binding affinity than do 16 and 25. The greatly enhanced activity of the phenolic 2-aminotetralins (12-15) compared with m- and p-tyramine (9 and 10, respectively) is likely due to the restriction of the side-chain conformation. The conformationally defined analogues 22-24 were less active than the conformationally restricted ones, 12-15, although the low-energy half-chair conformation of 2-aminotetralin is defined in 22-24. The reduced activity of 22-24 compared with the activity of 12-15 is probably due to the steric hindrance from the extra bridging atoms in binding to PNMT. The interaction of the p-hydroxyl group of the tyramine moiety may involve hydrogen bonding since the corresponding methyl ethers show a greatly reduced affinity for the active site of PNMT (Ki = 34 and 389 microM for methoxy analogues 28 and 35, compared to Ki = 4.7 and 111 microM for the corresponding phenolic analogues 14 and 23).     

Methotrexate analogues-27. Dual inhibition of dihydrofolate reductase and folylpolyglutamate synthetase by methotrexate and aminopterin analogues with a gamma-phosphonate group in the side chain

gamma-Phosphonate analogues of methotrexate (MTX) and aminopterin (AMT) were synthesized from 4-amino-4-deoxy-N10-methylpteroic acid and 4-amino-4-deoxy-N10-formylpteroic acid, respectively, by reaction with methyl D,L-2-amino-4-phosphonobutyrate followed by gentle alkaline hydrolysis. The products were compared with the corresponding D,L-homocysteic acid derivatives as inhibitors of dihydrofolate reductase and folylpolyglutamate synthetase, and as inhibitors of cell growth in culture. The gamma-phosphonates were somewhat less active than either the gamma-sulfonates or the parent drugs as inhibitors of murine dihydrofolate reductase. The MTX gamma-sulfonate and gamma-phosphonate analogues were equally inhibitory toward mouse liver folylpolyglutamate synthetase (Ki = 190 microM), but in the AMT series the gamma-phosphonate (Ki = 8.4 microM) was more potent than the gamma-sulfonate (Ki = 45 microM). The AMT analogues were consistently more inhibitory than the MTX analogues against cultured L1210 murine leukemia cells, but neither the gamma-phosphonates nor the gamma-sulfonates were as potent as their respective parent drugs. The gamma-phosphonate analogue of MTX was three times more potent than MTX against the MTX-resistant mutant line L1210/R81, but the AMT gamma-phosphonate was less potent than AMT; however, these differences were small in comparison with the level of resistance to all these compounds in the L1210/R81 line. The results suggest that N10-methyl and N10-unsubstituted compounds altered at the gamma-position do not necessarily follow identical structure-activity patterns in every test system.     

Potential inhibitors of S-adenosylmethionine-dependent methyltransferases. 10. Base- and amino acid modified analogues of S-aristeromycinyl-L-homocysteine

A series of base- and amino acid modified analogues of S-aristeromycinyl-L-homocysteine, a carbocyclic nucleoside, were synthesized and evaluated as inhibitors of S-adenosyl-L-methionine-dependent methyltransferases, including catechol O-methyltransferase, phenylethanolamine N-methyltransferase, and histamine N-methyltransferase. The base-modified analogues (8-azaadenine, 3-deazaadenine, and N6-methyladenine) were prepared by reaction of the corresponding carbocyclic 5'-chloro-5'-deoxynucleosides with the anion of homocysteine generated in situ either from L-homocystine or S-benzyl-L-homocysteine in Na/liquid NH3 or with DL-homocysteine thiolactone in alkaline solution. S-Aristeromycinyl-D-homocysteine was prepared with use of D-homocystine in the Na/liquid NH3 reaction. The sulfoxide and sulfone analogues were prepared by oxidation of S-aristeromycinyl-L-homocysteine. The various base- and amino acid modified analogues of S-aristeromycinyl-L-homocysteine were inactive as inhibitors of catechol O-methyltransferase. In contrast, the 3-deaza analogue was a good inhibitor (Ki = 20.5 +/- 1 microM) of phenylethanolamine N-methyltransferase whereas S-aristeromycinyl-D-homocysteine was an excellent inhibitor (Ki = 10.4 +/- 2.4 microM) of histamine N-methyltransferase. On the basis of these results, it would appear that the structural requirements for the binding S-aristeromycinyl-L-homocysteine are similar to those for binding S-adenosyl-L-homocysteine. Therefore, these carbocyclic analogues have the potential of being better inhibitors in vivo, because they should be more stable to metabolism than the ribosyl analogues.     

