M42 aminopeptidase catalytic site: the structural and functional role of a strictly conserved aspartate residue

The M42 aminopeptidases are a family of dinuclear aminopeptidases widely distributed in Prokaryotes. They are potentially associated to the proteasome, achieving complete peptide destruction. Their most peculiar characteristic is their quaternary structure, a tetrahedron-shaped particle made of twelve subunits. The catalytic site of M42 aminopeptidases is defined by seven conserved residues. Five of them are involved in metal ion binding which is important to maintain both the activity and the oligomeric state. The sixth conserved residue, a glutamate, is the catalytic base deprotonating the water molecule during peptide bond hydrolysis. The seventh residue is an aspartate whose function remains poorly understood. This aspartate residue, however, must have a critical role as it is strictly conserved in all MH clan enzymes. It forms some kind of catalytic triad with the histidine residue and the metal ion of the M2 binding site. We assess its role in TmPep1050, an M42 aminopeptidase of Thermotoga maritima, through a mutational approach. Asp-62 was substituted with alanine, asparagine, or glutamate residue. The Asp-62 substitutions completely abolished TmPep1050 activity and impeded dodecamer formation. They also interfered with metal ion binding as only one cobalt ion is bound per subunit instead of two. The structure of Asp62Ala variant was solved at 1.5 Å showing how the substitution has an impact on the active site fold. We propose a structural role for Asp-62, helping to stabilize a crucial loop in the active site and to position correctly the catalytic base and a metal ion ligand of the M1 site.     

Crystal structure and mechanism of tripeptidyl activity of prolyl tripeptidyl aminopeptidase from Porphyromonas gingivalis

The crystal structure of prolyl tripeptidyl aminopeptidase from Porphyromonas gingivalis was determined. Prolyl tripeptidyl aminopeptidase consists of beta-propeller and catalytic domains, and a large cavity between the domains; this structure is similar to dipeptidyl aminopeptidase IV. A catalytic triad (Ser603, His710, and Asp678) was located in the catalytic domain; this triad was virtually identical to that of the enzymes belonging to the prolyl oligopeptidase family. The structure of an inactive S603A mutant enzyme complexed with a substrate was also determined. The pyrrolidine ring of the proline residue appeared to fit into a hydrophobic pocket composed of Tyr604, Val629, Trp632, Tyr635, Tyr639, Val680, and Val681. There were characteristic differences in the residues of the beta-propeller domain, and these differences were related to the substrate specificity of tripeptidyl activity. The N-terminal amino group was recognized by salt bridges, with two carboxyl groups of Glu205 and Glu206 from a helix in dipeptidyl aminopeptidase IV. In prolyl tripeptidyl aminopeptidase, however, the Glu205 (located in the loop) and Glu636 were found to carry out this function. The loop structure provides sufficient space to accommodate three N-terminal residues (Xaa-Xaa-Pro) of substrates. This is the first report of the structure and substrate recognition mechanism of tripeptidyl peptidase.     

Identification of a novel proline-rich peptide-binding domain in prolyl 4-hydroxylase.

Prolyl 4-hydroxylase (EC 1.14.11.2) catalyzes the hydroxylation of -X-Pro-Gly- sequences and plays a central role in the synthesis of all collagens. The [alpha(I)]2beta2 type I enzyme is effectively inhibited by poly(L-proline), whereas the [alpha(II)]2beta2 type II enzyme is not. We report here that the poly(L-proline) and (Pro-Pro-Gly)10 peptide substrate-binding domain of prolyl 4-hydroxylase is distinct from the catalytic domain and consists of approximately 100 amino acids. Peptides of 10-19 kDa beginning around residue 140 in the 517 residue alpha(I) subunit remained bound to poly(L-proline) agarose after limited proteolysis of the human type I enzyme tetramer. A recombinant polypeptide corresponding to the alpha(I) subunit residues 138-244 and expressed in Escherichia coli was soluble, became effectively bound to poly(L-proline) agarose and could be eluted with (Pro-Pro-Gly)10. This polypeptide is distinct from the SH3 and WW domains, and from profilin, and thus represents a new type of proline-rich peptide-binding module. Studies with enzyme tetramers containing mutated alpha subunits demonstrated that the presence of a glutamate and a glutamine in the alpha(II) subunit in the positions corresponding to Ile182 and Tyr233 in the alpha(I) subunit explains most of the lack of poly(L-proline) binding of the type II prolyl 4-hydroxylase. Keywords: collagen/dioxygenases/peptide-binding domain/ proline-rich/prolyl hydroxylase     

