EPR and X-ray crystallographic characterization of the product-bound form of the MnII-loaded methionyl aminopeptidase from Pyrococcus furiosus

Methionine aminopeptidases (MetAPs) are ubiquitous metallohydrolases that remove the N-terminal methionine from nascent polypeptide chains. Although various crystal structures of MetAP in the presence of inhibitors have been solved, the structural aspects of the product-bound step has received little attention. Both perpendicular- and parallel-mode electron paramagnetic resonance (EPR) spectra were recorded for the Mn(II)-loaded forms of the type-I (Escherichia coli) and type-II (Pyrococcus furiosus) MetAPs in the presence of the reaction product l-methionine (L-Met). In general, similar EPR features were observed for both [MnMn(EcMetAP-I)]-L-Met and [MnMn(PfMetAP-II)]-L-Met. The observed perpendicular-mode EPR spectra consisted of a six-line hyperfine pattern at g = 2.03 (A = 8.8 mT) with less intense signals with eleven-line splitting at g = 2.4 and 1.7 (A = 4.4 mT). The former feature results from mononuclear, magnetically isolated Mn(II) ions and this signal are 3-fold more intense in the [MnMn(PfMetAP-II)]-L-Met EPR spectrum than in the [MnMn(EcMetAP-I)]-L-Met spectrum. Inspection of the EPR spectra of both [MnMn(EcMetAP-I)]-L-Met and [MnMn(PfMetAP-II)]-L-Met at 40 K in the parallel mode reveals that the [Mn(EcMetAP-I)]-L-Met spectrum exhibits a well-resolved hyperfine split pattern at g = 7.6 with a hyperfine splitting constant of A = 4.4 mT. These data suggest the presence of a magnetically coupled dinuclear Mn(II) center. On the other hand, a similar feature was not observed for the [MnMn(PfMetAP-II)]-L-Met complex. Therefore, the EPR data suggest that L-Met binds to [MnMn(EcMetAP-I)] differently than [MnMn(PfMetAP-II)]. To confirm these data, the X-ray crystal structure of [MnMn(PfMetAP-II)]-L-Met was solved to 2.3 A resolution. Both Mn1 and Mn2 reside in a distorted trigonal bipyramidal geometry, but the bridging water molecule, observed in the [CoCo(PfMetAP-II)] structure, is absent. Therefore, L-Met binding displaces this water molecule, but the carboxylate oxygen atom of L-Met does not bridge between the two Mn(II) ions. Instead, a single carboxylate oxygen atom of L-Met interacts with only Mn1, while the N-terminal amine nitrogen atom binds to M2. This L-Met binding mode is different from that observed for L-Met binding [CoCo(EcMetAP-I)]. Therefore, the catalytic mechanisms of type-I MetAPs may differ somewhat from type-II enzymes when a dinuclear metalloactive site is present.     

A new colorimetric assay for methionyl aminopeptidases: examination of the binding of a new class of pseudopeptide analog inhibitors

A direct and convenient spectrophotometric assay has been developed for methionine aminopeptidases (MetAPs). The method employs the hydrolysis of a substrate that is a methionyl analogue of p-nitroaniline (L-Met-p-NA), which releases the chromogenic product p-nitroaniline. This chromogenic product can be monitored continuously using a UV-Vis spectrophotometer set at 405 nm. The assay was tested with the type I MetAP from Escherichia coli (EcMetAP-I) and the type II MetAP from Pyrococcus furiosus (PfMetAP-II). Using L-Met-p-NA, the kinetic constants k(cat) and K(m) were determined for EcMetAP-I and PfMetAP-II and were compared with those obtained with a "standard" high-performance liquid chromatography (HPLC) discontinuous assay. The assay has also been used to determine the temperature dependence of the kinetic constant k(cat) for PfMetAP-II as well as to screen two novel pseudopeptide inhibitors of MetAPs. The results demonstrate that L-Met-p-NA provides a fast, convenient, and effective substrate for both type I and type II MetAPs and that this substrate can be used to quickly screen inhibitors of MetAPs.     

