Changes in zinc ligation promote remodeling of the active site in the zinc hydrolase superfamily.

The zinc hydrolase superfamily is a group of divergently related proteins that are predominantly enzymes with a zinc-based catalytic mechanism. The common structural scaffold of the superfamily consists of an eight-stranded beta-sheet flanked by six alpha-helices. Previous analyses, while acknowledging the likely divergent origins of leucine aminopeptidase, carboxypeptidase A and the co-catalytic enzymes of the metallopeptidase H clan based on their structural scaffolds, have failed to find any homology between the active sites in leucine aminopeptidase and the metallopeptidase H clan enzymes. Here we show that these two groups of co-catalytic enzymes have overlapping dizinc centers where one of the two zinc atoms is conserved in each group. Carboxypeptidase A and leucine aminopeptidase, on the other hand, no longer share any homologous zinc-binding sites. At least three catalytic zinc-binding sites have existed in the structural scaffold over the period of history defined by available structures. Comparison of enzyme-inhibitor complexes show that major remodeling of the substrate-binding site has occurred in association with each change in zinc ligation in the binding site. These changes involve re-registration and re-orientation of the substrate. Some residues important to the catalytic mechanism are not conserved amongst members. We discuss how molecules acting in trans may have facilitated the mutation of catalytically important residues in the active site in this group.     

Interaction of zinc ions with arsanilazotyrosine-248 carboxypeptidase A

The interaction between arsanilazotyrosine-248 carboxypeptidase A ([(Azo-CPD)Zn]) and excess zinc ions has been studied by stopped-flow and spectrophotometric methods at pH 8.2 and 7.7, I = 0.5 M (NaCl), and 25 degrees C. When excess zinc ions bind to arsanilazotyrosine-248 carboxypeptidase A, the characteristic red color, which arises from the intramolecular complex of the arsanilazotyrosine-248 residue with the active site zinc of the enzyme, changes to yellow with the inhibition of peptidase activity of the enzyme. Excess zinc ions have two binding sites for arsanilazotyrosine-248 carboxypeptidase A, and the binding constants of the first site (3.9 X 10(5) M-1 at pH 8.2; 7.1 X 10(4) M-1 at pH 7.7) are much larger than those of the second site (1.8 X 10(3) M-1 at pH 8.2; 7 X 10(2) M-1 at pH 7.7). The binding of excess zinc ions to the first site is completely correlated with the inhibition of the enzyme peptidase activity and the color change of the enzyme. The results can be understood in terms of zinc ions reacting with only one of three conformational states of arsanilazotyrosine-248 carboxypeptidase A [Harrison, L. W., Auld, D. S., & Vallee, B. L. (1975) Proc. Natl. Acad. Sci. U.S.A. 72, 4356].(ABSTRACT TRUNCATED AT 250 WORDS)     

Essential roles of zinc ligation and enzyme dimerization for catalysis in the aminoacylase-1/M20 family

Members of the aminoacylase-1 (Acy1)/M20 family of aminoacylases and exopeptidases exist as either monomers or homodimers. They contain a zinc-binding domain and a second domain mediating dimerization in the latter case. The roles that both domains play in catalysis have been investigated for human Acy1 (hAcy1) by x-ray crystallography and by site-directed mutagenesis. Structure comparison of the dinuclear zinc center in a mutant of hAcy1 reported here with dizinc centers in related enzymes points to a difference in zinc ligation in the Acy1/M20 family. Mutational analysis supports catalytic roles of zinc ions, a vicinal glutamate, and a histidine from the dimerization domain. By complementing different active site mutants of hAcy1, we show that catalysis occurs at the dimer interface. Reinterpretation of the structure of a monomeric homolog, peptidase V, reveals that a domain insertion mimics dimerization. We conclude that monomeric and dimeric Acy1/M20 family members share a unique active site architecture involving both enzyme domains. The study may provide means to improve homologous carboxypeptidase G2 toward application in antibody-directed enzyme prodrug therapy.     

