Secondary literature sources for PepX_N
The following references were automatically generated.
- Iyer S et al.
- Crystal structure of X-prolyl aminopeptidase from Caenorhabditis elegans: A cytosolic enzyme with a di-nuclear active site.
- FEBS Open Bio. 2015; 5: 292-302
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Eukaryotic aminopeptidase P1 (APP1), also known as X-prolyl aminopeptidase (XPNPEP1) in human tissues, is a cytosolic exopeptidase that preferentially removes amino acids from the N-terminus of peptides possessing a penultimate N-terminal proline residue. The enzyme has an important role in the catabolism of proline containing peptides since peptide bonds adjacent to the imino acid proline are resistant to cleavage by most peptidases. We show that recombinant and catalytically active Caenorhabditis elegans APP-1 is a dimer that uses dinuclear zinc at the active site and, for the first time, we provide structural information for a eukaryotic APP-1 in complex with the inhibitor, apstatin. Our analysis reveals that C. elegans APP-1 shares similar mode of substrate binding and a common catalytic mechanism with other known X-prolyl aminopeptidases.
- Weaver J, Watts T, Li P, Rye HS
- Structural basis of substrate selectivity of E. coli prolidase.
- PLoS One. 2014; 9: 111531-111531
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Prolidases, metalloproteases that catalyze the cleavage of Xaa-Pro dipeptides, are conserved enzymes found in prokaryotes and eukaryotes. In humans, prolidase is crucial for the recycling of collagen. To further characterize the essential elements of this enzyme, we utilized the Escherichia coli prolidase, PepQ, which shares striking similarity with eukaryotic prolidases. Through structural and bioinformatic insights, we have extended previous characterizations of the prolidase active site, uncovering a key component for substrate specificity. Here we report the structure of E. coli PepQ, solved at 2.0 A resolution. The structure shows an antiparallel, dimeric protein, with each subunit containing N-terminal and C-terminal domains. The C-terminal domain is formed by the pita-bread fold typical for this family of metalloproteases, with two Mg(II) ions coordinated by five amino-acid ligands. Comparison of the E. coli PepQ structure and sequence with homologous structures and sequences from a diversity of organisms reveals distinctions between prolidases from Gram-positive eubacteria and archaea, and those from Gram-negative eubacteria, including the presence of loop regions in the E. coli protein that are conserved in eukaryotes. One such loop contains a completely conserved arginine near the catalytic site. This conserved arginine is predicted by docking simulations to interact with the C-terminus of the substrate dipeptide. Kinetic analysis using both a charge-neutralized substrate and a charge-reversed variant of PepQ support this conclusion, and allow for the designation of a new role for this key region of the enzyme active site.
- Sakamoto Y et al.
- S46 peptidases are the first exopeptidases to be members of clan PA.
- Sci Rep. 2014; 4: 4977-4977
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The dipeptidyl aminopeptidase BII (DAP BII) belongs to a serine peptidase family, S46. The amino acid sequence of the catalytic unit of DAP BII exhibits significant similarity to those of clan PA endopeptidases, such as chymotrypsin. However, the molecular mechanism of the exopeptidase activity of family S46 peptidase is unknown. Here, we report crystal structures of DAP BII. DAP BII contains a peptidase domain including a typical double beta-barrel fold and previously unreported alpha-helical domain. The structures of peptide complexes revealed that the alpha-helical domain covers the active-site cleft and the side chain of Asn330 in the domain forms hydrogen bonds with the N-terminus of the bound peptide. These observations indicate that the alpha-helical domain regulates the exopeptidase activity of DAP BII. Because S46 peptidases are not found in mammals, we expect that our study will be useful for the design of specific inhibitors of S46 peptidases from pathogens.
- Oda K
- New families of carboxyl peptidases: serine-carboxyl peptidases and glutamic peptidases.
- J Biochem. 2012; 151: 13-25
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Peptidases or proteinases are now classified into seven families based on the nature of the catalytic residues [MEROPS-the peptidase database (http://merops.sanger.ac.uk/)]. They are aspartic- (first described in 1993), cysteine- (1993), serine- (1993) metallo- (1993), threonine- (1997), glutamic- (2004) and asparagine-peptidase (2010). By using an S-PI (pepstatin Ac) as a probe, a new subfamily of serine peptidase, serine-carboxyl peptidase (sedolisin) was discovered in 2001. In addition, the sixth family of peptidase, glutamic peptidase (eqolisin) was also discovered in 2004. The former peptidase is widely distributed in nature from archea to mammals, including humans. One of these enzymes is related to a human fatal hereditable disease, Batten disease. In contrast, the distribution of the latter peptidases is limited, with most of them found in human or plant pathogenic fungi. One such enzyme was isolated from a fungal infection in an HIV-infected patient. In this review, the background of the findings, and crystal structures, catalytic mechanisms, substrates specificities and distribution of the new peptidase families are described.
- Rockel B, Kopec KO, Lupas AN, Baumeister W
- Structure and function of tripeptidyl peptidase II, a giant cytosolic protease.
- Biochim Biophys Acta. 2012; 1824: 237-45
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Tripeptidyl peptidase II is the largest known eukaryotic peptidase. It has been described as a multi-purpose peptidase, which, in addition to its house-keeping function in intracellular protein degradation, plays a role in several vital cellular processes such as antigen processing, apoptosis, or cell division, and is involved in diseases like muscle wasting, obesity, and in cancer. Biochemical studies and bioinformatics have identified TPPII as a subtilase, but its structure is very unusual: it forms a large homooligomeric complex (6 MDa) with a spindle-like shape. Recently, the high-resolution structure of TPPII homodimers (300 kDa) was solved and a hybrid structure of the holocomplex built of 20 dimers was obtained by docking it into the EM-density. Here, we summarize our current knowledge about TPPII with a focus on structural aspects. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.
- Vukelic B et al.
- Reactive cysteine in the active-site motif of Bacteroides thetaiotaomicron dipeptidyl peptidase III is a regulatory residue for enzyme activity.
- Biol Chem. 2012; 393: 37-46
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Dipeptidyl peptidase III (DPP III), a member of the metallopeptidase family M49, was considered as an exclusively eukaryotic enzyme involved in intracellular peptide catabolism and pain modulation. In 2003, new data on genome sequences revealed the first prokaryotic orthologs, which showed low sequence similarity to eukaryotic ones and a cysteine (Cys) residue in the zinc-binding motif HEXXGH. Here we report the cloning and heterologous expression of DPP III from the human gut symbiont Bacteroides thetaiotaomicron. The catalytic efficiency of bacterial DPP III for preferred synthetic substrate hydrolysis was very similar to that of the human host enzyme. Substitution of Cys450 from the active-site motif by serine did not substantially change the enzymatic activity. However, this residue was wholly responsible for the inactivation effect of sulfhydryl reagents. Molecular modeling indicated seven basic amino acid residues in the local environment of Cys450 as a possible cause for its high reactivity. Sequence analysis of 81 bacterial M49 peptidases showed conservation of the HECLGH motif in 68 primary structures with the majority of proteins lacking an active-site Cys originated from aerobic bacteria. Data obtained suggest that Cys450 of B. thetaiotaomicron DPP III is a regulatory residue for the enzyme activity.
- Tang HK et al.
- Role of a propeller loop in the quaternary structure and enzymatic activity of prolyl dipeptidases DPP-IV and DPP9.
- FEBS Lett. 2011; 585: 3409-14
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The dipeptidyl peptidase (DPP) family members, including DPP-IV, DPP8, DPP9 and others, cleave the peptide bond after the penultimate proline residue and are drug target rich. The dimerization of DPP-IV is required for its activity. A propeller loop located at the dimer interface is highly conserved within the family. Here we carried out site-directed mutagenesis on the loop of DPPIV and identified several residues important for dimer formation and enzymatic activity. Interestingly, the corresponding residues on DPP9 have a different impact whereby the mutations decrease activity without changing dimerization. Thus the propeller loop seems to play a varying role in different DPPs.
- Pitman MR, Menz RI, Abbott CA
- Hydrophilic residues surrounding the S1 and S2 pockets contribute to dimerisation and catalysis in human dipeptidyl peptidase 8 (DP8).