Analyzing the binding of Co(II)-specific inhibitors to the methionyl aminopeptidases from Escherichia coli and Pyrococcus furiosus

Methionine aminopeptidases (MetAPs) represent a unique class of protease that is capable of the hydrolytic removal of an N-terminal methionine residue from nascent polypeptide chains. MetAPs are physiologically important enzymes; hence, there is considerable interest in developing inhibitors that can be used as antiangiogenic and antimicrobial agents. A detailed kinetic and spectroscopic study has been performed to probe the binding of a triazole-based inhibitor and a bestatin-based inhibitor to both Mn(II)- and Co(II)-loaded type-I (Escherichia coli) and type-II (Pyrococcus furiosus) MetAPs. Both inhibitors were found to be moderate competitive inhibitors. The triazole-type inhibitor was found to interact with both active-site metal ions, while the bestatin-type inhibitor was capable of switching its mode of binding depending on the metal in the active site and the type of MetAP enzyme.     

Two continuous spectrophotometric assays for methionine aminopeptidase

Two spectrophotometric assays have been developed for methionine aminopeptidases (MetAPs). The first method employs a thioester substrate which, upon enzymatic removal of the N-terminal methionine, generates a free thiol group. The released thiol is quantitated using Ellman's reagent. The MetAP reaction is conveniently monitored on a UV-VIS spectrophotometer in a continuous fashion, with the addition of an excess of Ellman's reagent into the assay reaction. Two tripeptide analogues were synthesized and found to be excellent substrates of both Escherichia coli MetAP and human MetAP2 (k(cat)/K(M) = 2.8 x 10(5) M(-1) s(-1) for the most reactive substrate). In the second assay method, the MetAP reaction is coupled to a prolyl aminopeptidase reaction using Met-Pro-p-nitroanilide as substrate. MetAP-catalyzed cleavage of the N-terminal methionine produces prolyl-p-nitroanilide, which is rapidly hydrolyzed by the prolyl aminopeptidase from Bacillus coagulans to release a chromogenic product, p-nitroaniline. This allows the MetAP reaction to be continuously monitored at 405 nm on a UV-VIS spectrophotometer. The assays have been applied to determine the pH optima and kinetic constants for the E. coli and human MetAPs as well as to screen MetAP inhibitors. These results demonstrate that the current assays are convenient, rapid, and sensitive methods for kinetic studies of MetAPs and effective tools for screening MetAP inhibitors.     

Identification of an SH3-binding motif in a new class of methionine aminopeptidases from Mycobacterium tuberculosis suggests a mode of interaction with the ribosome

The crystal structure of the methionine aminopeptidase (MetAP) from Mycobacterium tuberculosis (MtMetAP1c) has been determined in the apo- and methionine-bound forms. This is the first structure of a type I MetAP with a significant extension at the amino terminus. The catalytic domain is similar to that of Escherichia coli MetAP (EcMetAP), and the additional 40-residue segment wraps around the surface with an extended but well-defined structure. There are several members of the actinomyces family of bacteria that contain MetAPs with such N-terminal extensions, and we classify these as MetAP type Ic (MetAP1c). Some members of this family of bacteria also contain a second MetAP (type Ia) similar in size to EcMetAP. The main difference between the apo- and the methionine-bound forms of MtMetAP1c is in the conformation of the metal-binding residues. The position of the methionine bound in the active site is very similar to that found in many of the known members of this family. Side chains of several residues in the S1 and S1' subsites shift as much as 1.5 A compared to EcMetAP. Residues 14-17 have the sequence Pro-Thr-Arg-Pro and adopt the conformation of a polyproline II helix. Model-building suggests that this PxxP segment can bind to an SH3 protein motif. Other type Ib and type Ic MetAPs with N-terminal extensions contain similarly located PxxP motifs. Also, several ribosomal proteins are known to include SH3 domains, one of which is located close to the tunnel from which the nascent polypeptide chain exits the ribosome. Therefore, it is proposed that the binding of MetAPs to the ribosome is mediated by a complex between a PxxP motif on the protein and an SH3 domain on the ribosome. It is also possible that zinc-finger domains, which are located at the extreme N-terminus of type I MetAPs, may participate in interactions with the ribosome.     