3D structure of Sulfolobus solfataricus carboxypeptidase developed by molecular modeling is confirmed by site-directed mutagenesis and small angle X-ray scattering

Sulfolobus solfataricus carboxypeptidase (CPSso) is a thermostable zinc-metalloenzyme with a M(r) of 43,000. Taking into account the experimentally determined zinc content of one ion per subunit, we developed two alternative 3D models, starting from the available structures of Thermoactinomyces vulgaris carboxypeptidase (Model A) and Pseudomonas carboxypeptidase G2 (Model B). The former enzyme is monomeric and has one metal ion in the active site, while the latter is dimeric and has two bound zinc ions. The two models were computed by exploiting the structural alignment of the one zinc- with the two zinc-containing active sites of the two templates, and with a threading procedure. Both computed structures resembled the respective template, with only one bound zinc with tetrahedric coordination in the active site. With these models, two different quaternary structures can be modeled: one using Model A with a hexameric symmetry, the other from Model B with a tetrameric symmetry. Mutagenesis experiments directed toward the residues putatively involved in metal chelation in either of the models disproved Model A and supported Model B, in which the metal-binding site comprises His(108), Asp(109), and His(168). We also identified Glu(142) as the acidic residue interacting with the water molecule occupying the fourth chelation site. Furthermore, the overall fold and the oligomeric structure of the molecule was validated by small angle x-ray scattering (SAXS). An ab initio original approach was used to reconstruct the shape of the CPSso in solution from the experimental curves. The results clearly support a tetrameric structure. The Monte Carlo method was then used to compare the crystallographic coordinates of the possible quaternary structures for CPSso with the SAXS profiles. The fitting procedure showed that only the model built using the Pseudomonas carboxypeptidase G2 structure as a template fitted the experimental data.     

Molecular dynamics simulations of matrix metalloproteinase 2: role of the structural metal ions

Herein we investigate the role played by the so-called "structural metal ions" in the catalytic domain of the matrix metalloproteinase 2 enzyme (MMP-2 or gelatinase A). We performed seven molecular dynamics simulations that differ in the number and position of the noncatalytic zinc and calcium ions bound to the MMP-2 catalytic domain. An additional simulation including the three fibronectin-type modules inserted into the catalytic domain was also carried out. The analysis of the trajectories confirms that the binding/removal of the structural ions does not perturb the secondary structure elements but influences the position of several solvent-exposed loop regions that are placed near the active site cleft. The position of these loops modulates the accessibility of important anchorage points for substrate binding that have been identified in the active site groove. On the basis of semiempirical quantum chemical calculations, we estimated the relative free energies of the MMP-2 models, obtaining thus that the binding of two zinc and two calcium ions to the MMP-2 catalytic domain is energetically favored. In this MMP-2 model, which shows the most compact structure, all of the substrate binding sites are readily accessible. Globally, our results help to rationalize at the atomic level the calcium and zinc dependence of the hydrolytic activity catalyzed by the MMPs.     

Staphylococcus aureus aminopeptidase S is a founding member of a new peptidase clan

Staphylococcus aureus aminopeptidase S (AmpS) has been named for its predicted, but experimentally untested, aminopeptidase activity. The enzyme is homologous to biochemically characterized aminopeptidases that contain two cobalt or zinc ions in their active centers, but it is unrelated to all structurally characterized metallopeptidases. Here, we demonstrate AmpS aminopeptidase activity experimentally, and we present the 1.8-A crystal structure of the enzyme. Two metal ions with full occupancy and a third metal ion with low occupancy are present in the active site. A water molecule and Glu-319 serve as bridging ligands to the two metals with full occupancy. One of these metal ions is additionally coordinated by Glu-253 and His-348 and the other by His-381 and Asp-383. In addition, the metals are involved in weak metal-donor interactions to a water molecule and to Tyr-355. In the crystal, AmpS forms a dimer with a large internal cavity. The active sites are located at opposite ends of this internal cavity and are essentially inaccessible from the outside, suggesting that an inactive conformation was crystallized. Because gel filtration and analytical ultracentrifugation data also suggest dimer formation, the problem of substrate access to the active site cavity remains unresolved.     