- Biol Chem. 2010; 391: 959-72
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Dipeptidyl peptidase (DP) 8 belongs to the dipeptidyl peptidase IV gene family. DP8 has been implicated in immune function and asthma, although its biological function is yet unknown. Structures of the homologs, fibroblast activation protein (FAP) and DPIV, are known but the DP8 structure is yet to be resolved. To help characterise the DP8 substrate pocket, mutants of residues lining the pocket were produced at DP8(D772), DP8(Y315), DP8(H434) and DP8(D435) and assessed by substrate kinetics and size-exclusion chromatography. Mutations of DP8(D772A/E/S/V) affected catalysis but did not confer endopeptidase activity. Mutations of DP8(H434F), DP8(D435F) and DP8(Y315F) reduced catalytic activity. Furthermore, mutations to DP8(D772A/E/S/V), DP8(H434F), DP8(D435F) and DP8(Y315F) affected dimer stabilisation. Homology modelling of DP8 using DPIV and FAP crystal structures suggested that DP8(D772), DP8(H434) and DP8(D435) were located at the edge of the S2 catalytic pocket, contributing to the junction between the alpha-beta hydrolase and beta-propeller domains. This study provides insights into how the DP8 substrate pocket and dimer interface differ from DPIV and FAP which could be utilised for designing more selective DP8 inhibitors.
- Inagaki N et al.
- Molecular properties of the glucosaminidase AcmA from Lactococcus lactis MG1363: mutational and biochemical analyses.
- Gene. 2009; 447: 61-71
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The major autolysin AcmA of Lactococcus lactis ssp. cremoris MG1363 is a modular protein consisting of an N-terminal signal sequence, a central enzymatic region (glu(acma) as a glucosaminidase), and a C-terminal cell-recognition domain (LysM123). glu(acma) (about 160 amino acids) belongs to the glycoside hydrolase (GH) 73 family, and the two acidic residues E128 and D153 have been thought to be catalytically important. In this study, amino-acid substitution analysis of AcmA was first carried out in the Escherichia coli system. Point mutations E94A, E94Q, E128A, D153A, and Y191A markedly reduced cell-lytic activity (3.8%, 1.1%, 4.2%, 4.8%, and 2.4%, respectively), whereas E128Q and D153N retained significant residual activities (32.1% and 44.0%, respectively). On the other hand, Y191F and Y191W mutations retained high activities (66.2% and 46.0%, respectively). These results showed that E94 (rather than E128 and D153) and the aromatic residue Y191 probably play important roles in catalysis of AcmA. Together with mutational analysis of another GH73 glucoaminidase Glu(atlwm) from the Staphylococcus warneri M autolysin Atl(WM), these results suggested that the GH73 members cleave a glycosidic bond via a substrate-assisted mechanism, as postulated in the GH20 members. AcmA and Glu(atlwm) were purified from E. coli recombinant cells, and their enzymatic properties were studied.
- Zhang Y et al.
- Biochemical and structural characterization of the intracellular mannanase AaManA of Alicyclobacillus acidocaldarius reveals a novel glycoside hydrolase family belonging to clan GH-A.
- J Biol Chem. 2008; 283: 31551-8
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An intracellular mannanase was identified from the thermoacidophile Alicyclobacillus acidocaldarius Tc-12-31. This enzyme is particularly interesting, because it shows no significant sequence similarity to any known glycoside hydrolase. Gene cloning, biochemical characterization, and structural studies of this novel mannanase are reported in this paper. The gene consists of 963 bp and encodes a 320-amino acid protein, AaManA. Based on its substrate specificity and product profile, AaManA is classified as an endo-beta-1,4-mannanase that is capable of transglycosylation. Kinetic analysis studies revealed that the enzyme required at least five subsites for efficient hydrolysis. The crystal structure at 1.9 angstroms resolution showed that AaManA adopted a (beta/alpha)8-barrel fold. Two catalytic residues were identified: Glu151 at the C terminus of beta-stand beta4 and Glu231 at the C terminus of beta7. Based on the structure of the enzyme and evidence of its transglycosylation activity, AaManA is placed in clan GH-A. Superpositioning of its structure with that of other clan GH-A enzymes revealed that six of the eight GH-A key residues were functionally conserved in AaManA, with the exceptions being residues Thr95 and Cys150. We propose a model of substrate binding in AaManA in which Glu282 interacts with the axial OH-C(2) in-2 subsites. Based on sequence comparisons, the enzyme was assigned to a new glycoside hydrolase family (GH113) that belongs to clan GH-A.
- Nakajima Y et al.
- Dipeptidyl aminopeptidase IV from Stenotrophomonas maltophilia exhibits activity against a substrate containing a 4-hydroxyproline residue.
- J Bacteriol. 2008; 190: 7819-29
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The crystal structure of dipeptidyl aminopeptidase IV from Stenotrophomonas maltophilia was determined at 2.8-A resolution by the multiple isomorphous replacement method, using platinum and selenomethionine derivatives. The crystals belong to space group P4(3)2(1)2, with unit cell parameters a = b = 105.9 A and c = 161.9 A. Dipeptidyl aminopeptidase IV is a homodimer, and the subunit structure is composed of two domains, namely, N-terminal beta-propeller and C-terminal catalytic domains. At the active site, a hydrophobic pocket to accommodate a proline residue of the substrate is conserved as well as those of mammalian enzymes. Stenotrophomonas dipeptidyl aminopeptidase IV exhibited activity toward a substrate containing a 4-hydroxyproline residue at the second position from the N terminus. In the Stenotrophomonas enzyme, one of the residues composing the hydrophobic pocket at the active site is changed to Asn611 from the corresponding residue of Tyr631 in the porcine enzyme, which showed very low activity against the substrate containing 4-hydroxyproline. The N611Y mutant enzyme was generated by site-directed mutagenesis. The activity of this mutant enzyme toward a substrate containing 4-hydroxyproline decreased to 30.6% of that of the wild-type enzyme. Accordingly, it was considered that Asn611 would be one of the major factors involved in the recognition of substrates containing 4-hydroxyproline.
- Rummey C, Metz G
- Homology models of dipeptidyl peptidases 8 and 9 with a focus on loop predictions near the active site.
- Proteins. 2007; 66: 160-71
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Dipeptidyl peptidase 4 (DP4) inhibitors are currently under intensive investigation in late-stage clinical trials as a treatment for type II diabetes. Lack of selectivity toward the related enzymes DP8 and DP9 has recently emerged as a possible source of drug-induced toxicity. Unlike DP4, X-ray structures of DP8 and DP9 are not yet available. As an aid to understanding the structural basis for selectivity, the authors have constructed homology models of DP8 and DP9 based on the X-ray coordinates of DP4. Accurate sequence alignment reveals common structural features indicative for a well-preserved overall fold comprising two domains, namely, a hydrolase domain and a so-called beta-propeller, which together form the active site deeply buried within the protein. The conformation of two loops inside this deep cavity is particularly relevant for the active sites. The authors used a published protocol for loop prediction based on conformational sampling and energy analysis to generate plausible solutions for these two loops. The predictive power of the approach was successfully evaluated for the template protein DP4 and two additional known structures from the same protein family, namely, FAP and DPX. The authors also show that inclusion of the covalent ligand NVP-728 greatly enhances the refinement. Based on the established evaluation protocol, the corresponding loops of DP8 and DP9 were predicted and the resulting active sites were compared with DP4. In particular, the authors conclude that differences in the P2-pocket are relevant for the design of selective DP4 inhibitors. The loss of key interactions in DP8 and DP9 as predicted from their models is consistent with the selectivity profile of the DP4 clinical candidate MK-431.
- Meadows SA et al.
- Ala657 and conserved active site residues promote fibroblast activation protein endopeptidase activity via distinct mechanisms of transition state stabilization.
- Biochemistry. 2007; 46: 4598-605
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Fibroblast activation protein (FAP) and dipeptidyl peptidase-4 (DPP-4) are highly homologous serine proteases of the prolyl peptidase family and therapeutic targets for cancer and diabetes, respectively. Both proteases display dipeptidyl peptidase activity, but FAP alone has endopeptidase activity. FAP Ala657, which corresponds to DPP-4 Asp663, is important for endopeptidase activity; however, its specific role remains unclear, and it is unknown whether conserved DPP-4 substrate binding residues support FAP endopeptidase activity. Using site-directed mutagenesis and kinetic analyses, we show here that Ala657 and five conserved active site residues (Arg123, Glu203, Glu204, Tyr656, and Asn704) promote FAP endopeptidase activity via distinct mechanisms of transition state stabilization (TSS). The conserved residues provide marked TSS energy for both endopeptidase and dipeptidyl peptidase substrates, and structural modeling supports their function in binding both substrates. Ala657 also stabilizes endopeptidase substrate binding and additionally dictates FAP reactivity with transition state inhibitors, allowing tight interaction with tetrahedral intermediate analogues but not acyl-enzyme analogues. Conversely, DPP-4 Asp663 stabilizes dipeptidyl peptidase substrate binding and permits tight interaction with both transition state analogues. Structural modeling suggests that FAP Ala657 and DPP-4 Asp663 confer their contrasting effects on TSS by modulating the conformation of conserved residues FAP Glu204 and DPP-4 Glu206. FAP therefore requires the combined function of Ala657 and the conserved residues for endopeptidase activity.