The most potent organophosphorus inhibitors of leucine aminopeptidase. Structure-based design,chemistry, and activity

A new class of very potent inhibitors of cytosol leucine aminopeptidase (LAP), a member of the metalloprotease family, is described. The X-ray structure of bovine lens leucine aminopeptidase complexed with the phosphonic acid analogue of leucine (LeuP) was used for structure-based design of novel LAP inhibitors and for the analysis of their interactions with the enzyme binding site. The inhibitors were designed by modification of phosphonic group in the LeuP structure toward finding the substituents bound at the S' side of the enzyme. This resulted in two classes of compounds, the phosphonamidate and phosphinate dipeptide analogues, which were synthesized and evaluated as inhibitors of the enzyme. The in vitro kinetic studies for the phosphinate dipeptide analogues revealed that these compounds belong to the group of the most effective LAP inhibitors found so far. Their further modification at the P1 position resulted in more active inhibitors, hPheP[CH(2)]Phe and hPheP[CH(2)]Tyr (K(i) values 66 nM and 67 nM, respectively, for the mixture of four diastereomers). The binding affinities of these inhibitors toward the enzyme are the highest, if considering all compounds containing a phosphorus atom that mimic the transition state of the reaction catalyzed by LAP. To evaluate selectivity of the designed LAP inhibitors, additional tests toward aminopeptidase N (APN) were performed. The key feature, which determines their selectivity, is structure at the P1' position. Aromatic and aliphatic substituents placed at this position strongly interact with the LAP S1' binding pocket, while a significant increase in binding affinity toward APN was observed for compounds containing aromatic versus leucine side chains at the P1' position. The most selective inhibitor, hPheP[CH(2)]Leu, binds to LAP with 15 times higher affinity than to APN. One of the studied compounds, hPheP[CH(2)]Tyr, appeared to be very potent inhibitor of APN (K(i) = 36 nM for the mixture of four diastereomers). The most promising LAP inhibitors designed by computer-aided approach, the phosphonamidate dipeptide analogues, were unstable at pH below 12, because of the P-N bond decomposition, which excluded the possibility of determination of their binding affinities toward LAP.     

In vitro and in vivo effects of kelatorphan on enkephalin metabolism in rodent brain

Biologically relevant assays were used to compare the potency of kelatorphan (N-[3(R)-[(hydroxyamino)carbonyl]-2-benzyl-1-oxopropyl]-L-alanine) as inhibitor of the peptidase-induced metabolism of enkephalins to that of bestatin, a non-specific inhibitor of aminopeptidase and thiorphan, a highly potent blocker of the neutral endopeptidase (EC 3.4.24.11) designated as enkephalinase. Kelatorphan almost completely inhibited the formation of the three metabolites [3H]Tyr, [3H]Tyr-Gly and [3H]Tyr-Gly-Gly produced by incubation of [3H][Tyr1,Met5]enkephalin with rat striatal slices. Co-administered with [Met5]enkephalin in mouse brain, kelatorphan was able to prevent by 80% the degradation of the exogenous peptide. Moreover, a mixture of thiorphan (1 microM) and bestatin (20 microM) or kelatorphan alone (20 microM) induced a 2.2 to 2.5-fold increase in endogenous [Met5]enkephalin overflow after evoked depolarization of superfused rat striatal slices. In this assay, kelatorphan was the only compound to increase by 63% the basal level of released [Met5]enkephalin. Kelatorphan was about 100 times less potent than bestatin to inhibit the total rat striatal aminopeptidases, but as efficient (IC50 = 4 X 10(-7) M) as bestatin to inhibit a minor aminopeptidase activity resembling aminopeptidase M. Therefore the reported enhanced analgesic potency of kelatorphan with regard to the association of bestatin and thiorphan is very likely related to its ability to almost completely inhibit enkephalin-degrading enzymes (including the Tyr-Gly releasing peptidase) and to its better selectivity for the biologically relevant aminopeptidase M. Kelatorphan would be a valuable probe, preferable to the association of bestatin and thiorphan, to investigate the physiological functions regulated by a phasic enkephalinergic activity.     