Homology modeling and site-directed mutagenesis of pyroglutamyl peptidase II. Insights into omega-versus aminopeptidase specificity in the M1 family

Pyroglutamyl peptidase II (PPII), a highly specific membrane-bound omegapeptidase, removes N-terminal pyroglutamyl from thyrotropin-releasing hormone (相似文献   

Identification of human aminopeptidase O, a novel metalloprotease with structural similarity to aminopeptidase B and leukotriene A4 hydrolase

We have cloned and characterized a human brain cDNA encoding a new metalloprotease that has been called aminopeptidase O (AP-O). AP-O exhibits a series of structural features characteristic of aminopeptidases, including a conserved catalytic domain with a zinc-binding site (HEXXHX18E) that allows its classification in the M1 family of metallopeptidases or gluzincins. The structural complexity of AP-O is further increased by the presence of an additional C-terminal domain 170 residues long, which is predicted to have an ARM repeat fold originally identified in the Drosophila segment polarity gene product Armadillo. This ARM repeat domain is also present in aminopeptidase B, aminopeptidase B-like, and leukotriene A4 hydrolase and defines a novel subfamily of aminopeptidases that we have called ARM aminopeptidases. Northern blot analysis revealed that AP-O is mainly expressed in the pancreas, placenta, liver, testis, and heart. Human AP-O was produced in Escherichia coli, and the purified recombinant protein hydrolyzed synthetic substrates used for assaying aminopeptidase activity. This activity was abolished by general inhibitors of metalloproteases and specific inhibitors of aminopeptidases. Recombinant AP-O also cleaved angiotensin III to generate angiotensin IV, a bioactive peptide of the renin-angiotensin pathway with multiple actions on diverse tissues, including brain, testis, and heart. On the basis of these results we suggest that AP-O could play a role in the proteolytic processing of bioactive peptides in those tissues where it is expressed.     

Nicastrin, a presenilin-interacting protein, contains an aminopeptidase/transferrin receptor superfamily domain

Nicastrin, a protein implicated in Alzheimer's disease, has a domain that is found in the aminopeptidase/transferrin receptor superfamily. In nicastrin, this domain might possess catalytic activity (as observed with aminopeptidases) or it could serve merely as a binding domain (with analogy to the transferrin receptors) for the beta-amyloid precursor protein.     

Sequential hydrolysis of proline-containing peptides with immobilized aminopeptidases

Proline-containing polypeptides are shown to be sequentially degraded by two aminopeptidases. Clostridial aminopeptidase (EC 3.4.11-) cleaves off any N-terminal amino acid residue including proline from polypeptide chains, but does not cleave the N-terminal secondary peptide bonds involving a prolyl nitrogen. Aminopeptidase P (EC 3.4.11.9) cleaves exclusively such secondary bonds. The two enzymes were immobilized by coupling them covalently to porous amino glass beads. Highly stable preparations were obtained with unchanged pH optimum and thermal stability. The applicability of clostridial aminopeptidase to sequence determination was demonstrated by the time-dependent hydrolysis of enkephalin and Substance P octapeptide. Sequential hydrolysis with the two immobilized enzymes was demonstrated with the proline-containing (Pro-Gly-Pro)10, [Asn1, Val5]angiotensin II, bradykinin, Substance P and tuftsin. Absence of endopeptidase activities was demonstrated by resistance of cytochrome c to hydrolysis and by the ordered release of amino acids during the sequential degradation by immobilized clostridial aminopeptidase and aminopeptidase P.     

A kininase and a kinin-converting enzyme: two distinct alpha aminoacyl peptide hydrolases from bovine lung

Two closely related but different aminopeptidases from bovine lung have been isolated and characterized. The first aminopeptidase, which removes the N-terminal arginine residue from L-arginyl-L-prolyl-L-proline, bradykinin, and des-[Arg9]-bradykinin, has kininase activity; it has a pH optimum of 8.0, is stimulated by Mn2+, and its molecular weight in dilute buffers is slightly greater than 240,000 daltons. The second aminopeptidase, which converts kallidin to bradykinin, has kinin-converting activity; it has a pH optimum of 6.8, is stimulated by Co2+, and its molecular weight in dilute buffers is 250,000 daltons. The kinin-converting enzyme is blocked from action when the N-terminal penultimate residue is proline.     