- Cui Z, Maruyama Y, Mikami B, Hashimoto W, Murata K
- Crystal structure of glycoside hydrolase family 78 alpha-L-Rhamnosidase from Bacillus sp. GL1.
- J Mol Biol. 2007; 374: 384-98
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alpha-L-Rhamnosidase (EC 3.2.1.40) catalyzes the hydrolytic release of rhamnose from polysaccharides and glycosides. Bacillus sp. GL1 alpha-L-rhamnosidase (RhaB), a member of glycoside hydrolase (GH) family 78, is responsible for degrading the bacterial biofilm gellan, and also functions as a debittering agent for citrus fruit in the food and beverage industries through the release of rhamnose from plant glycoside, naringin. The X-ray crystal structure of RhaB was determined by single-wavelength anomalous diffraction using a selenomethionine derivative and refined at 1.9 A resolution with a final R-factor of 18.2%. As is seen in the homodimeric form of the active enzyme, the structure of RhaB in crystal packing is a homodimer containing 1908 amino acids (residues 3-956), 43 glycerol molecules, four calcium ions, and 1755 water molecules. The overall structure consists of five domains, four of which are beta-sandwich structures designated as domains N, D1, D2, and C, and an (alpha/alpha)(6)-barrel structure designated as domain A. Structural comparison by DALI showed that RhaB shares its highest level of structural similarity with chitobiose phosphorylase (Z score of 25.3). The structure of RhaB in complex with the reaction product rhamnose (inhibitor constant, K(i)=1.8 mM) was also determined and refined at 2.1 A with a final R-factor of 19.5%. Rhamnose is bound to the deep cleft of the (alpha/alpha)(6)-barrel domain, as is seen in the clan-L GHs. Several negatively charged residues, such as Asp567, Glu572, Asp579, and Glu841, conserved in GH family 78 enzymes, interact with rhamnose, and RhaB mutants of these residues have drastically reduced enzyme activity, indicating that the residues are crucial for enzyme catalysis and/or substrate binding. To our knowledge, this is the first report on the determination of the crystal structure of alpha-L-rhamnosidase and identification of its clan-L (alpha/alpha)(6)-barrel as a catalytic domain.
- Pitman MR, Menz RI, Abbott CA
- Prediction of dipeptidyl peptidase (DP) 8 structure by homology modelling.
- Adv Exp Med Biol. 2006; 575: 33-42
- Hiromoto T, Fujiwara S, Hosokawa K, Yamaguchi H
- Crystal structure of 3-hydroxybenzoate hydroxylase from Comamonas testosteroni has a large tunnel for substrate and oxygen access to the active site.
- J Mol Biol. 2006; 364: 878-96
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The 3-hydroxybenzoate hydroxylase (MHBH) from Comamonas testosteroni KH122-3s is a single-component flavoprotein monooxygenase, a member of the glutathione reductase (GR) family. It catalyzes the conversion of 3-hydroxybenzoate to 3,4-dihydroxybenzoate with concomitant requirements for equimolar amounts of NADPH and molecular oxygen. The production of dihydroxy-benzenoid derivative by hydroxylation is the first step in the aerobic degradation of various phenolic compounds in soil microorganisms. To establish the structural basis for substrate recognition, the crystal structure of MHBH in complex with its substrate was determined at 1.8 A resolution. The enzyme is shown to form a physiologically active homodimer with crystallographic 2-fold symmetry, in which each subunit consists of the first two domains comprising an active site and the C-terminal domain involved in oligomerization. The protein fold of the catalytic domains and the active-site architecture, including the FAD and substrate-binding sites, are similar to those of 4-hydroxybenzoate hydroxylase (PHBH) and phenol hydroxylase (PHHY), which are members of the GR family, providing evidence that the flavoprotein aromatic hydroxylases share similar catalytic actions for hydroxylation of the respective substrates. Structural comparison of MHBH with the homologous enzymes suggested that a large tunnel connecting the substrate-binding pocket to the protein surface serves for substrate transport in this enzyme. The internal space of the large tunnel is distinctly divided into hydrophilic and hydrophobic regions. The characteristically stratified environment in the tunnel interior and the size of the entrance would allow the enzyme to select its substrate by amphiphilic nature and molecular size. In addition, the structure of the Xe-derivative at 2.5 A resolution led to the identification of a putative oxygen-binding site adjacent to the substrate-binding pocket. The hydrophobic nature of the xenon-binding site extends to the solvent through the tunnel, suggesting that the tunnel could be involved in oxygen transport.
- Pirruccello M et al.
- A dimeric kinase assembly underlying autophosphorylation in the p21 activated kinases.
- J Mol Biol. 2006; 361: 312-26
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The p21-activated kinases (PAKs) are serine/threonine kinases that are involved in a wide variety of cellular functions including cytoskeletal motility, apoptosis, and cell cycle regulation. PAKs are inactivated by blockage of the active site of the kinase domain by an N-terminal regulatory domain. GTP-bound forms of Cdc42 and Rac bind to the regulatory domain and displace it, thereby allowing phosphorylation of the kinase domain and maximal activation. A key step in the activation process is the phosphorylation of the activation loop of one PAK kinase domain by another, but little is known about the underlying recognition events that make this phosphorylation specific. We show that the phosphorylated kinase domain of PAK2 dimerizes in solution and that this association is prevented by addition of a substrate peptide. We have identified a crystallographic dimer in a previously determined crystal structure of activated PAK1 in which two kinase domains are arranged face to face and interact through a surface on the large lobe of the kinase domain that is exposed upon release of the auto-inhibitory domain. The crystallographic dimer is suggestive of an engagement that mediates trans-autophosphorylation. Mutations at the predicted dimerization interface block dimerization and reduce the rate of autophosphorylation, supporting the role of this interface in PAK activation.
- Chen T, Ajami K, McCaughan GW, Gai WP, Gorrell MD, Abbott CA
- Molecular characterization of a novel dipeptidyl peptidase like 2-short form (DPL2-s) that is highly expressed in the brain and lacks dipeptidyl peptidase activity.
- Biochim Biophys Acta. 2006; 1764: 33-43
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DPL2 (DPP10) found at chromosome 2q14.1 is a member of the dipeptidyl peptidase IV (DPIV) gene family. Here we characterize a novel short DPL2 isoform (DPL2-s), a 789-amino acid protein, that differs from the previously described long DPL2 isoform (DPL2-l) at the N-terminal cytoplasmic domain by 13 amino acids. The two DPL2 isoforms use alternate first exons. DPL2 mRNA was expressed mainly in the brain and pancreas. Multiple forms of recombinant DPL2-s protein were observed in 293T cells, having mobilities 96 kDa, 100 kDa, and approximately 250 kDa which may represent soluble DPL2, transmembrane DPL2 and multimeric DPL2 respectively. DPL2 is glycosylated as a band shift is observed following PNGase F deglycosylation. DPL2-s was expressed primarily on the cell surface of transfected 293T and PC12 cells. DPL2-s exhibits high sequence homology with other DPIV peptidases, but lacks a catalytic serine residue and lacks dipeptidyl peptidase activity. Substitutions of Gly(644)-->Ser, Lys(643)Gly(644)-->TrpSer, or Asp(561)Lys(643)Gly(644)-->TyrTrpSer in the catalytic motif did not confer dipeptidyl peptidase activity upon DPL2-s. Thus, although DPL2 is similar in structure and sequence to the other dipeptidyl peptidases, it lacks vital residues required to confer dipeptidyl peptidase activity and has instead evolved features that enable it to act as an important component of voltage-gated potassium channels.
- Rigolet P, Xi XG, Rety S, Chich JF
- The structural comparison of the bacterial PepX and human DPP-IV reveals sites for the design of inhibitors of PepX activity.
- FEBS J. 2005; 272: 2050-9
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X-prolyl dipeptidyl aminopeptidases (X-PDAP) are enzymes catalysing the release of dipeptides from the amino termini of polypeptides containing a proline or an alanine at the penultimate position. Involved in various mammalian regulation processes, as well as in chronic human diseases, they have been proposed to play a role in pathogenicity for Streptococci. We compared the structure of X-PDAP from Lactococcus lactis (PepX) with its human counterpart DPP-IV. Despite very different overall folds, the residues most implicated for X-PDAP activity are conserved in the same positions and orientations in both enzymes, thus defining a structural signature for the X-PDAP specificity that crosses the species frontiers of evolution. Starting from this observation, we tested some inhibitors of DPP-IV on PepX activity, for which no specific inhibitor is known. We thus found that PepX was highly sensitive to valine-pyrrolidide with a KI of 9.3 microm, close to that reported in DPP-IV inhibition. We finally used the structure of PepX from L. lactis as a template for computer-based homology modeling of PepX from the pathogenic Streptococcus gordonii. Docking simulations of valine-pyrrolidide into the active site of PepX led to the identification of key residues for a rational drug design against PepX from Streptococci. These results could have applications in human health giving new perspectives to the struggle against pathogens.