Methotrexate analogues. 26. Inhibition of dihydrofolate reductase and folylpolyglutamate synthetase activity and in vitro tumor cell growth by methotrexate and aminopterin analogues containing a basic amino acid side chain

Analogues of the antitumor antifolate methotrexate (MTX) were synthesized in which the glutamate (Glu) moiety was replaced by ornithine (Orn), 2,4-diaminobutyric acid (Dab), or 2,3-diaminopropionic acid (Dap). An aminopterin (AMT) analogue with Orn in place of Glu was also synthesized. The MTX analogues were obtained by reaction of 4-amino-4-deoxy-N10-methylpteroic acid (mAPA) and N omega-Boc-alpha,omega-diaminoalkanoic acids in the presence of diethyl phosphorocyanidate, followed by deprotection with trifluoroacetic acid (TFA) or by reaction of p-nitrophenyl-mAPA and N omega-Boc-alpha,omega-diaminoalkanoic acids and subsequent treatment with TFA. The AMT analogue (APA-Orn) was synthesized by reaction of p-nitrophenyl 4-amino-4-deoxy-N10-formylpteroate with silylated N delta-Boc-L-ornithine in DMF at 55 degrees C for 3 days (45% yield), saponification (83%), and TFA cleavage (89%). APA-Orn was a potent inhibitor of both dihydrofolate reductase (DHFR) from L1210 mouse leukemia (IC50 = 0.072 microM) and partly purified folylpolyglutamate synthetase (FPGS) from mouse liver (Ki = 0.15 +/- 0.06 microM). The MTX analogue (mAPA-Orn) was likewise active against both enzymes, with an IC50 of 0.160 microM for DHFR and a Ki of 20.4 +/- 7.7 microM for FPGS inhibition. The other MTX analogues and the previously reported lysine derivative (mAPA-Lys) showed DHFR affinity similar to that of mAPA-Orn but lacked activity as FPGS inhibitors. The positively charged amino group appears to be detrimental to cellular uptake, as evidenced by the low cytotoxicity of these compounds (IC50 = 0.40-2.4 microM) in comparison with MTX and AMT (IC50 = 0.002 microM) against wild-type L1210 cells. On the other hand, mAPA-Orn and APA-Orn were both more potent than the corresponding Glu derivatives MTX and AMT against L1210/R81 cells, suggesting that in these MTX-resistant cells there may occur a "self-potentiation" process involving enhanced antifolate activity via interference with the polyglutamylation of reduced folates. APA-Orn is the most potent dual inhibitor of DHFR and FPGS discovered to date, but its effectiveness as a therapeutic agent may require some form of prodrug modification to neutralize the terminal amino group of the side chain.     

Analogues of carbamyl aspartate as inhibitors of dihydroorotase: preparation of boronic acid transition-state analogues and a zinc chelator carbamylhomocysteine

Dihydroorotase (DHO) catalyzes the conversion of carbamyl aspartate (CA) to dihydroorotate (DO) in the de novo pyrimidine biosynthetic pathway. Few effective inhibitors of DHO have been reported, and thus blockade of this reaction has not been widely pursued as a strategy for development of antitumor agents. Utilizing two mechanism-based strategies, we have designed and prepared potential DHO inhibitor analogues of CA. One strategy replaced the gamma-carboxyl moiety of CA with a boronic acid. This substitution yields compounds which form stable charged tetrahedral intermediates and mimic the enzyme-substrate transition state. Preparation of the boronic acid analogues of CA and its carboxylic acid esters focused on a Curtius rearrangement as a key step following a malonic ester synthesis. This was followed by carbamoylation of the free amine under nonaqueous neutral conditions with Si(NCO)4. The ethyl ester was a competitive inhibitor of DHO with an apparent Ki of 5.07 microM, while the nonesterified analogue and the methyl ester were not effective inhibitors. None of the compounds were cytotoxic against L1210 cells in culture. An active-site-directed sulfhydryl-containing zinc chelator was also prepared. This analogue irreversibly inhibited the enzyme, but it also was ineffective in L1210 growth inhibition.     