Removal of N-terminal methionine from recombinant proteins by engineered E. coli methionine aminopeptidase

The removal of N-terminal translation initiator Met by methionine aminopeptidase (MetAP) is often crucial for the function and stability of proteins. On the basis of crystal structure and sequence alignment of MetAPs, we have engineered Escherichia coli MetAP by the mutation of three residues, Y168G, M206T, Q233G, in the substrate-binding pocket. Our engineered MetAPs are able to remove the Met from bulky or acidic penultimate residues, such as Met, His, Asp, Asn, Glu, Gln, Leu, Ile, Tyr, and Trp, as well as from small residues. The penultimate residue, the second residue after Met, was further removed if the antepenultimate residue, the third residue after Met, was small. By the coexpression of engineered MetAP in E. coli through the same or a separate vector, we have successfully produced recombinant proteins possessing an innate N terminus, such as onconase, an antitumor ribonuclease from the frog Rana pipiens. The N-terminal pyroglutamate of recombinant onconase is critical for its structural integrity, catalytic activity, and cyto-toxicity. On the basis of N-terminal sequence information in the protein database, 85%-90% of recombinant proteins should be produced in authentic form by our engineered MetAPs.     

金属离子选择性的甲硫氨酰氨肽酶抑制剂研究进展

甲硫氨酰氨肽酶(MetAP)是潜在的抗细菌、抗真菌和肿瘤治疗的分子靶点。MetAP是一类两价金属离子依赖的蛋白水解酶。然而,生理状态下,MetAP在细胞内结合并利用的金属离子类型目前还没有定论。因而,研究和发展不同金属离子选择性的甲硫氨酰氨肽酶抑制剂对细胞内源性金属离子的解析以及新型抗肿瘤及抗感染药物的研发具有重要意义。     

Mutations at the S1 sites of methionine aminopeptidases from Escherichia coli and Homo sapiens reveal the residues critical for substrate specificity

Methionine aminopeptidase (MetAP) catalyzes the removal of methionine from newly synthesized polypeptides. MetAP carries out this cleavage with high precision, and Met is the only natural amino acid residue at the N terminus that is accepted, although type I and type II MetAPs use two different sets of residues to form the hydrophobic S1 site. Characteristics of the S1 binding pocket in type I MetAP were investigated by systematic mutation of each of the seven S1 residues in Escherichia coli MetAP type I (EcMetAP1) and human MetAP type I (HsMetAP1). We found that Tyr-65 and Trp-221 in EcMetAP1, as well as the corresponding residues Phe-197 and Trp-352 in HsMetAP1, were essential for the hydrolysis of a thiopeptolide substrate, Met-S-Gly-Phe. Mutation of Phe-191 to Ala in HsMetAP1 caused inactivity in contrast to the full activity of EcMetAP1(Y62A), which may suggest a subtle difference between the two type I enzymes. The more striking finding is that mutation of Cys-70 in EcMetAP1 or Cys-202 in HsMetAP1 opens up the S1 pocket. The thiopeptolides Leu-S-Gly-Phe and Phe-S-Gly-Phe, with previously unacceptable Leu or Phe as the N-terminal residue, became efficient substrates of EcMetAP1(C70A) and HsMetAP1(C202A). The relaxed specificity shown in these S1 site mutants for the N-terminal residues was confirmed by hydrolysis of peptide substrates and inhibition by reaction products. The structural features at the enzyme active site will be useful information for designing specific MetAP inhibitors for therapeutic applications.     

