Purification and properties of an extracellular leucine aminopeptidase from the Bacillus sp. N2

A halophilic bacterium was isolated from fermented anchovy sauce and identified as Bacillus species. An extracellular leucine aminopeptidase from Bacillus sp. N2 was purified to homogeneity using four successive purification steps. The enzyme has a native molecular mass of about 57 000 Da using FPLC gel filtration analysis and a molecular mass of 58 000 Da using SDS-polyacrylamide gel electrophoresis. This monomeric leucine aminopeptidase showed maximum enzyme activity at pH 9·5. The optimum temperature was 50 °C when L -Leu- p -nitroanilide was the substrate. The leucine aminopeptidase was inactivated by 1,10-phenanthroline, dithiothreitol and sodium dodecyl sulphate. Enzyme activity was increased by addition of Co²⁺. It is likely that Co²⁺ plays an important role in the catalysis or stability of the Bacillus sp. N2 leucine aminopeptidase. Sodium chloride (0–4·5 mol l⁻¹) increased the hydrolytic activity towards L -Leu- p -nitroanilide. The N-terminal amino acid sequence was Glu-Arg-Glu-Leu-Pro-Phe-Lys-Ala-Lys-His-Ala-Tyr-Ser-Thr-Ile. The purified enzyme had a high specificity for L -Leu- p -nitroanilide.     

Accumulation of cell-bound alpha-amylase in Bacillus subtilis cells in the presence of tunicamycin

The amino acid sequence of the N-terminal cyanogen bromide fragment of bovine lens leucine aminopeptidase has been determined. This fragment contains a total of 171 amino acid residues and has a calculated molecular weight of 18,637. The sequence data presented here represent the first report of primary structure determination of a member of the class of aminopeptidases.The single cleavage site produced by limited tryptic digestion of native leucine aminopeptidase was determined to be between arginine-137 and lysine-138 of the total amino acid sequence. The possible existence of distinct structural domains in leucine aminopeptidase is discussed.     

Predicting N-terminal acetylation based on feature selection method

Methionine aminopeptidase and N-terminal acetyltransferase are two enzymes that contribute most to the N-terminal acetylation, which has long been recognized as a frequent and important kind of co-translational modifications [R.A. Bradshaw, W.W. Brickey, K.W. Walker, N-terminal processing: the methionine aminopeptidase and N alpha-acetyl transferase families, Trends Biochem. Sci. 23 (1998) 263-267]. The combined action of these two enzymes leads to two types of N-terminal acetylated proteins that are with/without the initiator methionine after the N-terminal acetylation. To accurately predict these two types of N-terminal acetylation, a new method based on feature selection has been developed. 1047 N-terminal acetylated and non-acetylated decapeptides retrieved from Swiss-Prot database (http://cn.expasy.org) are encoded into feature vectors by amino acid properties collected in Amino Acid Index database (http://www.genome.jp/aaindex). The Maximum Relevance Minimum Redundancy method (mRMR) combining with Incremental Feature Selection (IFS) and Feature Forward Selection (FFS) is then applied to extract informative features. Nearest Neighbor Algorithm (NNA) is used to build prediction models. Tested by Jackknife Cross-Validation, the correct rate of predictors reach 91.34% and 75.49% for each type, which are both better than that of 84.41% and 62.99% acquired by using motif methods [S. Huang, R.C. Elliott, P.S. Liu, R.K. Koduri, J.L. Weickmann, J.H. Lee, L.C. Blair, P. Ghosh-Dastidar, R.A. Bradshaw, K.M. Bryan, et al., Specificity of cotranslational amino-terminal processing of proteins in yeast, Biochemistry 26 (1987) 8242-8246; R. Yamada, R.A. Bradshaw, Rat liver polysome N alpha-acetyltransferase: substrate specificity, Biochemistry 30 (1991) 1017-1021]. Furthermore, the analysis of the informative features indicates that at least six downstream residues might have effect on the rules that guide the N-terminal acetylation, besides the penultimate residue. The software is available upon request.     

Distinct behavior of beta-endorphin and corticotropin toward leucine aminopeptidase action

Reactions of human beta-endorphin, corticotropin and their synthetic analogs with leucine aminopeptidase have been investigated. The results confirmed previous findings that beta-endorphin is resistant to the aminopeptidase action whereas corticotropin is not. Beta-endorphin-(1-5) is completely digested by the enzyme while beta-endorphin-(1-17) is resistant. In contrast, the NH2-terminal 7 residues in corticotropin are removed readily by leucine aminopeptidase. This is confirmed by the observation that human corticotropin-(7-38) is not hydrolyzed by the enzyme. This contrasting behavior of the two hormones toward leucine aminopeptidase may be related to differences in their conformational structures.     