- Stamler R, Kappe G, Boelens W, Slingsby C
- Wrapping the alpha-crystallin domain fold in a chaperone assembly.
- J Mol Biol. 2005; 353: 68-79
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Small heat shock proteins (sHsps) are oligomers that perform a protective function by binding denatured proteins. Although ubiquitous, they are of variable sequence except for a C-terminal approximately 90-residue "alpha-crystallin domain". Unlike larger stress response chaperones, sHsps are ATP-independent and generally form polydisperse assemblies. One proposed mechanism of action involves these assemblies breaking into smaller subunits in response to stress, before binding unfolding substrate and reforming into larger complexes. Two previously solved non-metazoan sHsp multimers are built from dimers formed by domain swapping between the alpha-crystallin domains, adding to evidence that the smaller subunits are dimers. Here, the 2.5A resolution structure of an sHsp from the parasitic flatworm Taenia saginata Tsp36, the first metazoan crystal structure, shows a new mode of dimerization involving N-terminal regions, which differs from that seen for non-metazoan sHsps. Sequence differences in the alpha-crystallin domains between metazoans and non-metazoans are critical to the different mechanism of dimerization, suggesting that some structural features seen for Tsp36 may be generalized to other metazoan sHsps. The structure also indicates scope for flexible assembly of subunits, supporting the proposed process of oligomer breakdown, substrate binding and reassembly as the chaperone mechanism. It further shows how sHsps can bind coil and secondary structural elements by wrapping them around the alpha-crystallin domain. The structure also illustrates possible roles for conserved residues associated with disease, and suggests a mechanism for the sHsp-related pathogenicity of some flatworm infections. Tsp36, like other flatworm sHsps, possesses two divergent sHsp repeats per monomer. Together with the two previously solved structures, a total of four alpha-crystallin domain structures are now available, giving a better definition of domain boundaries for sHsps.
- Geueke B, Namoto K, Seebach D, Kohler HP
- A novel beta-peptidyl aminopeptidase (BapA) from strain 3-2W4 cleaves peptide bonds of synthetic beta-tri- and beta-dipeptides.
- J Bacteriol. 2005; 187: 5910-7
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A novel bacterial strain that was capable of growing on the beta-tripeptide H-betahVal-betahAla-betahLeu-OH as the sole carbon and nitrogen source was isolated from an enrichment culture. On the basis of physiological characterization, partial 16S rRNA sequencing, and fatty acid analysis, strain 3-2W4 was identified as a member of the family Sphingomonadaceae. Growth on the beta-tripeptide and the beta-dipeptide H-betahAla-betahLeu-OH was observed, and emerging metabolites were characterized. Small amounts of a persisting metabolite, the N-acetylated beta-dipeptide, were identified in both media. According to dissolved organic carbon measurements, 74 to 80% of the available carbon was dissimilated. The beta-peptide-degrading enzyme was purified from the crude cell extract of cells from strain 3-2W4 grown on complex medium. The enzyme was composed of two subunits, and the N-terminal sequences of both were determined. With this information, it was possible to identify the complete nucleotide sequence and to deduce the primary structure of the gene bapA. The gene encoded a beta-peptidyl aminopeptidase (BapA) of 402 amino acids that was synthesized as preprotein with a signal sequence of 29 amino acids. The enzyme was cleaved into two subunits (residues 30 to 278 and 279 to 402). It belonged to the N-terminal nucleophile (Ntn) hydrolase superfamily.
- Cheung YY, Lam SY, Chu WK, Allen MD, Bycroft M, Wong KB
- Crystal structure of a hyperthermophilic archaeal acylphosphatase from Pyrococcus horikoshii--structural insights into enzymatic catalysis, thermostability, and dimerization.
- Biochemistry. 2005; 44: 4601-11
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Acylphosphatases catalyze the hydrolysis of the carboxyl-phosphate bond in acyl phosphates. Although acylphosphatase-like sequences are found in all three domains of life, no structure of acylphosphatase has been reported for bacteria and archaea so far. Here, we report the characterization of enzymatic activities and crystal structure of an archaeal acylphosphatase. A putative acylphosphatase gene (PhAcP) was cloned from the genomic DNA of Pyrococcus horikoshii and was expressed in Escherichia coli. Enzymatic parameters of the recombinant PhAcP were measured using benzoyl phosphate as the substrate. Our data suggest that, while PhAcP is less efficient than other mammalian homologues at 25 degrees C, the thermophilic enzyme is fully active at the optimal growth temperature (98 degrees C) of P. horikoshii. PhAcP is extremely stable; its apparent melting temperature was 111.5 degrees C and free energy of unfolding at 25 degrees C was 54 kJ mol(-)(1). The 1.5 A crystal structure of PhAcP adopts an alpha/beta sandwich fold that is common to other acylphosphatases. PhAcP forms a dimer in the crystal structure via antiparallel association of strand 4. Structural comparison to mesophilic acylphosphatases reveals significant differences in the conformation of the L5 loop connecting strands 4 and 5. The extreme thermostability of PhAcP can be attributed to an extensive ion-pair network consisting of 13 charge residues on the beta sheet of the protein. The reduced catalytic efficiency of PhAcP at 25 degrees C may be due to a less flexible active-site residue, Arg20, which forms a salt bridge to the C-terminal carboxyl group. New insights into catalysis were gained by docking acetyl phosphate to the active site of PhAcP.
- Zhang G, Dai J, Wang L, Dunaway-Mariano D, Tremblay LW, Allen KN
- Catalytic cycling in beta-phosphoglucomutase: a kinetic and structural analysis.
- Biochemistry. 2005; 44: 9404-16
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Lactococcus lactis beta-phosphoglucomutase (beta-PGM) catalyzes the interconversion of beta-d-glucose 1-phosphate (beta-G1P) and beta-d-glucose 6-phosphate (G6P), forming beta-d-glucose 1,6-(bis)phosphate (beta-G16P) as an intermediate. Beta-PGM conserves the core domain catalytic scaffold of the phosphatase branch of the HAD (haloalkanoic acid dehalogenase) enzyme superfamily, yet it has evolved to function as a mutase rather than as a phosphatase. This work was carried out to identify the structural basis underlying this diversification of function. In this paper, we examine beta-PGM activation by the Mg(2+) cofactor, beta-PGM activation by Asp8 phosphorylation, and the role of cap domain closure in substrate discrimination. First, the 1.90 A resolution X-ray crystal structure of the Mg(2+)-beta-PGM complex is examined in the context of previously reported structures of the Mg(2+)-alpha-d-galactose-1-phosphate-beta-PGM, Mg(2+)-phospho-beta-PGM, and Mg(2+)-beta-glucose-6-phosphate-1-phosphorane-beta-PGM complexes to identify conformational changes that occur during catalytic turnover. The essential role of Asp8 in nucleophilic catalysis was confirmed by demonstrating that the D8A and D8E mutants are devoid of catalytic activity. Comparison of the ligands to Mg(2+) in the different complexes shows that a single Mg(2+) coordination site must alternatively accommodate water, phosphate, and the phosphorane intermediate during catalytic turnover. Limited involvement of the HAD family metal-binding loop in Mg(2+) anchoring in beta-PGM is consistent with the relatively loose binding indicated by the large K(m) for Mg(2+) activation (270 +/- 20 microM) and with the retention of activity found in the E169A/D170A double loop mutant. Comparison of the relative positions of cap and core domains in the different complexes indicated that interaction of cap domain Arg49 with the "nontransferring" phosphoryl group of the substrate ligand might stabilize the cap-closed conformation, as required for active site desolvation and alignment of Asp10 for acid-base catalysis. Kinetic analyses of the specificity of beta-PGM toward phosphoryl group donors and the specificity of phospho-beta-PGM toward phosphoryl group acceptors were carried out. The results support a substrate induced-fit mechanism of beta-PGM catalysis, which allows phosphomutase activity to dominate over the intrinsic phosphatase activity. Last, we present evidence that the autophosphorylation of beta-PGM by the substrate beta-G1P accounts for the origin of phospho-beta-PGM in the cell.
- Mori S, Nirasawa S, Komba S, Kasumi T
- Characterization and kinetic analysis of enzyme-substrate recognition by three recombinant lactococcal tripeptidases.