Structure of the angiogenesis inhibitor ovalicin bound to its noncognate target, human Type 1 methionine aminopeptidase

Methionine aminopeptidases (MetAPs) remove the initiator methionine during protein biosynthesis. They exist in two isoforms, MetAP1 and MetAP2. The anti-angiogenic compound fumagillin binds tightly to the Type 2 MetAPs but only weakly to Type 1. High-affinity complexes of fumagillin and its relative ovalicin with Type 2 human MetAP have been reported. Here we describe the crystallographic structure of the low-affinity complex between ovalicin and Type 1 human MetAP at 1.1 A resolution. This provides the first opportunity to compare the structures of ovalicin or fumagillin bound to a Type 1 and a Type 2 MetAP. For both Type 1 and Type 2 human MetAPs the inhibitor makes a covalent adduct with a corresponding histidine. At the same time there are significant differences in the alignment of the inhibitors within the respective active sites. It has been argued that the lower affinity of ovalicin and fumagillin for the Type 1 MetAPs is due to the smaller size of their active sites relative to the Type 2 enzymes. Comparison with the uncomplexed structure of human Type 1 MetAP indicates that there is some truth to this. Several active site residues have to move "outward" by 0.5 Angstroms or so to accommodate the inhibitor. Other residues move "inward." There are, however, other factors that come into play. In particular, the side chain of His310 rotates by 134 degrees into a different position where (together with Glu128 and Tyr195) it coordinates a metal ion not seen at this site in the native enzyme.     

Structure and function of the methionine aminopeptidases

The removal of the N-terminal methionine from proteins and peptides is dependent upon a novel class of proteases typified by the dinuclear metalloenzyme methionine aminopeptidase from Escherichia coli (eMetAP). Substantial progress has recently been made in determining the structures of several members of this family. The identification of human MetAP as the target of putative anti-cancer drugs reiterates the importance of this family of enzymes. Determination of the modes of binding to E. coli MetAP of a substrate-like bestatin-based inhibitor, as well as phosphorus-containing transition-state analogs and reaction products has led to a rationalization of the substrate specificity and suggested the presumed catalytic mechanism. The conservation of key active site residues and ligand interactions between the MetAPs and other enzyme of the same fold suggest that avoidance of cross-reactivity may be an important consideration in the design of inhibitors directed toward a single member of the family.     

Identification of potent type I MetAP inhibitors by simple bioisosteric replacement. Part 1: Synthesis and preliminary SAR studies of thiazole-4-carboxylic acid thiazol-2-ylamide derivatives

A series of thiazole-4-carboxylic acid thiazol-2-ylamide (TCAT, 4) derivatives were designed and synthesized according to simple bioisosteric replacement from previously reported pyridine-2-carboxylic acid thiazol-2-ylamide (PCAT) MetAP inhibitors. The preliminary SAR studies demonstrated that these TCAT series of compounds showed different activity and selectivity compared with those of the corresponding PCAT compounds. These findings provide useful information for the design and discovery of more potent inhibitors of type I MetAPs.     

A single amino acid difference between archaeal and human type 2 methionine aminopeptidases differentiates their affinity towards ovalicin