Structural and kinetic bases for the metal preference of the M18 aminopeptidase from Pseudomonas aeruginosa

The peptidases in clan MH are known as cocatalytic zinc peptidases that have two zinc ions in the active site, but their metal preference has not been rigorously investigated. In this study, the molecular basis for metal preference is provided from the structural and biochemical analyses. Kinetic studies of Pseudomonas aeruginosa aspartyl aminopeptidase (PaAP) which belongs to peptidase family M18 in clan MH revealed that its peptidase activity is dependent on Co²⁺ rather than Zn²⁺: the k_cat (s⁻¹) values of PaAP were 0.006, 5.10 and 0.43 in no-metal, Co²⁺, and Zn²⁺ conditions, respectively. Consistently, addition of low concentrations of Co²⁺ to PaAP previously saturated with Zn²⁺ greatly enhanced the enzymatic activity, suggesting that Co²⁺ may be the physiologically relevant cocatalytic metal ion of PaAP. The crystal structures of PaAP complexes with Co²⁺ or Zn²⁺ commonly showed two metal ions in the active site coordinated with three conserved residues and a bicarbonate ion in a tetragonal geometry. However, Co²⁺- and Zn²⁺-bound structures showed no noticeable alterations relevant to differential effects of metal species, except the relative orientation of Glu-265, a general base in the active site. The characterization of mutant PaAP revealed that the first metal binding site is primarily responsible for metal preference. Similar to PaAP, Streptococcus pneumonia glutamyl aminopeptidase (SpGP), belonging to aminopeptidase family M42 in clan MH, also showed requirement for Co²⁺ for maximum activity. These results proposed that clan MH peptidases might be a cocatalytic cobalt peptidase rather than a zinc-dependent peptidase.     

Structure determination and refinement of bovine lens leucine aminopeptidase and its complex with bestatin.

The three-dimensional structure of bovine lens leucine aminopeptidase (EC 3.4.11.1) complexed with bestatin, a slow-binding inhibitor, has been solved to 3.0 A resolution by the multiple isomorphous replacement method with phase combination and density modification. In addition, this structure and the structure of the isomorphous native enzyme have been refined at 2.25 and 2.32 A resolution, respectively, with crystallographic R-factors of 0.180 and 0.159, respectively. The current structural model for the enzyme includes the two zinc ions and 481 of the 487 amino acid residues comprising the asymmetric unit. The enzyme is physiologically active as a hexamer, which has 32 symmetry, and is triangular in shape with a triangle edge length of 115 A and maximal thickness of 90 A. Monomers are crystallographically equivalent. Each is folded into two unequal alpha/beta domains connected by an alpha-helix to give a comma-like shape with approximate maximal dimensions of 90 A x 55 A x 55 A. The secondary structural composition is 35% alpha-helix and 23% beta-strand. The N-terminal domain (160 amino acid residues) mediates trimer-trimer interactions and does not appear to participate directly in catalysis, while the C-terminal domain (327 amino acid residues) is responsible for catalysis and binds the two zinc ions, which are less than 3 A apart. These two metal ions are located near the edge of an eight-stranded, saddle-shaped beta-sheet. The zinc ion that has the lower temperature factor is co-ordinated by one carboxylate oxygen atom from each of Asp255, Asp332 and Glu334, and the carbonyl oxygen of Asp332. The other zinc ion, presumed to be readily exchangeable, is co-ordinated by one carboxylate oxygen atom of each of Asp273 and Glu334 and the side-chain amino group of Lys250. The active site also contains two positively charged residues, Lys262 and Arg336. The six active sites are themselves located in the interior of the hexamer, where they line a disk-shaped cavity of radius 15 A and thickness 10 A. Access to this cavity is provided by solvent channels that run along the 2-fold symmetry axes. Bestatin binds to one of the active site zinc ions, and its phenylalanine and leucine side-chains occupy hydrophobic pockets adjacent to the active site. Finally, the relationship between bovine lens leucine aminopeptidase and the homologous enzyme pepA from Escherichia coli is discussed.     