- Biochim Biophys Acta. 2005; 1748: 26-34
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Tripeptidases from Lactococcus lactis subsp. lactis (L9PepTR), L. lactis subsp. cremoris (L6PepTR), and L. lactis subsp. hordniae (hTPepTR) were cloned, overexpressed, purified, and characterized. Although these enzymes contained three to seven naturally occurring amino acid differences, both metal-binding and catalytic sites were highly conserved. The k(cat) values of hTPepTR were approximately 1.5- to 2-fold higher than those of L9PepTR, while, for L6PepTR, they were approximately 0.8- to 1.4-times the L9PepTR values. The K(m) of tripeptidase from subsp. lactis (L9PepTR) was considerably larger when glycine was the amino acid located at both the N- and C-terminus of the peptide substrate. In addition, the K(m) values of L9PepTR increased in the following order for YGG, LGG, FGG, SGG, and alpha-aminoisobutyrylglycylglycine, while the k(cat)/K(m) decreased in the same order. These results suggest that the dipole moment and steric hindrance of the N-terminal amino acid side chain may be the most important factors controlling substrate specificity.
- Gorrell MD
- Dipeptidyl peptidase IV and related enzymes in cell biology and liver disorders.
- Clin Sci (Lond). 2005; 108: 277-92
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DP (dipeptidyl peptidase) IV is the archetypal member of its six-member gene family. Four members of this family, DPIV, FAP (fibroblast activation protein), DP8 and DP9, have a rare substrate specificity, hydrolysis of a prolyl bond two residues from the N-terminus. The ubiquitous DPIV glycoprotein has proved interesting in the fields of immunology, endocrinology, haematology and endothelial cell and cancer biology and DPIV has become a novel target for Type II diabetes therapy. The crystal structure shows that the soluble form of DPIV comprises two domains, an alpha/beta-hydrolase domain and an eight-blade beta-propeller domain. The propeller domain contains the ADA (adenosine deaminase) binding site, a dimerization site, antibody epitopes and two openings for substrate access to the internal active site. FAP is structurally very similar to DPIV, but FAP protein expression is largely confined to diseased and damaged tissue, notably the tissue remodelling interface in chronically injured liver. DPIV has a variety of peptide substrates, the best studied being GLP-1 (glucagon-like peptide-1), NPY (neuropeptide Y) and CXCL12. The DPIV family has roles in bone marrow mobilization. The functional interactions of DPIV and FAP with extracellular matrix confer roles for these proteins in cancer biology. DP8 and DP9 are widely distributed and indirectly implicated in immune function. The DPL (DP-like) glycoproteins that lack peptidase activity, DPL1 and DPL2, are brain-expressed potassium channel modulators. Thus the six members of the DPIV gene family exhibit diverse biological roles.
- Lahiri SD, Zhang G, Dai J, Dunaway-Mariano D, Allen KN
- Analysis of the substrate specificity loop of the HAD superfamily cap domain.
- Biochemistry. 2004; 43: 2812-20
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The haloacid dehalogenase (HAD) superfamily includes a variety of enzymes that catalyze the cleavage of substrate C-Cl, P-C, and P-OP bonds via nucleophilic substitution pathways. All members possess the alpha/beta core domain, and many also possess a small cap domain. The active site of the core domain is formed by four loops (corresponding to sequence motifs 1-4), which position substrate and cofactor-binding residues as well as the catalytic groups that mediate the "core" chemistry. The cap domain is responsible for the diversification of chemistry within the family. A tight beta-turn in the helix-loop-helix motif of the cap domain contains a stringently conserved Gly (within sequence motif 5), flanked by residues whose side chains contribute to the catalytic site formed at the domain-domain interface. To define the role of the conserved Gly in the structure and function of the cap domain loop of the HAD superfamily members phosphonoacetaldehyde hydrolase and beta-phosphoglucomutase, the Gly was mutated to Pro, Val, or Ala. The catalytic activity was severely reduced in each mutant. To examine the impact of Gly substitution on loop 5 conformation, the X-ray crystal structure of the Gly50Pro phosphonoacetaldehyde hydrolase mutant was determined. The altered backbone conformation at position 50 had a dramatic effect on the spatial disposition of the side chains of neighboring residues. Lys53, the Schiff Base forming lysine, had rotated out of the catalytic site and the side chain of Leu52 had moved to fill its place. On the basis of these studies, it was concluded that the flexibility afforded by the conserved Gly is critical to the function of loop 5 and that it is a marker by which the cap domain substrate specificity loop can be identified within the amino acid sequence of HAD family members.
- Yu Y et al.
- Crystal structure of human tryptophanyl-tRNA synthetase catalytic fragment: insights into substrate recognition, tRNA binding, and angiogenesis activity.
- J Biol Chem. 2004; 279: 8378-88
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Human tryptophanyl-tRNA synthetase (hTrpRS) produces a full-length and three N terminus-truncated forms through alternative splicing and proteolysis. The shortest fragment that contains the aminoacylation catalytic fragment (T2-hTrpRS) exhibits the most potent angiostatic activity. We report here the crystal structure of T2-hTrpRS at 2.5 A resolution, which was solved using the multi-wavelength anomalous diffraction method. T2-hTrpRS shares a very low sequence homology of 22% with Bacillus stearothermophilus TrpRS (bTrpRS); however, their overall structures are strikingly similar. Structural comparison of T2-hTrpRS with bTrpRS reveals substantial structural differences in the substrate-binding pocket and at the entrance to the pocket that play important roles in substrate binding and tRNA binding. T2-hTrpRS has a wide opening to the active site and adopts a compact conformation similar to the closed conformation of bTrpRS. These results suggest that mammalian and bacterial TrpRSs might use different mechanisms to recognize the substrate. Modeling studies indicate that tRNA binds with the dimeric enzyme and interacts primarily with the connective polypeptide 1 of hTrpRS via its acceptor arm and the alpha-helical domain of hTrpRS via its anticodon loop. Our results also suggest that the angiostatic activity is likely located at the alpha-helical domain, which resembles the short chain cytokines.
- Itoh T, Akao S, Hashimoto W, Mikami B, Murata K
- Crystal structure of unsaturated glucuronyl hydrolase, responsible for the degradation of glycosaminoglycan, from Bacillus sp. GL1 at 1.8 A resolution.
- J Biol Chem. 2004; 279: 31804-12
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Unsaturated glucuronyl hydrolase (UGL) is a novel glycosaminoglycan hydrolase that releases unsaturated d-glucuronic acid from oligosaccharides produced by polysaccharide lyases. The x-ray crystallographic structure of UGL from Bacillus sp. GL1 was first determined by multiple isomorphous replacement (mir) and refined at 1.8 A resolution with a final R-factor of 16.8% for 25 to 1.8 A resolution data. The refined UGL structure consists of 377 amino acid residues and 478 water molecules, four glycine molecules, two dithiothreitol (DTT) molecules, and one 2-methyl-2,4-pentanediol (MPD) molecule. UGL includes an alpha(6)/alpha(6)-barrel, whose structure is found in the six-hairpin enzyme superfamily of an alpha/alpha-toroidal fold. One side of the UGL alpha(6)/alpha(6)-barrel structure consists of long loops containing three short beta-sheets and contributes to the formation of a deep pocket. One glycine molecule and two DTT molecules surrounded by highly conserved amino acid residues in UGLs were found in the pocket, suggesting that catalytic and substrate-binding sites are located in this pocket. The overall UGL structure, with the exception of some loops, very much resembled that of the Bacillus subtilis hypothetical protein Yter, whose function is unknown and which exhibits little amino acid sequence identity with UGL. In the active pocket, residues possibly involved in substrate recognition and catalysis by UGL are conserved in UGLs and Yter. The most likely candidate catalytic residues for glycosyl hydrolysis are Asp(88) and Asp(149). This was supported by site-directed mutagenesis studies in Asp(88) and Asp(149).
- Im YJ et al.
- The active site of a lon protease from Methanococcus jannaschii distinctly differs from the canonical catalytic Dyad of Lon proteases.
- J Biol Chem. 2004; 279: 53451-7
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ATP-dependent Lon proteases catalyze the degradation of various regulatory proteins and abnormal proteins within cells. Methanococcus jannaschii Lon (Mj-Lon) is a homologue of Escherichia coli Lon (Ec-Lon) but has two transmembrane helices within its N-terminal ATPase domain. We solved the crystal structure of the proteolytic domain of Mj-Lon using multiwavelength anomalous dispersion, refining it to 1.9-angstroms resolution. The structure displays an overall fold conserved in the proteolytic domain of Ec-Lon; however, the active site shows uniquely configured catalytic Ser-Lys-Asp residues that are not seen in Ec-Lon, which contains a catalytic dyad. In Mj-Lon, the C-terminal half of the beta4-alpha2 segment is an alpha-helix, whereas it is a beta-strand in Ec-Lon. Consequently, the configurations of the active sites differ due to the formation of a salt bridge between Asp-547 and Lys-593 in Mj-Lon. Moreover, unlike Ec-Lon, Mj-Lon has a buried cavity in the region of the active site containing three water molecules, one of which is hydrogen-bonded to catalytic Ser-550. The geometry and environment of the active site residues in Mj-Lon suggest that the charged Lys-593 assists in lowering the pK(a) of the Ser-550 hydroxyl group via its electrostatic potential, and the water in the cavity acts as a proton acceptor during catalysis. Extensive sequence alignment and comparison of the structures of the proteolytic domains clearly indicate that Lon proteases can be classified into two groups depending on active site configuration and the presence of DGPSA or (D/E)GDSA consensus sequences, as represented by Ec-Lon and Mj-Lon.