Aminopeptidase N from Streptococcus salivarius subsp. thermophilus NCDO 573: purification and properties

A 96 kDa aminopeptidase was purified from Streptococcus salivarius subsp. thermophilus NCDO 573. The enzyme had similar properties to aminopeptidases isolated from lactococci and lactobacilli and showed a high degree of N -terminal amino acid sequence homology to aminopeptidase N from Lactococcus lactis subsp. cremoris. It catalysed the hydrolysis of a range of aminoacyl 4-nitroanilides and 7-amido-4-methylcoumarin derivatives, dipeptides, tripeptides and oligopeptides. In common with aminopeptidases from other lactic acid bacteria, the enzyme from Strep. salivarius subsp. thermophilus showed highest activity with lysyl derivatives but was also very active with arginyl and leucyl derivatives. Relative activity with alanyl, phenylalanyl, tyrosyl, seryl and valyl derivatives was considerably lower and with glycyl, glutamyl and prolyl derivatives almost negligible. The aminopeptidase also catalysed the hydrolysis of dipeptides and tripeptides but mostly at rates much less than that with L-lysyl-4-nitroanilide and oligopeptides. The enzyme catalysed the successive hydrolysis of various amino acid residues from the N -terminus of several oligopeptides but it was unable to cleave peptide bonds on the N -terminal side of a proline residue.     

An Aneurinibacillus sp. strain AM-1 produces a proline-specific aminopeptidase useful for collagen degradation

AIMS: We have been for a species of thermophilic bacteria that can effectively decompose collagen and collagen peptides that tend to be hard-to-degrade proteins because of their high content of proline residues. This study focused upon the enzymatic degradation of prolyl peptides by thermophilic bacteria. METHODS AND RESULTS: A strain, AM-1, producing a proline-specific aminopeptidase was isolated using a medium containing gelatin that was taken from soil samples collected at Arima Hot Spring located near Kobe, Japan. The strain showed the strongest level of hydrolysing activity toward prolyl-p-nitroanilide, and the activity proved to be thermostable. Phylogenetic analysis based on 16S rDNA sequences revealed that the isolated strain AM-1 was closest to Aneurinibacillus thermoaerophilus DSM10154T in its characteristics. Analysis of the purified proline-specific aminopeptidase suggested that the enzyme is an aminopeptidase containing metal that includes important disulphide bond(s). The strain AM-1 aminopeptidase has more similarities with leucyl aminopeptidases, but its activity level differs greatly with prolyl peptides. CONCLUSIONS: The proline-specific aminopeptidase from strain AM-1 is the first from the genus Aneurinibacillus and may be a new type of aminopeptidase for hydrolysing prolyl peptide. This enzyme also contributed to the degradation of collagen when used in combination with another collagenolytic protease. SIGNIFICANCE AND IMPACT OF THE STUDY: The proline-specific aminopeptidase obtained from strain AM-1 may be used in the treatment of wastewater containing collagen that is encountered in the meat industries, and for decreasing bitter peptides in milk products.     

Genetic Characterization of pepP, Which Encodes an Aminopeptidase P Whose Deficiency Does Not Affect Lactococcus lactis Growth in Milk, Unlike Deficiency of the X-Prolyl Dipeptidyl Aminopeptidase

We sequenced the pepP gene of Lactococcus lactis, which encodes an aminopeptidase P (PepP), and demonstrated that the X-prolyl dipeptidyl aminopeptidase PepX plays a more important role than PepP in nitrogen nutrition. PepP shares homology with methionine aminopeptidases and could play a role in the maturation of nascent proteins.     