Polypeptide stimulators of the Ms-Lon protease

Both the peptidase activity against small fluorescent peptide substrates and the ATPase activity of Lon (La) proteases are stimulated by unstructured proteins such as alpha-casein. This stimulation reveals the simultaneous interaction of Lon with two proteolytic substrates--alpha-casein and the peptide substrate. To understand the cellular function of this stimulation, it is important to determine the physical properties of Lon stimulators. The abilities of compositionally simple random copolymers of amino acids (rcAAs) to stimulate the peptidase and ATPase activities of the Lon protease from Mycobacterium smegmatis (Ms-Lon) and its N-terminal truncation mutant (N-E226) were determined. We report that cationic but not anionic rcAAs stimulated Ms-Lon's peptidase activity but were themselves poor substrates for the enzyme. Peptidase stimulation by rcAAs correlated approximately with the degree of hydrophobicity of these polypeptides and reached levels >10-fold higher than observed previously for Ms-Lon stimulators such as alpha-casein. In contrast to alpha-casein, which stimulates Ms-Lon's peptidase activity by 40% and ATPase activity by 150%, rcAAs stimulated peptidase activity without concomitant stimulation of ATPase activity. Active site labeling experiments suggested that both rcAAs and ATP increased peptidase activity by increasing accessibility to the peptidase active site. Peptidase activity assays in the presence of both alpha-casein and rcAAs revealed that interactions of rcAAs and alpha-casein with Ms-Lon are extremely complex and not mutually exclusive. Specifically, (1) additions of low concentrations of alpha-casein (<50 microg/mL) caused a further stimulation of Ms-Lon's rcAA-stimulated peptidase activity; (2) additions of higher concentrations of alpha-casein inhibited Ms-Lon's rcAA-stimulated peptidase activity; (3) additions of all concentrations of alpha-casein inhibited N-E226's rcAA-stimulated peptidase activity. We conclude the Ms-Lon can interact with an rcAA, alpha-casein, and a substrate peptide simultaneously, and that formation of this quaternary complex requires the N-terminal domain of Ms-Lon. These data support models of Ms-Lon that include two allosteric polypeptide binding sites distinct from the catalytic peptidase site.     

Crystal structure of the dinuclear zinc aminopeptidase PepV from Lactobacillus delbrueckii unravels its preference for dipeptides

PepV from Lactobacillus delbrueckii, a dinuclear zinc peptidase, has been characterized as an unspecific amino dipeptidase. The crystal structure of PepV in complex with the phosphinic inhibitor AspPsi[PO(2)CH(2)]AlaOH, a dipeptide substrate mimetic, reveals a "catalytic domain" and a "lid domain," which together form an internal active site cavity that traps the inhibitor. The catalytic domain is topologically similar to catalytic domains from amino- and carboxypeptidases. However, the lid domain is unique among the related enzymes. In contrast to the other related exopeptidases, PepV recognizes and fixes the dipeptide backbone, while the side chains are not specifically probed and can vary, rendering it a nonspecific dipeptidase. The cocrystallized inhibitor illustrates the two roles of the two catalytic zinc ions, namely stabilization of the tetrahedral intermediate and activation of the catalytic water molecule.     

Structure of the prolidase from Pyrococcus furiosus

The structure of prolidase from the hyperthermophilic archaeon Pyrococcus furiosus (Pfprol) has been solved and refined at 2.0 A resolution. This is the first structure of a prolidase, i.e., a peptidase specific for dipeptides having proline as the second residue. The asymmetric unit of the crystals contains a homodimer of the enzyme. Each of the two protein subunits has two domains. The C-terminal domain includes the catalytic site, which is centered on a dinuclear metal cluster. In the as-isolated form of Pfprol, the active-site metal atoms are Co(II) [Ghosh, M., et al. (1998) J. Bacteriol. 180, 4781-9]. An unexpected finding is that in the crystalline enzyme the active-site metal atoms are Zn(II), presumably as a result of metal exchange during crystallization. Both of the Zn(II) atoms are five-coordinate. The ligands include a bridging water molecule or hydroxide ion, which is likely to act as a nucleophile in the catalytic reaction. The two-domain polypeptide fold of Pfprol is similar to the folds of two functionally related enzymes, aminopeptidase P (APPro) and creatinase. In addition, the catalytic C-terminal domain of Pfprol has a polypeptide fold resembling that of the sole domain of a fourth enzyme, methionine aminopeptidase (MetAP). The active sites of APPro and MetAP, like that of Pfprol, include a dinuclear metal center. The metal ligands in the three enzymes are homologous. Comparisons with the molecular structures of APPro and MetAP suggest how Pfprol discriminates against oligopeptides and in favor of Xaa-Pro substrates. The crystal structure of Pfprol was solved by multiple-wavelength anomalous dispersion. The crystals yielded diffraction data of relatively high quality and resolution, despite the fact that one of the two protein subunits in the asymmetric unit was found to be significantly disordered. The final R and R(free) values are 0.24 and 0.28, respectively.     