- Harris SF, Shiau AK, Agard DA
- The crystal structure of the carboxy-terminal dimerization domain of htpG, the Escherichia coli Hsp90, reveals a potential substrate binding site.
- Structure. 2004; 12: 1087-97
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Hsp90 is a ubiquitous, well-conserved molecular chaperone involved in the folding and stabilization of diverse proteins. Beyond its capacity for general protein folding, Hsp90 influences a wide array of cellular signaling pathways that underlie key biological and disease processes. It has been proposed that Hsp90 functions as a molecular clamp, dimerizing through its carboxy-terminal domain and utilizing ATP binding and hydrolysis to drive large conformational changes including transient dimerization of the amino-terminal and middle domains. We have determined the 2.6 A X-ray crystal structure of the carboxy-terminal domain of htpG, the Escherichia coli Hsp90. This structure reveals a novel fold and that dimerization is dependent upon the formation of a four-helix bundle. Remarkably, proximal to the helical dimerization motif, each monomer projects a short helix into solvent. The location, flexibility, and amphipathic character of this helix suggests that it may play a role in substrate binding and hence chaperone activity.
- Hieta R et al.
- The peptide-substrate-binding domain of human collagen prolyl 4-hydroxylases. Backbone assignments, secondary structure, and binding of proline-rich peptides.
- J Biol Chem. 2003; 278: 34966-74
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The collagen prolyl 4-hydroxylases (C-P4Hs) catalyze the formation of 4-hydroxyproline by the hydroxylation of proline residues in -Xaa-Pro-Gly-sequences. The vertebrate enzymes are alpha 2 beta 2 tetramers in which protein-disulfide isomerase serves as the beta subunit. Two isoforms of the catalytic alpha subunit have been identified and shown to form [alpha(I)]2 beta 2 and [alpha(II)]2 beta 2 tetramers, the type I and type II C-P4Hs, respectively. The peptide-substrate-binding domain of type I C-P4H has been shown to be located between residues 138 and 244 in the 517-residue alpha(I) subunit and to be distinct from the catalytic domain that is located in the C-terminal region. We report here that a recombinant human C-P4H alpha(I) polypeptide Phe144-Ser244 forms a folded domain consisting of five alpha helices and one short beta strand. This structure is quite different from those of other proline-rich peptide-binding modules, which consist mainly of beta strands. Binding of the peptide (Pro-Pro-Gly)2 to this domain caused major chemical shifts in many backbone amide resonances, the residues showing the largest shifts being mainly hydrophobic, including three tyrosines. The Kd values determined by surface plasmon resonance and isothermal titration calorimetry for the binding of several synthetic peptides to the alpha(I) and the corresponding alpha(II) domain were very similar to the Km and Ki values for these peptides as substrates and inhibitors of the type I and type II C-P4H tetramers. The Kd values of the alpha(I) and alpha(II) domains for (Gly-Pro-4Hyp)5 were much higher than those for (Pro-Pro-Gly)5, indicating a marked decrease in the affinity of hydroxylated peptides for the domain. Many characteristic features of the binding of peptides to the type I and type II C-P4H tetramers can thus be explained by the properties of binding to this domain rather than the catalytic domain.
- Thoma R, Loffler B, Stihle M, Huber W, Ruf A, Hennig M
- Structural basis of proline-specific exopeptidase activity as observed in human dipeptidyl peptidase-IV.
- Structure. 2003; 11: 947-59
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Inhibition of dipeptidyl peptidase IV (DPP-IV), the main glucagon-like peptide 1 (GLP1)-degrading enzyme, has been proposed for the treatment of type II diabetes. We expressed and purified the ectodomain of human DPP-IV in Pichia pastoris and determined the X-ray structure at 2.1 A resolution. The enzyme consists of two domains, the catalytic domain, with an alpha/beta hydrolase fold, and a beta propeller domain with an 8-fold repeat of a four-strand beta sheet motif. The beta propeller domain contributes two important functions to the molecule that have not been reported for such structures, an extra beta sheet motif that forms part of the dimerization interface and an additional short helix with a double Glu sequence motif. The Glu motif provides recognition and a binding site for the N terminus of the substrates, as revealed by the complex structure with diprotin A, a substrate with low turnover that is trapped in the tetrahedral intermediate of the reaction in the crystal.
- Padyana AK, Burley SK
- Crystal structure of shikimate 5-dehydrogenase (SDH) bound to NADP: insights into function and evolution.
- Structure. 2003; 11: 1005-13
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The crystal structure of Methanococcus jannaschii shikimate 5-dehydrogenase (MjSDH) bound to the cofactor nicotinamide adenine dinucleotide phosphate (NADP) has been determined at 2.35 A resolution. Shikimate 5-dehydrogenase (SDH) is responsible for NADP-dependent catalysis of the fourth step in shikimate biosynthesis, which is essential for aromatic amino acid metabolism in bacteria, microbial eukaryotes, and plants. The structure of MjSDH is a compact alpha/beta sandwich with two distinct domains, responsible for binding substrate and the NADP cofactor, respectively. A phylogenetically conserved deep cleft on the protein surface corresponds to the enzyme active site. The structure reveals a topologically new domain fold within the N-terminal segment of the polypeptide chain, which binds substrate and supports dimerization. Insights gained from homology modeling and sequence/structure comparisons suggest that the SDHs represent a unique class of dehydrogenases. The structure provides a framework for further investigation to discover and develop novel inhibitors targeting this essential enzyme.
- Marco-Marin C, Ramon-Maiques S, Tavarez S, Rubio V
- Site-directed mutagenesis of Escherichia coli acetylglutamate kinase and aspartokinase III probes the catalytic and substrate-binding mechanisms of these amino acid kinase family enzymes and allows three-dimensional modelling of aspartokinase.
- J Mol Biol. 2003; 334: 459-76
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We test, using site-directed mutagenesis, predictions based on the X-ray structure of N-acetyl-L-glutamate kinase (NAGK), the paradigm of the amino acid kinase protein family, about the roles of specific residues on substrate binding and catalysis. The mutations K8R and D162E decreased V([sustrate]= infinity ) 100-fold and 1000-fold, respectively, in agreement with the predictions that K8 catalyzes phosphoryl transfer and D162 organizes the catalytic groups. R66K and N158Q increased selectively K(m)(Asp) three to four orders of magnitude, in agreement with the binding of R66 and N158 to the C(alpha) substituents of NAG. Mutagenesis in parallel of aspartokinase III (AKIII phosphorylates aspartate instead of acetylglutamate), another important amino acid kinase family member of unknown 3-D structure, identified in AKIII two residues, K8 and D202, that appear to play roles similar to those of K8 and D162 of NAGK, and supports the involvement of E119 and R198, similarly to R66 and N158 of NAGK, in the binding of the amino acid substrate, apparently interacting, respectively, with the alpha-NH(3)(+) and alpha-COO(-) of aspartate. These results and an improved alignment of the NAGK and AKIII sequences have guided us into 3-D modelling of the amino acid kinase domain of AKIII using NAGK as template. The model has good stereochemistry and validation parameters. It provides insight into substrate binding and catalysis, agreeing with mutagenesis results with another aspartokinase that were not considered when building the model.AKIII is homodimeric and is inhibited by lysine. Lysine may bind to a regulatory region that is C-terminal to the amino acid kinase domain. We make a C-terminally truncated AKIII (AKIIIt) and show that the C-region is involved in intersubunit interactions, since AKIIIt is found to be monomeric. Further, it is inactive, as demanded if dimer formation is essential for activity. Models for AKIII architecture are proposed that account for these findings.
- Soldano KL, Jivan A, Nicchitta CV, Gewirth DT
- Structure of the N-terminal domain of GRP94. Basis for ligand specificity and regulation.
- J Biol Chem. 2003; 278: 48330-8
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GRP94, the endoplasmic reticulum (ER) paralog of the chaperone Hsp90, plays an essential role in the structural maturation or secretion of a subset of proteins destined for transport to the cell surface, such as the Toll-like receptors 2 and 4, and IgG, respectively. GRP94 differs from cytoplasmic Hsp90 by exhibiting very weak ATP binding and hydrolysis activity. GRP94 also binds selectively to a series of substituted adenosine analogs. The high resolution crystal structures at 1.75-2.1 A of the N-terminal and adjacent charged domains of GRP94 in complex with N-ethylcarboxamidoadenosine, radicicol, and 2-chlorodideoxyadenosine reveals a structural mechanism for ligand discrimination among hsp90 family members. The structures also identify a putative subdomain that may act as a ligand-responsive switch. The residues of the charged region fold into a disordered loop whose termini are ordered and continue the twisted beta sheet that forms the structural core of the N-domain. This continuation of the beta sheet past the charged domain suggests a structural basis for the association of the N-terminal and middle domains of the full-length chaperone.