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

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

Characterization of two uterine proteases and their actions on the estrogen receptor

We have characterized two previously undetected proteases from the calf uterine cytosol and measured their actions on the estrogen receptor. One is an exopeptidase, purified 60-fold, that hydrolyzed amino acid (lysine-, and alanine-, or leucine-) p-nitroanilide substrates and leucylglycylglycine, did not hydrolyze [14C]methemoglobin, was completely inhibited by 1 mM bestatin or puromycin (specific inhibitors of leucine aminopeptidase like enzymes), and was unable to influence the sedimentation of the 8S form of the estrogen receptor in sucrose gradients containing dilute Tris buffer. A commercial porcine leucine aminopeptidase, like the calf uterine aminopeptidase, did not convert the 8S estrogen receptor to a 4S form. Evidently, removal of the N-terminal amino acid(s) from the estrogen receptor by exopeptidase action cannot alter the sedimentation of the 8S form of the receptor, or the N-terminal amino acid(s) of the receptor is (are) unaccessible or resistant to exopeptidase activity. The second, a receptor-active protease, is an endopeptidase that did not hydrolyze any of the synthetic amide or peptide substrates tested but did possess [14C]methemoglobin-degrading activity and the ability to convert the 8S estrogen receptor to a modified 4S form in sucrose gradients containing dilute Tris buffer. The modified 4S receptor was separable from the native receptor by DEAE-cellulose chromatography. The endopeptidase did not require Ca2+ for activity, and its chromatographic properties were distinctly different from a previously isolated Ca2+-activated protease. It was inhibited by leupeptin or dipyridyl disulfide, suggesting the presence of a thiol group that is essential for its activity. These data indicate that a decrease in the sedimentation rate of the estrogen receptor in sucrose gradients with low salt or a change in the receptor's elution on DEAE-cellulose chromatography is not related to receptor activation but is produced by the receptor-active protease or other proteases.     

Properties of Streptomyces griseus aminopeptidase

The paper deals with studying the properties of aminopeptidase isolated from Str. griseus culture fluid. The preparation is characterized by a high specific activity and heat stability, it has no admixtures of carboxypeptidases and proteinases. The enzyme is easily inhibited by EDTA, but the addition of Ca2+ evokes its complete reactivation. A partial recovery of the activity may be also reached under the influence of some other bivalent metals. In hydrolysis of di- and tripeptides it is shown that the enzyme has a preferential effect on the substrates with N-terminal leucine. Peptides with N-terminal alanine, valine and glycine are almost not hydrolyzed. The use of the native insulin and decapeptide with the known amino acidic sequence as substrates shows that aminopeptidase can hydrolyze proteins and peptides with the successive release of some amino acids: phenylalanine, serine triptophane, valine, asparagine, etc. Glycine is difficult for removal and may inhibit the further hydrolysis of the polypeptide chain.     

The crystal structure of AF1521 a protein from Archaeoglobus fulgidus with homology to the non-histone domain of macroH2A

MacroH2A is an unusual histone H2A variant that has an extensive C-terminal tail that comprises approximately two thirds of the protein. The C-terminal non-histone domain of macroH2A is also found in a number of other proteins and has been termed the macro domain. Here we report the crystal structure to 1.7A of AF1521, a protein consisting of a stand-alone macro domain from Archaeoglobus fulgidus. The structure has a mixed alpha/beta fold that closely resembles the N-terminal DNA binding domain of the Escherichia coli leucine aminopeptidase PepA. The structure also shows some similarity to members of the P-loop family of nucleotide hydrolases.     

Sensitivity of D-beta-hydroxybutyrate dehydrogenase to proteolytic enzymes; influence of phospholipids

Controlled proteolysis of D-beta-hydroxybutyrate dehydrogenase in different forms were carried out using several proteases with different and well known specificities. The results obtained were the following: Purified apoBDH (phospholipid-free) was rapidly and strongly inactivated by all proteases tested except leucine aminopeptidase , in contrast with non-membrane enzymes which were unaffected by all proteases. BDH activity was completely preserved when proteases were incubated with either native BDH (membrane linked) or reconstituted BDH with reactivating-phospholipids (lecithins of total mitochondrial phospholipids), while non-reactivating-phospholipids gave no protection against proteases. C-terminal part of the enzyme was found to be essential for enzymatic activity while the N-terminal aminoacid is N-substituted. Controlled proteolysis whatever the protease used (except leucine aminopeptidase ) was followed by strong inactivation of the enzyme.     