Structural analysis of a ternary complex of allantoate amidohydrolase from Escherichia coli reveals its mechanics

Purine metabolism plays a major role in regulating the availability of purine nucleotides destined for nucleic acid synthesis. Allantoate amidohydrolase catalyzes the conversion of allantoate to (S)-ureidoglycolate, one of the crucial alternate steps in purine metabolism. The crystal structure of a ternary complex of allantoate amidohydrolase with its substrate allantoate and an allosteric effector, a sulfate ion, from Escherichia coli was determined to understand better the catalytic mechanism and substrate specificity. The 2.25 A resolution X-ray structure reveals an alpha/beta scaffold akin to zinc exopeptidases of the peptidase M20 family and lacks the (beta/alpha)(8)-barrel fold characteristic of the amidohydrolases. Arrangement of the substrate and the two co-catalytic zinc ions at the active site governs catalytic specificity for hydrolysis of N-carbamyl versus the peptide bond in exopeptidases. In its crystalline form, allantoate amidohydrolase adopts a relatively open conformation. However, structural analysis reveals the possibility of a significant movement of domains via rotation about two hinge regions upon allosteric effector and substrate binding resulting in a closed catalytically competent conformation by bringing the substrate allantoate closer to co-catalytic zinc ions. Two cis-prolyl peptide bonds found on either side of the dimerization domain in close proximity to the substrate and ligand-binding sites may be involved in protein folding and in preserving the integrity of the catalytic site.     

Structure of the complex of active site metal-depleted horse liver alcohol dehydrogenase and NADH.

The complex between active site-specific metal-depleted horse liver alcohol dehydrogenase and NADH has been studied with X-ray crystallographic methods to 2.9 A resolution. The electron density maps revealed that only the catalytic zinc ions are removed, whereas the non-catalytic zinc sites ae fully occupied. A gross conformational change in the protein induced by co-enzyme binding takes place in this enzyme species despite the absence of the metal ion in the catalytic center. This circumstance is of great importance in the understanding and further analysis of the trigger mechanisms operating during the conformation transition in alcohol dehydrogenase, since the catalytic center is located at the hinge region for a domain rotation in the subunit, and the metal atom is essential for catalysis. The overall protein structure is the same as that of an NADH complex of the native zinc enzyme and the co-enzyme is bound in a similar manner. The local structural changes observed are restricted to the empty metal binding site.     

Purification and characterization of a methionine-specific aminopeptidase from Salmonella typhimurium

An aminopeptidase specific for methionine (peptidase M) has been purified from wild-type and mutant Salmonella typhimurium strains. Recombinant peptidase M was also purified from Escherichia coli. These preparations were characterized with respect to their physicochemical properties using analytical ultracentrifugation, SDS/PAGE, isoelectric focusing, titration curve analysis, amino acid analysis, N-and C-terminal sequencing and various spectroscopic methods. Peptidase M activity is stimulated by Co2+, in agreement with previous studies using crude extracts of Salmonella. The purified preparations did not contain significant amounts of any metal. Enzymically important metal is loosely associated and lost during enzyme purification. Peptidase M was shown to contain seven free sulphydryl residues none of which are involved in either intra-or inter-molecular disulphide bonds. Most appear solvent-accessible as evidenced by their reactivity under native conditions. Limited modification of the sulphydryl residues with either iodoacetamide or 5,5'-dithiobis(2-nitrobenzoic acid) led to inactivation. Several cysteines were shown to be labelled to various degrees by peptide mapping of inactivated S-[14C]carboxymethylated protein. Whether cysteine modification affects enzymic activity directly (blocking an active site) or indirectly (by causing conformational change) remains to be established.     