In almost all living cells, methionine aminopeptidase (MetAP) co-translationally cleaves the initiator methionine in at least 70% of the newly synthesized polypeptides. MetAPs are typically classified into Type 1 and Type 2. While prokaryotes and archaea contain only either Type 1 or Type 2 MetAPs respectively, eukaryotes contain both types of enzymes. Almost all MetAPs published till date cleave only methionine from the amino terminus of the substrate peptides. Earlier experiments on crude Type 2a MetAP isolated from Pyrococcus furiosus (PfuMetAP2a) cosmid protein library was shown to cleave leucine in addition to methionine. Authors in that study have ruled out the PfuMetAP2a activity against leucine substrates and assumed it to be a background reaction contributed by other contaminating proteases. In the current paper, using the pure recombinant enzyme, we report that indeed activity against leucine is directly carried out by the PfuMetAP2a. In addition, the natural product ovalicin which is a specific covalent inhibitor of Type 2 MetAPs does not show efficient inhibition against the PfuMetAP2a. Bioinformatic analysis suggested that a glycine in eukaryotic MetAP2s (G222 in human MetAP2b) and asparagine (N53 in PfuMetAP2a) in archaeal MetAP2s positioned at the analogous position. N53 side chain forms a hydrogen bond with a conserved histidine (H62) at the entrance of the active site and alters its orientation to accommodate the ovalicin. This slight orientational difference of the H62, reduces affinity of the ovalicin by 300,000-fold when compared with the HsMetAP2b inhibition. This difference in the activity is partly reduced in the case of N53G mutation of the PfuMetAP2a.     

Discovery of a New Genetic Variant of Methionine Aminopeptidase from Streptococci with Possible Post-Translational Modifications: Biochemical and Structural Characterization

Protein N-terminal methionine excision is an essential co-translational process that occurs in the cytoplasm of all organisms. About 60-70% of the newly synthesized proteins undergo this modification. Enzyme responsible for the removal of initiator methionine is methionine aminopeptidase (MetAP), which is a dinuclear metalloprotease. This protein is conserved through all forms of life from bacteria to human except viruses. MetAP is classified into two isoforms, Type I and II. Removal of the map gene or chemical inhibition is lethal to bacteria and to human cell lines, suggesting that MetAP could be a good drug target. In the present study we describe the discovery of a new genetic variant of the Type I MetAP that is present predominantly in the streptococci bacteria. There are two inserts (insert one: 27 amino acids and insert two: four residues) within the catalytic domain. Possible glycosylation and phosphorylation posttranslational modification sites are identified in the ‘insert one’. Biochemical characterization suggests that this enzyme behaves similar to other MetAPs in terms of substrate specificity. Crystal structure Type Ia MetAP from Streptococcus pneumoniae (SpMetAP1a) revealed that it contains two molecules in the asymmetric unit and well ordered inserts with structural features that corroborate the possible posttranslational modification. Both the new inserts found in the SpMetAP1a structurally align with the P-X-X-P motif found in the M. tuberculosis and human Type I MetAPs as well as the 60 amino acid insert in the human Type II enzyme suggesting possible common function. In addition, one of the β-hairpins within in the catalytic domain undergoes a flip placing a residue which is essential for enzyme activity away from the active site and the β-hairpin loop of this secondary structure in the active site obstructing substrate binding. This is the first example of a MetAP crystallizing in the inactive form.     

Amino acid sequences of alpha-helical segments from S-carbosymethylkerateine-A. Complete sequence of a type-I segment.

The amino acid sequence of a type-I helical segment from the low-sulphur protein (S-carboxymethylkerateine-A) of wool was determined by combining automatic and manual-sequencing data. Whereas in the type-II helical segment most of the cationic groups occur in pairs, 11 of the 22 anionic residues in the sequence of the type-I segment were situated next to a second anionic residue. This suggests possible interactions between type-I and type-II helical segments in alpha-keratin. As observed with the sequence of a type-II helical segment a model constructed on 3.6 residues per turn of helix shows a line of hydrophobic residues along the helix, thereby supporting the physicochemical evidence that the molecule is predominantly helical and forms part of a coiled-coil structure. Examination of the sequence data by predictive methods indicates the possibilty of extensive sections of alpha-helix interspersed with discontinuities. The molecule contains a number of regions with peptide sequences identical with those found by other workers after enzymic digestion of fractions from oxidized wool.     