- Sanz Y, Toldra F
- Purification and characterization of an X-prolyl-dipeptidyl peptidase from Lactobacillus sakei.
- Appl Environ Microbiol. 2001; 67: 1815-20
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An X-prolyl-dipeptidyl peptidase has been purified from Lactobacillus sakei by ammonium sulfate fractionation and five chromatographic steps, which included hydrophobic interaction, anion-exchange chromatography, and gel filtration chromatography. This procedure resulted in a recovery yield of 7% and an increase in specificity of 737-fold. The enzyme appeared to be a dimer with a subunit molecular mass of approximately 88 kDa. Optimal activity was shown at pH 7.5 and 55 degrees C. The enzyme was inhibited by serine proteinase inhibitors and several divalent cations (Cu(2+), Hg(2+), and Zn(2+)). The enzyme almost exclusively hydrolyzed X-Pro from the N terminus of each peptide as well as fluorescent and colorimetric substrates; it also hydrolyzed X-Ala at the N terminus, albeit at lower rates. K(m) s for Gly-Pro- and Lys-Ala-7-amido-4-methylcoumarin were 29 and 88 microM, respectively; those for Gly-Pro- and Ala-Pro-p-nitroanilide were 192 and 50 microM, respectively. Among peptides, beta-casomorphin 1-3 was hydrolyzed at the highest rates, while the relative hydrolysis of the other tested peptides was only 1 to 12%. The potential role of the purified enzyme in the proteolytic pathway by catalyzing the hydrolysis of peptide bonds involving proline is discussed.
- Banbula A et al.
- Porphyromonas gingivalis DPP-7 represents a novel type of dipeptidylpeptidase.
- J Biol Chem. 2001; 276: 6299-305
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A novel dipeptidylpeptidase (DPP-7) was purified from the membrane fraction of Porphyromonas gingivalis. This enzyme, with an apparent molecular mass of 76 kDa, has the specificity for both aliphatic and aromatic residues in the P1 position. Although it belongs to the serine class of peptidases, it does not resemble other known dipeptidylpeptidases. Interestingly, the amino acid sequence around the putative active site serine residue shows significant similarity to the C-terminal region of the Staphylococcus aureus V-8 endopeptidase. The genes encoding homologues of DPP-7 were found in genomes of Xylella fastidiosa, Shewanella putrefaciens, and P. gingivalis. It is likely that at least in P. gingivalis, DPP-7 and its homologue, in concert with other di- and tripeptidases, serve nutritional functions by providing dipeptides to this asaccharolytic bacterium.
- Dikov A, Dimitrova M, Pajpanova T, Krieg R, Halbhuber KJ
- Histochemical method for dipeptidyl aminopeptidase II with a new anthraquinonyl hydrazide substrate.
- Cell Mol Biol (Noisy-le-grand). 2000; 46: 1213-8
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A new method for the histochemical visualization of lysosomal aminopeptidase dipeptidyl peptidase II activity (DPP II) is developed. The substrate L-Lys-L-Ala-5-chloro-1-anthraquinonylhydrazide-2HBr (Lys-Ala-CAH) is readily hydrolyzed by the enzyme to release 5-Cl-1-anthraquinonylhydrazine (CAH). The last compound is simultaneously coupled to an aromatic aldehyde, e.g. 4-nitrobenzaldehyde (p-NBA) or piperonal (3,4-methylenedioxybenzaldehyde; PPL), to form a highly insoluble deeply colored hydrazone, marking the enzyme locations. Using the new method, DPP II is successfully localyzed in tissue sections from different rat organs.
- Exterkate FA, Alting AC
- Role of calcium in activity and stability of the Lactococcus lactis cell envelope proteinase.
- Appl Environ Microbiol. 1999; 65: 1390-6
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The mature lactococcal cell envelope proteinase (CEP) consists of an N-terminal subtilisin-like proteinase domain and a large C-terminal extension of unknown function whose far end anchors the molecule in the cell envelope. Different types of CEP can be distinguished on the basis of specificity and amino acid sequence. Removal of weakly bound Ca2+ from the native cell-bound CEP of Lactococcus lactis SK11 (type III specificity) is coupled with a significant reversible decrease in specific activity and a dramatic reversible reduction in thermal stability, as a result of which no activity at 25 degrees C (pH 6.5) can be measured. The consequences of Ca2+ removal are less dramatic for the CEP of strain Wg2 (mixed type I-type III specificity). Autoproteolytic release of CEP from cells concerns this so-called "Ca-free" form only and occurs most efficiently in the case of the Wg2 CEP. The results of a study of the relationship between the Ca2+ concentration and the stability and activity of the cell-bound SK11 CEP at 25 degrees C suggested that binding of at least two Ca2+ ions occurred. Similar studies performed with hybrid CEPs constructed from SK11 and Wg2 wild-type CEPs revealed that the C-terminal extension plays a determinative role with respect to the ultimate distinct Ca2+ dependence of the cell-bound CEP. The results are discussed in terms of predicted Ca2+ binding sites in the subtilisin-like proteinase domain and Ca-triggered structural rearrangements that influence both the conformational stability of the enzyme and the effectiveness of the catalytic site. We argue that distinctive primary folding of the proteinase domain is guided and maintained by the large C-terminal extension.
- Ohkubo I et al.
- Dipeptidyl peptidase III from rat liver cytosol: purification, molecular cloning and immunohistochemical localization.
- Biol Chem. 1999; 380: 1421-30
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Dipeptidyl peptidase III (DPP III) was purified to homogeneity from rat liver cytosol. The calculated molecular weight of the purified enzyme was 82845.6 according to TOF-MS and 82000 on non-denaturing PAGE, and 82000 on SDS-PAGE in the absence or presence of beta-mercaptoethanol. These findings suggest that the enzyme exists in a monomeric form in rat liver cytosol. The enzyme rapidly hydrolyzed the substrate Arg-Arg-MCA and moderately hydrolyzed Gly-Arg-MCA in the pH range of 7.5 to 9.5. The Km, k(cat) and k(cat)/Km values of DPP III at optimal pH (pH 8.5) were 290 microM, 18.0 s(-1) and 62.1 s(-1) x nM(-1) for Arg-Arg-MCA and 125 microM, 4.53 s(-1) and 36.2 s(-1) x nM(-1) for Ala-Arg-MCA, respectively. DPP III was potently inhibited by EDTA, 1,10-phenanthroline, DFP, PCMBS and NEM. These findings suggest that DPP III is an exo-type peptidase with characteristics of a metallo- and serine peptidase. For further information on the molecular structure, we screened a rat liver cDNA library using affinity-purified anti-rat DPP III rabbit IgG antibodies, determined the cDNA structure and deduced the amino acid sequence. The cDNA, designated as lambdaRDIII-11, is composed of 2640 bp and encodes 738 amino acids in the coding region. Although the enzyme has a novel zinc-binding motif, HEXXXH, DPP III is thought to belong to family 1 in clan MA in the metalloprotease kingdom. The DPP III antigen was detected in significant amounts in the cytosol of various rat tissues by immunohistochemical examination.
- Beauvais A, Monod M, Debeaupuis JP, Diaquin M, Kobayashi H, Latge JP
- Biochemical and antigenic characterization of a new dipeptidyl-peptidase isolated from Aspergillus fumigatus.
- J Biol Chem. 1997; 272: 6238-44
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A novel dipeptidyl-peptidase (DPP V) was purified from the culture medium of Aspergillus fumigatus. This is the first report of a secreted dipeptidyl-peptidase. The enzyme had a molecular mass of 88 kDa and contained approximately 9 kDa of N-linked carbohydrate. The expression and secretion of dipeptidyl-peptidase varied with the growth conditions; maximal intra- and extracellular levels were detected when the culture medium contained only proteins or protein hydrolysates in the absence of sugars. The gene of DPP V was cloned and showed significant sequence homology to other eukaryotic dipeptidyl-peptidase genes. Unlike the other dipeptidyl-peptidases, which are all intracellular, DPP V contained a signal peptide. Like the genes of other dipeptidyl-peptidases, that of DPP V displayed the consensus sequences of the catalytic site of the nonclassical serine proteases. The biochemical properties of native and recombinant DPP V obtained in Pichia pastoris were unique and were characterized by a substrate specificity limited to the hydrolysis of X-Ala, His-Ser, and Ser-Tyr dipeptides at a neutral pH optimum. In addition, we showed that DPP V is identical to one of the two major antigens used for the diagnosis of aspergillosis.