X-ray structure of ILL2, an auxin-conjugate amidohydrolase from Arabidopsis thaliana

The plant hormone indole-3-acetic acid (IAA) is the most abundant natural auxin involved in many aspects of plant development and growth. The IAA levels in plants are modulated by a specific group of amidohydrolases from the peptidase M20D family that release the active hormone from its conjugated storage forms. Here, we describe the X-ray crystal structure of IAA-amino acid hydrolase IAA-leucine resistantlike gene 2 (ILL2) from Arabidopsis thaliana at 2.0 A resolution. ILL2 preferentially hydrolyses the auxin-amino acid conjugate N-(indol-3-acetyl)-alanine. The overall structure of ILL2 is reminiscent of dinuclear metallopeptidases from the M20 peptidase family. The structure consists of two domains, a larger catalytic domain with three-layer alpha beta alpha sandwich architecture and aminopeptidase topology and a smaller satellite domain with two-layer alphabeta-sandwich architecture and alpha-beta-plaits topology. The metal-coordinating residues in the active site of ILL2 include a conserved cysteine that clearly distinguishes this protein from previously structurally characterized members of the M20 peptidase family. Modeling of N-(indol-3-acetyl)-alanine into the active site of ILL2 suggests that Leu175 serves as a key determinant for the amino acid side-chain specificity of this enzyme. Furthermore, a hydrophobic pocket nearby the catalytic dimetal center likely recognizes the indolyl moiety of the substrate. Finally, the active site of ILL2 harbors an absolutely conserved glutamate (Glu172), which is well positioned to act as a general acid-base residue. Overall, the structure of ILL2 suggests that this enzyme likely uses a catalytic mechanism that follows the paradigm established for the other enzymes of the M20 peptidase family.     

Peptidoglycan amidase MepA is a LAS metallopeptidase

LAS enzymes are a group of metallopeptidases that share an active site architecture and a core folding motif and have been named according to the group members lysostaphin, D-Ala-D-Ala carboxypeptidase and sonic hedgehog. Escherichia coli MepA is a periplasmic, penicillin-insensitive murein endopeptidase that cleaves the D-alanyl-meso-2,6-diamino-pimelyl amide bond in E. coli peptidoglycan. The enzyme lacks sequence similarity with other peptidases, and is currently classified as a peptidase of unknown fold and catalytic class in all major data bases. Here, we build on our observation that two motifs, characteristic of the newly described LAS group of metallopeptidases, are conserved in MepA-type sequences. We demonstrate that recombinant E. coli MepA is sensitive to metal chelators and that mutations in the predicted Zn2+ ligands His-113, Asp-120, and His-211 inactivate the enzyme. Moreover, we present the crystal structure of MepA. The active site of the enzyme is most similar to the active sites of lysostaphin and D-Ala-D-Ala carboxypeptidase, and the fold is most closely related to the N-domain of sonic hedgehog. We conclude that MepA-type peptidases are LAS enzymes.     

Structure of proline iminopeptidase from Xanthomonas campestris pv. citri: a prototype for the prolyl oligopeptidase family.

The proline iminopeptidase from Xanthomonas campestris pv. citri is a serine peptidase that catalyses the removal of N-terminal proline residues from peptides with high specificity. We have solved its three-dimensional structure by multiple isomorphous replacement and refined it to a crystallographic R-factor of 19.2% using X-ray data to 2.7 A resolution. The protein is folded into two contiguous domains. The larger domain shows the general topology of the alpha/beta hydrolase fold, with a central eight-stranded beta-sheet flanked by two helices and the 11 N-terminal residues on one side, and by four helices on the other side. The smaller domain is placed on top of the larger domain and essentially consists of six helices. The active site, located at the end of a deep pocket at the interface between both domains, includes a catalytic triad of Ser110, Asp266 and His294. Cys269, located at the bottom of the active site very close to the catalytic triad, presumably accounts for the inhibition by thiol-specific reagents. The overall topology of this iminopeptidase is very similar to that of yeast serine carboxypeptidase. The striking secondary structure similarity to human lymphocytic prolyl oligopeptidase and dipeptidyl peptidase IV makes this proline iminopeptidase structure a suitable model for the three-dimensional structure of other peptidases of this family.     