A continuous fluorigenic assay for the measurement of the activity of endoplasmic reticulum aminopeptidase 1: Competition kinetics as a tool for enzyme specificity investigation

Endoplasmic reticulum aminopeptidase 1 (ERAP1) is a recently discovered enzyme that plays critical roles in antigen presentation and the immune response. Unlike other aminopeptidases, ERAP1 displays strong sequence preferences for residues distal to the peptide-substrate’s N terminus. This unusual substrate specificity necessitates the development of new assays that are appropriate for the study of such aminopeptidases. Here we describe a continuous fluorigenic assay suitable for the analysis of the enzymatic properties of ERAP1. In this assay, signal is generated by the excision of an internally quenched N-terminal tryptophan residue from a 10mer peptide by the aminopeptidase, resulting in the enhancement of tryptophan fluorescence in the solution. This method overcomes the limitations of previously used fluorigenic and high-performance liquid chromatography (HPLC)-based assays and is appropriate for small molecule inhibitor screening as well as for rapid substrate specificity analysis by kinetic competition experiments. Such efficient peptidic fluorigenic substrates like the ones described here should greatly simplify specificity analysis and inhibitor discovery for ERAP1 and similar aminopeptidases.     

Prolyl aminopeptidase from rat brain and kidney. Action on peptides and identification as leucyl aminopeptidase

Based on the liberation of proline from ProLeuGlyNH2 (MIF-1, melanostatin) manganese-activated prolyl aminopeptidase activities were purified from rat brain and kidney cytosolic fractions. They were distinguished from other di- and tripeptidases and an arylamidase liberating N-terminal proline. Purified prolyl aminopeptidase from both sources had identical molecular properties (native Mr 300,000, subunit Mr 54,000) and very similar catalytic properties. The action of the purified enzymes was not restricted to proline. Other, in particular lipophilic, amino acids were cleaved from di-, tri- and oligopeptides with even higher velocities. Peptides with N-terminal penultimate proline residues were not degraded. From a comparison of molecular data, action on peptides, influence of pH values, inhibitors and activators, it is concluded that the activity is identical with leucyl aminopeptidase (EC 3.4.11.1) and that a separate prolyl aminopeptidase (EC 3.4.11.5) does not exist in rats.     

Binding analysis of a psychrotrophic FKBP22 to a folding intermediate of protein using surface plasmon resonance

SIB1 FKBP22 is a homodimer, with each subunit consisting of the C-terminal catalytic domain and N-terminal dimerization domain. This protein exhibits peptidyl prolyl cis-trans isomerase activity for both peptide and protein substrates. However, truncation of the N-terminal domain greatly reduces the activity only for a protein substrate. Using surface plasmon resonance, we showed that SIB1 FKBP22 loses the binding ability to a folding intermediate of protein upon truncation of the N-terminal domain but does not lose it upon truncation of the C-terminal domain. We propose that the binding site of SIB1 FKBP22 to a protein substrate of PPIase is located at the N-terminal domain.     

Functional characterization of an Arabidopsis prolyl aminopeptidase AtPAP1 in response to salt and drought stresses

It has been over 50 years since the first prolyl aminopeptidase gene was identified in Escherichia coli (EC 3.4.11.5). However, up to now, few prolyl aminopeptidases have been reported to regulate osmotic stress tolerance, especially in plant. In this study, we focused on characterization of the biological functions of the Arabidopsis prolyl aminopeptidase AtPAP1 (At2g14260), which positively regulated plant tolerance to salt and drought stresses. Protein sequence alignment revealed that AtPAP1 was evolutionarily conserved among different plant species, and the smaller molecular weight and phylogenetic tree indicated that AtPAP1 belonged to the S33.001 subfamily. By using quantitative real-time PCR assays, we demonstrated that expression of the AtPAP1 gene was rapidly induced by salt and drought stresses. We also found that knockout of the AtPAP1 gene decreased, while AtPAP1 overexpression enhanced plant tolerance to salt and drought stresses. Measurements of the proline contents and the prolyl aminopeptidase activity suggested that the transgenic plants accumulated more free proline and exhibited higher prolyl aminopeptidase activity than the wild type or knockout plants under control conditions, as well as salt and drought stresses. Furthermore, through the GUS activity analysis, we also demonstrated that the AtPAP1 promoter is stress inducible and tissue specific. The AtPAP1-GFP fusion protein was found to localize in the cytoplasm of the onion epidermal cells. In conclusion, we showed that the Arabidopsis AtPAP1 gene could positively regulate plant tolerance to salt and drought stress, maybe by acting as a prolyl aminopeptidase and thereby increasing the concentration of free proline in plant cells.     