Beta-aminoketones as prodrugs for selective irreversible inhibitors of type-1 methionine aminopeptidases

We identified and characterized β-aminoketones as prodrugs for irreversible MetAP inhibitors that are selective for the MetAP-1 subtype. β-Aminoketones with certain structural features form α,β-unsaturated ketones under physiological conditions, which bind covalently and selectively to cysteines in the S1 pocket of MetAP-1. The binding mode was confirmed by X-ray crystallography and assays with the MetAPs from Escherichia coli, Staphylococcus aureus and both human isoforms. The initially identified tetralone derivatives showed complete selectivity for E. coli MetAP versus human MetAP-1 and MetAP-2. Rational design of indanone analogs yielded compounds with selectivity for the human type-1 versus the human type-2 MetAP.     

Expression and characterization of Mycobacterium tuberculosis methionine aminopeptidase type 1a

Methionine aminopeptidase (MetAP) carries out the cotranslational N-terminal methionine excision and is essential for bacterial survival. Mycobacterium tuberculosis expresses two MetAPs, MtMetAP1a and MtMetAP1c, at different levels in growing and stationary phases, and both are potential targets to develop novel antitubercular therapeutics. Recombinant MtMetAP1a was purified as an apoenzyme, and metal binding and activation were characterized with an activity assay using a fluorogenic substrate. Ni(II), Co(II) and Fe(II) bound tightly at micromolar concentrations, and Ni(II) was the most efficient activator for the MetAP-catalyzed substrate hydrolysis. Although the characteristics of metal binding and activation are similar to MtMetAP1c we characterized before, MtMetAP1a was significantly more active, and more importantly, a set of inhibitors displayed completely different inhibitory profiles on the two mycobacterial MetAPs in both potency and metalloform selectivity. The differences in catalysis and inhibition predicted the significant differences in active site structure.     

Kinetic and mutational studies of the number of interacting divalent cations required by bacterial and human methionine aminopeptidases

Methionine aminopeptidases (MetAP) are responsible for the proteolytic removal of the initiator methionine from nascent proteins. This processing permits multiple posttranslational modifications and protein turnover. We have cloned, expressed in Escherichia coli, and purified the recombinant human mitochondrial MetAP isoform (MetAP1D). The full-length enzyme and a truncated form lacking the mitochondrial targeting sequence (residues 1-55) have been characterized as metal-requiring proteases, with Co2+ being the best activator. At the optimal pH (8.0), the kcat of MetAP1D of 0.39 min-1 is 280-fold lower, and the Km of the substrate Met-Pro-p-nitroanilide (576 microM) is 3-fold greater, than the respective kinetic parameters obtained with MetAP from E. coli, although MetAP1D is 61% homologous to E. coli MetAP and their circular dichroic spectra are nearly identical. MetAP1D thus appears to be a less efficient enzyme than other known MetAPs in vitro. At saturating substrate concentrations, a plot of Vmax versus free Co2+ shows sigmoidal metal activation of MetAP1D, both with and without an N-terminal His-tag, with a Hill coefficient (n) of 1.9 and a K0.5 of 0.40 microM. Similarly, E. coli MetAP shows n = 2.1 and K0.5 = 0.2 microM. Hence, at least two Co2+ ions, which may act cooperatively, are needed to promote catalysis, providing kinetic evidence for the functioning of both Co2+ ions of the binuclear complex found in the X-ray structure of E. coli MetAP [Roderick, S. L. and Matthews, B. W. (1993) Biochemistry 32, 3907-3912] and resolving a disagreement in the literature. The X-ray structure of the human cytosolic MetAP1 showed three Co2+ ions at the active site, with the third Co2+ coordinated by the conserved residue His 212 [Addlagatta, A., Hu, X., Liu, J. O., and Matthews, B. W. (2005) Biochemistry 44, 14741-14749]. Consistent with the structure, kinetic studies of the human cytosolic MetAP1 yielded a Hill coefficient (n) of 2.9 and a K0.5 of 0.26 microM for activation by Co2+, as well as a kcat of 25.5 min-1 and a Km of 740 microM for the substrate Met-Pro-p-nitroanilide. The H212A mutation decreased n to 2.2, decreased kcat 60-fold to 0.42 min-1, and increased K0.5 6.5-fold to 1.8 microM. The H212K mutation further decreased n to 1.4, decreased kcat 1800-fold to 0.014 min-1, and increased K0.5 158-fold to 41 microM. Hence, at least three Co2+ ions are needed to promote optimal catalysis by human MetAP1. Both mutations of His212 abolished the binding and/or the cooperativity of the third Co2+ ion, as indicated by the decreases in n and the increases in K0.5 of the remaining two Co2+ ions, but did not affect the Km of the substrate. The more damaging effects of the H212K mutation on both the Hill coefficient for Co2+ binding and the catalysis suggest that Lys 212 might directly compete with Co2+ for the third metal-binding site. Together, these results suggest that human MetAP1 is distinct from other members of the MetAP superfamily in the number of metal ions employed and likely mechanism of catalysis.     