A spectral study of cobalt(II)-substituted Bacillus cereus phospholipase C

The coordination sphere of both the structural and catalytic zinc ions of Bacillus cereus phospholipase C has been probed by substitution of cobalt(II) for zinc and investigation of the resultant derivatives by a variety of spectroscopic techniques. The electronic absorption, circular dichroic, magnetic circular dichroic, and electron paramagnetic resonance spectra were found to be strikingly similar when cobalt(II) was substituted into either site and are consistent with a distorted octahedral environment for the metal ion in both sites. Octahedral coordination appears comparatively rare in zinc metalloenzymes but has been suggested for glyoxalase I [Sellin, S., Eriksson, L. E. G., Aronsson, A.-C., & Mannervik, B. (1983) J. Biol. Chem. 258, 2091-2093; Garcia-Iniguez, L., Powers, L., Chance, B., Sellin, S., Mannervik, B., & Mildvan, A. S. (1984) Biochemistry 23, 685-689], transcarboxylase [Fung, C.-H., Mildvan, A. S., & Leigh, J. S. (1974) Biochemistry 13, 1160-1169], and the regulatory binding site of Aeromonas aminopeptidase [Prescott, J. M., Wagner, F. W., Holmquist, B., & Vallee, B. L. (1985) Biochemistry 24, 5350-5356]. Phospholipase C is so far unique in having two such sites.     

Site-specific substituted cobalt(II) horse liver alcohol dehydrogenases. Preparation and characterization in solution, crystalline and immobilized state.

The specific substitution, using highly selective techniques, of catalytic and/or noncatalytic zinc ions by cobaltous ions in horse liver alcohol dehydrogenase (EC 1.1.1.1) has been studied with dissolved, crystalline and agarose-immobilised enzyme, in order to examine the effect of protein structure on the specificity of the metal exchange. The different binding sites can be clearly distinguished by the absorption spectra of their cobalt derivatives. In solution an anaerobic column chromatographic method made it possible to exchange half of the zinc in the enzyme by cobalt ions in a much shorter time than previous procedures. By raising the temperature in the exchange step, even the slowly exchanging zinc ions were substituted by cobalt, yielding products similar to cobalt alcohol dehydrogenases described earlier. Treatment of crystal suspensions of the enzyme with chelating agents (preferentially dipicolinic acid) gave an inactive protein with two zinc ions remaining bound. The enzyme could be reactivated by treatment of the crystalline protein with 5 mM zinc or cobaltous ions or by dialysis of dissolved inactive protein against 20 microM zinc or 1 mM cobaltous ions. Higher metal concentrations led to denaturation but the inactive protein could be crystallized from solution and then reactivated completely at higher metal concentrations. The preparation and absorption spectrum show that cobalt is bound specifically at the catalytic sites. Since metal substitution at these sites critically depends on the maintenance of the correct tertiary and quaternary structure, these must be preserved in the crystal lattice and partially altered in solution when the catalytic zinc ions are removed (or when excess of metal ions is applied), thus demonstrating the structure-stabilizing role of the catalytic metal ions. The enzyme immobilised on agarose, with unchanged content of active sites [Schneider-Bernl?hr et al. (1978) Eur. J. Biochem. 41, 475--484], was treated like the crystal suspensions. Although half of the zinc was removed, some activity remained. After reactivation with cobaltous ions, a loss of about 30% active sites was measured. Thus the apparently homogenous bound enzyme was rather heterogeneous in the properties of its catalytic metal binding sites. These results are taken as further proof for the dependence of the metal substitution on the proper tertiary and quaternary structure which is strained by multiple interactions in the covalently immobilised enzyme.     

The extracellular regions of PSMA and the transferrin receptor contain an aminopeptidase domain: implications for drug design

The Aeromonas proteolytica aminopeptidase (AMP), Pseudomonas sp. (RS-16) carboxypeptidase G2 (CPG2), and Streptomyces griseus aminopeptidase (SGAP) are zinc dependent proteolytic enzymes with cocatalytic zinc ion centers and a conserved aminopeptidase fold. A BLAST search with the sequence of the solved AMP structure indicated that a similar domain could be found in prostate-specific membrane antigen (PSMA) and the transferrin receptor (TfR). When the PSMA or TfR sequence was input into the THREADER program, the top structural matches were SGAP and AMP confirming that these are structurally conserved domains. Optimal sequence alignment of PSMA and TfR using the known three-dimensional structures of AMP, CPG2, and SGAP shows that the critical amino acids involved in forming the catalytic pocket are conserved in PSMA but absent in the TfR. The specificity pocket in AMP is formed from four aromatic side chains and the equivalent region in CPG2/PSMA has a changed sequence pattern. Since CPG2 and PSMA are folate hydrolases, the changed specificity pocket leaves space to accommodate the large pteroate moiety of folic acid. In contrast, no enzyme function has been ascribed to the TfR.