Design of novel inhibitors of aminopeptidases. Synthesis of peptide-derived diamino thiols and sulfur replacement analogues of bestatin

Investigations were directed toward inhibition of an aminopeptidase, isolated from rat brain, which has been implicated in the metabolic inactivation of enkephalins. The design rationale and synthesis of novel peptidyl diamino thiol inhibitors of rat brain aminopeptidase are presented, along with accompanying structure-activity analysis. Some of the reported compounds are highly active aminopeptidase inhibitors and possess enzyme inhibitory potency in the nanomolar range (62; I50 = 1 nM). Analysis of the data permits speculations on possible modes of binding of diamino thiols to aminopeptidase. Other investigations were directed toward understanding the mode of enzyme binding of the naturally occurring aminopeptidase inhibitor bestatin. On the basis of published models of enzyme binding, replacement of the C-2 hydroxyl group of bestatin by a sulfhydryl group was anticipated to lead to enhanced inhibition due to a strengthened interaction of this group with enzymic zinc. Contrary to expectations, "thiobestatin" inhibited rat brain aminopeptidase with only the same degree of effectiveness as the corresponding alcohol. Speculations on the possible mode of enzyme-inhibitor binding of bestatin are offered.     

Analogues of aminoglutethimide: selective inhibition of aromatase

In exploring further the structural features that influence the relative efficacy of analogues of aminoglutethimide [1, 3-(4-aminophenyl)-3-ethylpiperidine-2,6-dione] as inhibitors of the cholesterol side-chain cleavage enzyme system desmolase and the estrogen forming system aromatase, analogues have been synthesized in which the aminophenyl substituent is replaced by pyridyl or substituted pyridyl. The 4-pyridyl analogue 5 [3-ethyl-3-(4-pyridyl)-piperidine-2,6-dione] is a strong competitive inhibitor of aromatase (Ki = 1.1 microM; value for 1, 0.60 microM), which exhibits a type II difference spectrum (Ks = 0.28 microM; value for 1, 0.13 microM) but is noninhibitory toward desmolase. The 2- and 3-pyridyl analogues (3 and 4) inhibit neither enzyme system. 1-Amino-3-ethyl-3-phenylpiperidine-2,6-dione (2) is a strong and selective inhibitor of desmolase but the 4-pyridyl analogue 10 [1-amino-3-ethyl-3-(4-pyridyl)-piperidine-2,6-dione] is a weak inhibitor of desmolase and aromatase. Analogues of 5 having a less basic aromatic substituent, namely, the N-oxide 11 and the 2,3,5,6-tetrafluoro derivative 13, were also prepared. The latter is a weak inhibitor of aromatase and the former inhibits neither enzyme system.     

Immunochemical identification of the cell surface bound leucine aminopeptidase, the target enzyme for the immunostimulant bestatin

The microbial product bestatin is known to inhibit soluble microsomal- and cytosolic leucine aminopeptidase (Leu-APm and Leu-APc) as well as aminopeptidase B (AP-B). To clarify which of these enzymes is the target for bestatin on the cell surface, indirect immunofluorescence studies with antisera raised against purified Leu-APm and AP-B were performed. These antibodies (anti-Leu-APm and anti-AP-B) were found to react with intracellularly localized Leu-APm and AP-B of ethanol-treated L5178y cells. Using non-treated L5178y cells fluorescence was detected only on the cell surface after incubation with anti-Leu-APm. To confirm the supposition that only Leu-APm is present on the cell surface, the AP from the cell membrane was solubilized and analyzed electrophoretically. Based on relative migration data it could be shown, that the cell surface is charged with Leu-APm and not with detectable amounts of Leu-APc or AP-B. Moreover, it could be demonstrated that the solubilized Leu-APm binds to [3H]bestatin.