The replacement histone H2A.Z in a hyperacetylated form is a feature of active genes in the chicken

The replacement histone H2A.Z is variously reported as being linked to gene expression and preventing the spread of heterochromatin in yeast, or concentrated at heterochromatin in mammals. To resolve this apparent dichotomy, affinity-purified antibodies against the N-terminal region of H2A.Z, in both a triacetylated and non-acetylated state, are used in native chromatin immmuno-precipitation experiments with mononucleosomes from three chicken cell types. The hyperacetylated species concentrates at the 5′ end of active genes, both tissue specific and housekeeping but is absent from inactive genes, while the unacetylated form is absent from both active and inactive genes. A concentration of H2A.Z is also found at insulators under circumstances implying a link to barrier activity but not to enhancer blocking. Although acetylated H2A.Z is widespread throughout the interphase genome, at mitosis its acetylation is erased, the unmodified form remaining. Thus, although H2A.Z may operate as an epigenetic marker for active genes, its N-terminal acetylation does not.     

Isolation and characterization of a new aminopeptidase from bovine lens

An aminopeptidase has been purified to homogeneity from bovine lens tissue by gel filtration and DEAE-cellulose chromatography. This enzyme has a molecular weight of 96,000 under both native and denaturing conditions. The purified enzyme hydrolyzed a variety of synthetic substrates as well as di-, tri-, and higher molecular weight peptides. Significantly this enzyme is capable of hydrolyzing arginine, lysine, and proline aminoacyl bonds. The pH optimum for activity and stability was 6.0. Both a reduced sulfhydryl group and a divalent metal ion are essential for activity. The native enzyme contains 1.6 mol of zinc and 1.0 mol of copper/mol of enzyme. No activation was seen upon incubation with either magnesium or manganese; however, heavy metal ions were inhibitory. Bestatin and puromycin were effective inhibitors and no endopeptidase activity could be detected in the purified preparation. This enzyme is clearly distinct from the lens leucine aminopeptidase, but rather, is identical to a cytosolic aminopeptidase III isolated from other tissues. Evidence is presented which argues that this enzyme may be the major lens aminopeptidase under in vivo conditions.     

Effects of alpha1-adrenergic receptor blockade by doxazosin on renin-angiotensin system-regulating aminopeptidase and vasopressin-degrading activities in male and female rat thalamus.

The thalamus has connections with central autonomic centers involved in cardiovascular control and is enervated by noradrenergic fibers. The excitability of thalamic neurons is due to a reduction of ionic currents mediated by alpha(1)-adrenoceptors. The brain renin- angiotensin system (RAS) and the peptide hormone arginine-vasopressin (AVP) are also involved in the central control of blood pressure, and fluid and electrolyte homeostasis. It has been extensively reported that aminopeptidase A (APA), aminopeptidase B (APB), aminopeptidase N (APN), and vasopressin-degrading cystyl aminopeptidase activity (AVP-DA) play an important role in the regulation of the activity of angiotensins and AVP. We have analyzed the effect of alpha(1)-adrenoceptor blockade by doxazosin on RAS-regulating aminopeptidase activities and AVP-DA in soluble and membrane-bound fractions of male and female rat thalamus. Our results show that alpha(1)-adrenoceptors blockade by doxazosin does not modify the RAS through its degrading peptidases at thalamic level either in male or female rats. However, alpha(1)-adrenoceptors blockade shows gender differences in AVP-DA, increasing in males but not in females, supporting an increased capacity of males against females to degrade AVP and, therefore, to regulate cardiovascular homeostasis, under this pharmacological manipulation.     

Removal of N-acetyl groups from blocked peptides with acylpeptide hydrolase. Stabilization of the enzyme and its application to protein sequencing

Acylpeptide hydrolase, an enzyme that removes the modified residue from N-terminally acetylated peptides, has been purified from ovine liver and developed as a tool in sequencing blocked peptides and proteins. Its instability imposes a major limitation on the use of the mammalian enzyme in protein chemistry. Coupling to Sepharose followed by intramolecular cross-linking with dimethyl-suberimidate increased its thermostability and rendered it more resistant to inactivation by either SDS or N,N-dimethylformamide. The resulting enzyme preparation is reusable and more effective at cleaving longer acetylated peptides. It is therefore useful for unblocking acetylated proteins prior to protein sequence analysis. Intact proteins and many isolated peptides are still too large to be cleaved directly, but in this paper we describe a procedure for overcoming this difficulty. The protein is fragmented and non-acetylated peptides are then absorbed out with isothiocyanato-glass. The N-terminal peptide remains in solution and is unblocked with stabilised acylpeptide hydrolase. No chromatographic separation are required. The N-terminal sequence can then be obtained by automated Edman degradation. This procedure has been successfully demonstrated on a large synthetic peptide.     