Structural and immunological evidence for the identity of prolyl aminopeptidase with leucyl aminopeptidase

Prolyl aminopeptidase (EC 3.4.11.5) has been assumed to be a unique enzyme catalyzing specifically the removal of unsubstituted NH2-terminal L-prolyl residues from various peptides and to be distinct from leucyl aminopeptidase (EC 3.4.11.1). In the present study, prolyl aminopeptidases were purified to apparent homogeneity from pig small intestine mucosa and human liver and their NH2-terminal amino acid sequences were determined together with that of pig kidney leucyl aminopeptidase. The NH2-terminal 24-residue sequence of pig intestinal prolyl aminopeptidase was shown to be identical with that of pig kidney leucyl aminopeptidase. The NH2-terminal sequence of human liver prolyl aminopeptidase was also shown to be very similar to that of pig kidney leucyl aminopeptidase. Further, pig intestinal prolyl aminopeptidase and pig kidney leucyl aminopeptidase were immunologically indistinguishable. These lines of evidence strongly suggest that prolyl aminopeptidase is identical with leucyl aminopeptidase.     

Biochemical characterization and structural prediction of a novel cytosolic leucyl aminopeptidase of the M17 family from Schizosaccharomyces pombe

A new leucyl aminopeptidase activity has been identified in the fission yeast Schizosaccharomyces pombe. The enzyme, which has been purified and named leucyl aminopeptidase yspII (LAP yspII), had a molecular mass of 320 and 54 kDa by gel filtration and SDS/PAGE, respectively, suggesting a homohexameric structure. The enzyme cleaved synthetic aminoacyl-4-nitroanilides at an optimum of pH 8.5, and preferred leucine and methionine as N-terminal amino acids. A clear dependence on Mn2+ concentration for activity was found, and an apparent association constant of 0.33 mM was calculated for the metal ion. Bestatin behaved as a competitive inhibitor of LAP yspII (K(i) = 0.14 microM), while chelating agents such as chloroquine, EDTA and 1,10-phenanthroline also reduced enzyme activity. A MALDI-MS analysis, followed by sequencing of two of the resulting peptides, showed that LAP yspII undoubtedly corresponds to the putative aminopeptidase C13A11.05 identified in the S. pombe genome project. The protein exhibited nearly 40% sequence identity to fungal and mammalian aminopeptidases belonging to the M17 family of metallopeptidases. Catalytic residues (Lys292 and Arg366), as well as those involved in coordination with the cocatalytic metal ions (Lys280, Asp285, Asp303, Asp362 and Glu364) and those forming the hydrophobic pocket for substrate binding (Met300, Asn360, Ala363, Thr390, Leu391, Ala483 and Met486), were perfectly conserved among all known aminopeptidases. The S. pombe enzyme is predicted to be formed two clearly distinguished domains with a well conserved C-terminal catalytic domain showing a characteristic topology of eight beta-sheets surrounded by alpha-helical segments in the form of a saddle.     

Purification and Functional Characterisation of Rhiminopeptidase A,a Novel Aminopeptidase from the Venom of Bitis gabonica rhinoceros

Background

Snake bite is a major neglected public health issue within poor communities living in the rural areas of several countries throughout the world. An estimated 2.5 million people are bitten by snakes each year and the cost and lack of efficacy of current anti-venom therapy, together with the lack of detailed knowledge about toxic components of venom and their modes of action, and the unavailability of treatments in rural areas mean that annually there are around 125,000 deaths worldwide. In order to develop cheaper and more effective therapeutics, the toxic components of snake venom and their modes of action need to be clearly understood. One particularly poorly understood component of snake venom is aminopeptidases. These are exo-metalloproteases, which, in mammals, are involved in important physiological functions such as the maintenance of blood pressure and brain function. Although aminopeptidase activities have been reported in some snake venoms, no detailed analysis of any individual snake venom aminopeptidases has been performed so far. As is the case for mammals, snake venom aminopeptidases may also play important roles in altering the physiological functions of victims during envenomation. In order to further understand this important group of snake venom enzymes we have isolated, functionally characterised and analysed the sequence-structure relationships of an aminopeptidase from the venom of the large, highly venomous West African gaboon viper, Bitis gabonica rhinoceros.