A simple statistical method for estimating type-II (cluster-specific) functional divergence of protein sequences

Predicting functional amino acid residues in silico is important for comparative genomics. In this paper, we focus on the issue of how to statistically identify cluster-specific amino acid residues that are related to the functional divergence after gene duplication. We approach this problem using a framework based on site-specific shift of amino acid property (type-II functional divergence), as opposed to site-specific shift of evolutionary rate (type-I functional divergence). An efficient statistical procedure is implemented to facilitate the development of phylogenomic database for cluster-specific residues of large-scale protein families. Our method has the following features: 1) statistical testing of the type-II functional divergence and 2) the site-specific Bayesian profile to measure how amino acid residues contribute to type-II (cluster-specific) functional divergence. Consequently, one may obtain the posterior probability for "functional" cluster-specific residues. Case studies are presented and indicate that radical cluster-specific residues are responsible for most of inferred type-II functional divergence, whereas conserved cluster-specific residues appear less than even those imperfect radical cluster-specific residues to this type of functional divergence.     

Subtype-selectivity of metal-dependent methionine aminopeptidase inhibitors

Inhibitors of methionine aminopeptidases (MetAPs) are treatment options for various pathological conditions. Several inhibitor classes have been described previously, but only few data on the subtype selectivity, which is of crucial importance for these enzymes, is available. We present a systematic study on the subtype- and species-selectivity of MetAP inhibitors that require the binding of an auxiliary metal ion. This includes, in particular, compounds based on the benzimidazole pharmacophore, but also hydroxyquinoline and picolinic acid derivatives. Our data indicates that a significant degree of selectivity can be attained with metal-dependent MetAP inhibitors.     

Specificity for inhibitors of metal-substituted methionine aminopeptidase

Methionine aminopeptidases (MetAPs) have been studied in vitro as Co(II) enzymes, but their in vivo metal remains to be defined. While activation of Escherichia coli MetAP (EcMetAP1) by Co(II), Mn(II), and Zn(II) was detectable by a colorimetric Met-S-Gly-Phe assay, significant activation by Ni(II) was shown in a fluorescence Met-AMC assay, in addition to Co(II) and Mn(II) activation. When tested on the metal-substituted EcMetAP1s, a few inhibitors that we obtained recently from a random screening on Co-EcMetAP1 either became much weak or lost activity on Mn- or Zn-EcMetAP1, although they kept inhibitory activity on Ni-EcMetAP1. A couple of peptidic inhibitors and the methionine mimetic (3R)-amino-(2S)-hydroxyheptanoic acid (AHHpA, 6) maintained moderate activities on Co-, Mn-, Zn-, and Ni-EcMetAP1s. Our results clearly demonstrate that the metal-substitution has changed the enzyme specificity for substrates and inhibitors. Therapeutic applications call for inhibitors specific for MetAP with a physiologically relevant metal at its active site.