Identification of yeast aspartyl aminopeptidase gene by purifying and characterizing its product from yeast cells

Aspartyl aminopeptidase (EC 3.4.11.21) cleaves only unblocked N-terminal acidic amino-acid residues. To date, it has been found only in mammals. We report here that aspartyl aminopeptidase activity is present in yeast. Yeast aminopeptidase is encoded by an uncharacterized gene in chromosome VIII (YHR113W, Saccharomyces Genome Database). Yeast aspartyl aminopeptidase preferentially cleaved the unblocked N-terminal acidic amino-acid residue of peptides; the optimum pH for this activity was within the neutral range. The metalloproteases inhibitors EDTA and 1.10-phenanthroline both inhibited the activity of the enzyme, whereas bestatin, an inhibitor of most aminopeptidases, did not affect enzyme activity. Gel filtration chromatography revealed that the molecular mass of the native form of yeast aspartyl aminopeptidase is approximately 680,000. SDS/PAGE of purified yeast aspartyl aminopeptidase produced a single 56-kDa band, indicating that this enzyme comprises 12 identical subunits.     

Human leukocyte-derived arginine aminopeptidase. The third member of the oxytocinase subfamily of aminopeptidases

In this study we report the cloning and characterization of a novel human aminopeptidase, which we designate leukocyte-derived arginine aminopeptidase (L-RAP). The sequence encodes a 960-amino acid protein with significant homology to placental leucine aminopeptidase and adipocyte-derived leucine aminopeptidase. The predicted L-RAP contains the HEXXH(X)18E zinc-binding motif, which is characteristic of the M1 family of zinc metallopeptidases. Phylogenetic analysis indicates that L-RAP forms a distinct subfamily with placental leucine aminopeptidase and adipocyte-derived leucine aminopeptidase in the M1 family. Immunocytochemical analysis indicates that L-RAP is located in the lumenal side of the endoplasmic reticulum. Among various synthetic substrates tested, L-RAP revealed a preference for arginine, establishing that the enzyme is a novel arginine aminopeptidase with restricted substrate specificity. In addition to natural hormones such as angiotensin III and kallidin, L-RAP cleaved various N-terminal extended precursors to major histocompatibility complex class I-presented antigenic peptides. Like other proteins involved in antigen presentation, L-RAP is induced by interferon-gamma. These results indicate that L-RAP is a novel aminopeptidase that can trim the N-terminal extended precursors to antigenic peptides in the endoplasmic reticulum.     

Binding of G alpha(o) N terminus is responsible for the voltage-resistant inhibition of alpha(1A) (P/Q-type, Ca(v)2.1) Ca(2+) channels

G-protein-mediated inhibition of presynaptic voltage-dependent Ca(2+) channels is comprised of voltage-dependent and -resistant components. The former is caused by a direct interaction of Ca(2+) channel alpha(1) subunits with G beta gamma, whereas the latter has not been characterized well. Here, we show that the N terminus of G alpha(o) is critical for the interaction with the C terminus of the alpha(1A) channel subunit, and that the binding induces the voltage-resistant inhibition. An alpha(1A) C-terminal peptide, an antiserum raised against G alpha(o) N terminus, and a G alpha(o) N-terminal peptide all attenuated the voltage-resistant inhibition of alpha(1A) currents. Furthermore, the N terminus of G alpha(o) bound to the C terminus of alpha(1A) in vitro, which was prevented either by the alpha(1A) channel C-terminal or G alpha(o) N-terminal peptide. Although the C-terminal domain of the alpha(1B) channel showed similar ability in the binding with G alpha(o) N terminus, the above mentioned treatments were ineffective in the alpha(1B) channel current. These findings demonstrate that the voltage-resistant inhibition of the P/Q-type, alpha(1A) channel is caused by the interaction between the C-terminal domain of Ca(2+) channel alpha(1A) subunit and the N-terminal region of G alpha(o).     