Methodology and Principal Findings

The venom of B. g. rhinoceros was fractionated by size exclusion chromatography and fractions with aminopeptidase activities were isolated. Fractions with aminopeptidase activities showed a pure protein with a molecular weight of 150 kDa on SDS-PAGE. In the absence of calcium, this purified protein had broad aminopeptidase activities against acidic, basic and neutral amino acids but in the presence of calcium, it had only acidic aminopeptidase activity (APA). Together with the functional data, mass spectrometry analysis of the purified protein confirmed this as an aminopeptidase A and thus this has been named as rhiminopeptidase A. The complete gene sequence of rhiminopeptidase A was obtained by sequencing the PCR amplified aminopeptidase A gene from the venom gland cDNA of B. g. rhinoceros. The gene codes for a predicted protein of 955 amino acids (110 kDa), which contains the key amino acids necessary for functioning as an aminopeptidase A. A structural model of rhiminopeptidase A shows the structure to consist of 4 domains: an N-terminal saddle-shaped β domain, a mixed α and β catalytic domain, a β-sandwich domain and a C-terminal α helical domain.

Conclusions

This study describes the discovery and characterisation of a novel aminopeptidase A from the venom of B. g. rhinoceros and highlights its potential biological importance. Similar to mammalian aminopeptidases, rhiminopeptidase A might be capable of playing roles in altering the blood pressure and brain function of victims. Furthermore, it could have additional effects on the biological functions of other host proteins by cleaving their N-terminal amino acids. This study points towards the importance of complete analysis of individual components of snake venom in order to develop effective therapies for snake bites.     

Purification and properties of glutamyl aminopeptidase from chicken egg-white

Hydrolytic activities characteristic for different aminopeptidases were detected in the egg-white of unfertilized chicken eggs, and one aminopeptidase was isolated in an electrophoretically homogeneous form. The isolated aminopeptidase preferentially hydrolyzed bonds of alpha-glutamyl residue at the NH(2)-end of synthetic substrates and peptides. The enzyme is a dimer with an M(r) of 320,000 and pI of 4.2. Its optimal pH and temperature are 7.6 and 60 degrees C, respectively. EDTA, amastatin, and N-bromosuccinimide are inhibitors, while Ca2++ and Mn2+ are activators of the enzyme Ca2+ also stabilizes the enzyme. According to the observed properties, the isolated chicken egg-white aminopeptidase belongs to the glutamyl aminopeptidases.     

Crystal structure of the human carboxypeptidase N (kininase I) catalytic domain

Human carboxypeptidase N (CPN), a member of the CPN/E subfamily of "regulatory" metallo-carboxypeptidases, is an extracellular glycoprotein synthesized in the liver and secreted into the blood, where it controls the activity of vasoactive peptide hormones, growth factors and cytokines by specifically removing C-terminal basic residues. Normally, CPN circulates in blood plasma as a hetero-tetramer consisting of two 83 kDa (CPN2) domains each flanked by a 48 to 55 kDa catalytic (CPN1) domain. We have prepared and crystallized the recombinant C-terminally truncated catalytic domain of human CPN1, and have determined and refined its 2.1 A crystal structure. The structural analysis reveals that CPN1 has a pear-like shape, consisting of a 319 residue N-terminal catalytic domain and an abutting, cylindrically shaped 79 residue C-terminal beta-sandwich transthyretin (TT) domain, more resembling CPD-2 than CPM. Like these other CPN/E members, two surface loops surrounding the active-site groove restrict access to the catalytic center, offering an explanation for why some larger protein carboxypeptidase inhibitors do not inhibit CPN. Modeling of the Pro-Phe-Arg C-terminal end of the natural substrate bradykinin into the active site shows that the S1' pocket of CPN1 might better accommodate P1'-Lys than Arg residues, in agreement with CPN's preference for cleaving off C-terminal Lys residues. Three Thr residues at the distal TT edge of CPN1 are O-linked to N-acetyl glucosamine sugars; equivalent sites in the membrane-anchored CPM are occupied by basic residues probably involved in membrane interaction. In tetrameric CPN, each CPN1 subunit might interact with the central leucine-rich repeat tandem of the cognate CPN2 subunit via a unique hydrophobic surface patch wrapping around the catalytic domain-TT interface, exposing the two active centers.