- Kitazono A, Kabashima T, Huang HS, Ito K, Yoshimoto T
- Prolyl aminopeptidase gene from Flavobacterium meningosepticum: cloning, purification of the expressed enzyme, and analysis of its sequence.
- Arch Biochem Biophys. 1996; 336: 35-41
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In spite of the numerous studies regarding prolyl aminopeptidase, little is known about its mechanism and the significance of its similarity to a number of hydrolases of diverse specificity that belong to the alpha/beta hydrolase-fold family (Pseudomonas 2-hydroxymuconic semialdehyde hydrolase, atropinesterase, and 2-hydroxy-6-oxophenylhexa-2,4-dienoic acid hydrolase; human and rat epoxide hydrolases). We report the cloning and sequencing of the novel prolyl aminopeptidase gene from Flavobacterium meningosepticum (FPAP) which allowed a more comprehensive sequence comparison. FPAP was found to be a 35-kDa monomeric enzyme, releasing N-terminal proline but not hydroxyproline residues from small peptides and naphthylamide esters. Using the unweighted pair group method with arithmetic mean method, an evolutionary tree that depicts the probable relationship between the prolyl aminopeptidases and the alpha/beta hydrolase-fold enzymes was constructed. Since the alpha/beta hydrolase-fold family might also include the members of the prolyl oligopeptidase family (prolyl oligopeptidase, dipeptidyl peptidase IV, and prolyl carboxypeptidase), this proposal links all the known Pro-Y bond-cleaving proline-specific peptidases (prolyl oligopeptidase family, prolyl aminopeptidases, and prolinase) as enzymes with similar scaffolds and hydrolytic mechanisms. On the other hand, the enzymes that cleave X-Pro bonds are metalloenzymes grouped within the "pita-bread" fold family (aminopeptidase P and prolidase). Although the latter two enzymes show significant sequence homology, prolyl aminopeptidase, prolinase, and the members of the prolyl oligopeptidase family do not, and might share the alpha/beta hydrolase-fold scaffold. This rationale would explain the failure in finding a common "proline-recognizing motif" in the primary structures of these proline-specific peptidases.
- Brandt W, Lehmann T, Hofmann T, Schowen RL, Barth A
- The probable conformation of substrates recognized by dipeptidyl-peptidase IV and some aspects of the catalytic mechanism derived from theoretical investigations.
- J Comput Aided Mol Des. 1992; 6: 159-74
- Display abstract
By theoretical conformational investigations of substrates and nonsubstrates of the enzyme dipeptidyl-peptidase IV (DP IV) as well as dipeptide-esters using the ECEPP83 method we determined the structure of peptides recognized and cleaved by the enzyme. From a comparison of all possible structures for the substrates with conformations not possible in nonsubstrates we concluded that a single conformation explains substrate specificities of DP IV. This conformation is characterized by the following dihedral angles: psi 1 = 85 degrees, omega 1 = 180 degrees, phi 2 = -75 degrees, psi 2 = 80 degrees, and omega 2 = 180 degrees. The conclusions were supported by comparisons of molecular electrostatic potentials calculated with the molecular graphics program HAMOG.
- Tan PS et al.
- Localization of peptidases in lactococci.
- Appl Environ Microbiol. 1992; 58: 285-90
- Display abstract
The localization of two aminopeptidases, an X-prolyl-dipeptidyl aminopeptidase, an endopeptidase, and a tripeptidase in Lactococcus lactis was studied. Polyclonal antibodies raised against each purified peptidase are specific and do not cross-react with other peptidases. Experiments were performed by immunoblotting after cell fractionation and by electron microscopy of immunogold-labeled peptidases. All peptidases were found to be intracellular. However, immunogold studies showed a peripheral labeling of the X-prolyl-dipeptidyl aminopeptidase, the tripeptidase, and the endopeptidase. This peripheral location was further supported by the detection of these three enzymes in cell membrane fractions in which none of the two aminopeptidases was present.
- Niven GW
- Aminopeptidase A from Lactococcus lactis.
- Biochem Soc Trans. 1991; 19: 273-273
- Matoba S, Ogrydziak DM
- A novel location for dipeptidyl aminopeptidase processing sites in the alkaline extracellular protease of Yarrowia lipolytica.
- J Biol Chem. 1989; 264: 6037-43
- Display abstract
A stretch of 10 consecutive dipeptides with the sequence -X-Ala- or -X-Pro-, possible cleavage sites for dipeptidyl aminopeptidase (DPAPase) activity, are located in the prepro-region of the alkaline extracellular protease (AEP) beginning at Leu14. Evidence for DPAPase processing of this dipeptide stretch was obtained by characterizing the polypeptide secreted by a strain carrying a xpr6 mutation. The secreted polypeptide reacted with antibodies specific for AEP and was essentially identical to the 52-kilodalton intracellular AEP precursor based on mobility during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, content of N-linked carbohydrate, and peptide mapping. Amino-terminal amino acid sequencing of this secreted precursor revealed that it consisted of at least three major polypeptides. One began at the end of the stretch of dipeptides, and two of the others began two and four amino acids upstream. These results confirm that DPAPase activity is involved in the formation of the 52-kilodalton AEP precursor. In other reported cases of DPAPase processing, the dipeptides are located directly upstream of the mature polypeptide. For AEP, the dipeptide stretch is located over 120 amino acids upstream from the N terminus of mature AEP. The novel location of the dipeptide stretch may provide a mechanism for preventing premature activation of AEP in the secretory pathway.
- Kallenbach W, Kullertz G, Fischer G
- [Determination of dipeptidyl aminopeptidase activities in the cerebrospinal fluid].
- Psychiatr Neurol Med Psychol (Leipz). 1984; 36: 295-302
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The investigation of enzyme activity in cerebrospinal fluid has been without relevant results for laboratories analysing spinal fluid. For neurochemical purposes, it is interesting that the Substance P is convered by Depeptidyl-aminopeptidase IV (DP IV), liberating dipeptides. The hydrolysis of nitroanilids of the form Xaa-Pro-NHNp in cerebrospinal fluid was analysed using them as peptidases substrates. Finally a method for measuring the activity was proposed.
- Fischer G, Heins J, Barth A
- The conformation around the peptide bond between the P1- and P2-positions is important for catalytic activity of some proline-specific proteases.
- Biochim Biophys Acta. 1983; 742: 452-62
- Display abstract
Proline-containing dipeptidyl-4-nitroanilides have been synthesised and subjected to dipeptidyl peptidase IV-catalysed hydrolysis at high enzyme concentrations to collect information on the conformational specificity of the enzyme active site for a nonscissile bond. Descriptions of the biphasic kinetics were carried out in terms of cis/trans interconversion of the substrates. The results show that the enzyme can cleave only the trans-conformation of the substrate. The competitive inhibition by Gly-Pro-OH and Ala-Pro-OH is also specific for the trans form of the dipeptides. The interpretation of the results obtained from these kinetic studies has led to proposals for the stepwise cleavage of biologically active peptides like substance P and beta-casomorphine by dipeptidyl peptidase IV.
- Krutzsch HC, Pisano JJ
- Preparation of dipeptidyl aminopeptidase IV for polypeptide sequencing.
- Biochim Biophys Acta. 1979; 576: 280-9
- Display abstract
Dipeptidyl aminopeptidase IV is a dipeptidylpeptide hydrolase (EC 3.4.14) which hydrolyzes bond at the carboxyl group of proline releasing X-Pro dipeptides from the amino-terminus of polypeptides. The enzyme was purified 440-fold in 37% yield from swine kidney by ammonium sulfate fractionation, DEAE-cellulose chromatography, gel filtration and affinity chromatography with dipeptide-substituted Sepharose 4B. The enzyme released X-Pro from all X-Pro-beta-naphthylamides and polypeptides tested. The released dipeptides were not further degraded, and were readily identified in digests. The enzyme is suitable for use in the dipeptidyl aminopeptidase method for sequence analysis of polypeptides.
- Kato T, Hama T, Nagatsu T, Kuzuya H, Sakakibara S
- Changes of X-prolyl dipeptidyl-aminopeptidase activity in developing rat brain.
- Experientia. 1979; 35: 1329-30
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We found X-prolyl dipeptidyl-aminopeptidase activity in rat brain and examined the developmental changes at various ages. The total enzyme activity per brain increased until 4 weeks of age, and then decreased during maturation. Specific activity in young rat brain was higher than that in adult rat brain. The properties of the brain enzyme were different from those of pituitary and other tissues.
- Callahan PX, Ken McDonald J, Ellis S
- [23] Sequencing of peptides with dipeptidyl aminopeptidase I.
- Methods Enzymol. 1972; 25: 282-98
- Ken McDonald J, Callahan PX, Ellis S
- [22] Preparation and specificity of dipeptidyl aminopeptidase I.
- Methods Enzymol. 1972; 25: 272-81