Purification and characterization of aminopeptidase B from Escherichia coli K-12

Aminopeptidase B, which is one of the four cysteinylglycinases of Escherichia coli K-12, was purified to electrophoretic homogeneity and its enzymatic characteristics were observed. Aminopeptidase B was activated by various divalent cations such as Ni2+, Mn2+, Co2+, and Cd2+, and lost its activity completely on dialysis against EDTA. This indicates that aminopeptidsase B is a metallopeptidase. It was stabilized against heat in the presence of Mn2+ or Co2+. The activity of aminopeptidase B, which was saturated with one of above divalent cations, was enhanced on the addition of a very small amount of a second divalent cation. Alpha-glutamyl p-nitroanilide, leucine p-nitroanilide, and methionine p-nitroanilide were good substrates for aminopeptidase B, while native peptides, cysteinylglycine and leucylglycine, were far better substrates. The kcat/Km for cysteinylglycine was much bigger than those for leucylglycine or leucine p-nitroanilide.     

Enzymatic degradation of beta- and mixed alpha,beta-oligopeptides

One of the main and most astonishing characteristics of peptides comprised of beta-amino acids with proteinogenic side chains is their extraordinarily high stability towards enzymatic degradation. So far, only certain microbial enzymes have been shown to cleave N-terminal beta(3)-homoamino acid residues from peptides. In this work, the L-aminopeptidase-D-amidase/esterase (DmpA) from Ochrobactrum anthropi LMG7991 is compared to two closely related beta-peptidyl aminopeptidases (BapA), which originate from Sphingosinicella strains, and to microsomal leucine aminopeptidase (LAP) as a reference. All four enzymes are aminopeptidases cleaving N-terminal amino acids from small peptides. Degradation experiments reveal that DmpA and both BapA enzymes exhibit unique, but clearly distinct substrate specificities and preferences. DmpA also cleaves beta- and mixed alpha,beta-peptides and amides, but a short side chain of the N-terminal beta-amino acid residue seems to be a prerequisite, since only peptides carrying N-terminal betahGly and beta(3)hAla are hydrolyzed with good efficiencies. Both beta-peptidyl aminopeptidases cleave beta-amino acids from a variety of beta-peptides and mixed alpha,beta-peptides, but they do not accept alpha-amino acids in the N-terminal position. Astonishingly, DmpA exhibited much higher catalytical rates for the mixed dipeptide carnosine (H-betahGly-His-OH) than for any other substrate described until now.     

A synthetic method for diversification of the P1' substituent in phosphinic dipeptides as a tool for exploration of the specificity of the S1' binding pockets of leucine aminopeptidases

A novel, general, and versatile method of diversification of the P1' position in phosphinic pseudodipeptides, presumable inhibitors of proteolytic enzymes, was elaborated. The procedure was based on parallel derivatization of the amino group in the suitably protected phosphinate building blocks with appropriate alkyl and aryl halides. This synthetic strategy represents an original approach to phosphinic dipeptide chemistry. Its usefulness was confirmed by obtaining a series of P1' modified phosphinic dipeptides, inhibitors of cytosolic leucine aminopeptidase, through computer-aided design basing on the structure of homophenylalanyl-phenylalanine analogue (hPheP[CH(2)]Phe) bound in the enzyme active site as a lead structure. In this approach novel interactions between inhibitor P1' fragment and the S1' region of the enzyme, particularly hydrogen bonding involving Asn330 and Asp332 enzyme residues, were predicted. The details of the design, synthesis, and activity evaluation toward cytosolic leucine aminopeptidase and aminopeptidase N are discussed. Although the potency of the lead compound has not been improved, marked selectivity of the synthesized inhibitors toward both studied enzymes was observed.     

Arylamidase of Neisseria catarrhalis

Neisseria catarrhalis produces arylamidase intracellularly and is one of the gram-negative bacteria producing exceptionally large amounts of this enzyme.In general, gram-positive bacteria do not produce this enzyme. Arylamidase from N. catarrhalis was purified by salt fractionation, chromatography, and density gradient ultracentrifugation. Its sedimentation coefficient was 6.6; l-alanine-beta-naphthylamide (betaNA) was the most rapidly hydrolyzed amino acid-betaNA. The enzyme had pK(e) values of 6.1 and 8.7 and pK(es) values of 7.1 and 7.9; only those amino acid-betaNA compounds of the l configuration were susceptible to hydrolysis. Arylamidase catalyzed stepwise hydrolysis of dipeptide-betaNA, beginning with the N-terminal residue. Substrates having amino acid residues with larger R groups, such as leucine, interacted much more effectively with enzyme. The significance of the predominate occurrence of arylamidase activity in gram-negative bacteria and the role of this enzyme in the physiology of these organisms remain unclear. It has been established, however, that arylamidase is distinct from leucine aminopeptidase.