Purification and characterization of an aminopeptidase A from hog intestinal brush-border membrane

The Secretion and Action of Brush Border Enzymes in the Mammalian Small Intestine

Microvilli are conventionally regarded as an extension of the small intestinal absorptive surface, but they are also, as latterly discovered, a launching pad for brush border digestive enzymes. Recent work has demonstrated that motor elements of the microvillus cytoskeleton operate to displace the apical membrane toward the apex of the microvillus, where it vesiculates and is shed into the periapical space. Catalytically active brush border digestive enzymes remain incorporated within the membranes of these vesicles, which shifts the site of BB digestion from the surface of the enterocyte to the periapical space. This process enables nutrient hydrolysis to occur adjacent to the membrane in a pre-absorptive step. The characterization of BB digestive enzymes is influenced by the way in which these enzymes are anchored to the apical membranes of microvilli, their subsequent shedding in membrane vesicles, and their differing susceptibilities to cleavage from the component membranes. In addition, the presence of active intracellular components of these enzymes complicates their quantitative assay and the elucidation of their dynamics. This review summarizes the ontogeny and regulation of BB digestive enzymes and what is known of their kinetics and their action in the peripheral and axial regions of the small intestinal lumen.

Structural insights into central hypertension regulation by human aminopeptidase A

Hypertension is regulated through both the central and systemic renin-angiotensin systems. In the central renin-angiotensin system, zinc-dependent aminopeptidase A (APA) up-regulates blood pressure by specifically cleaving the N-terminal aspartate, but not the adjacent arginine, from angiotensin II, a process facilitated by calcium. Here, we determined the crystal structures of human APA and its complexes with different ligands and identified a calcium-binding site in the S1 pocket of APA. Without calcium, the S1 pocket can bind both acidic and basic residues through formation of salt bridges with the charged side chains. In the presence of calcium, the binding of acidic residues is enhanced as they ligate the cation, whereas the binding of basic residues is no longer favorable due to charge repulsion. Of the peptidomimetic inhibitors of APA, amastatin has higher potency than bestatin by fitting better in the S1 pocket and interacting additionally with the S3' subsite. These results explain the calcium-modulated substrate specificity of APA in central hypertension regulation and can guide the design and development of brain-targeting antihypertensive APA inhibitors.

Aminopeptidases and proteolipids of intestinal brush border

The presence of human blood group A determinants has been shown on the A+ rabbit intestinal brush border glycoproteins, particularly hydrolases. Sugar compositions of aminopeptidases N from A+ and A- rabbits were compatible with the presence in these molecules of eight N-linked glycans and of two O-linked glycans bearing the A determinants in A+ animals. The exact relative molecular masses of hydrophobic domain(s) of aminopeptidases N and A from pig and rabbit intestinal brush border have been determined by an isotopic dilution technique. The values obtained were compatible with the anchorage in the membrane of the monomeric rabbit enzymes, or of each subunit of the dimeric pig enzymes, by their N-terminal sequences, composed of 20-25 hydrophobic amino acids. This N-terminal hydrophobic sequence (14 residues) has been determined for rabbit aminopeptidase N. Short peptides containing approximately 60% hydrophobic amino acids have been extracted by chloroform-methanol from purified brush border and basolateral membranes of pig enterocytes. Their molecular properties were very similar to those of the aminopeptidase anchors released by trypsin treatment of detergent-extracted enzymes. However, several lines of evidence failed to support the assumption that these free hydrophobic peptides can be identified with anchors left inside the bilayer after proteolytic cleavage of surface hydrolases.

Gastrointestinal Function

This chapter describes the normal biochemical processes of intestinal secretion, digestion, and absorption. The digestive system is composed of the gastrointestinal (GI) tract, or the alimentary canal, salivary glands, the liver, and the exocrine pancreas. The principal functions of the gastrointestinal tract are to digest and absorb ingested nutrients, and to excrete waste products of digestion. Most nutrients are ingested in a form that is either too complex for absorption or insoluble, and therefore, indigestible or incapable of being digested. Within the GI tract, much of these substances are solubilized and further degraded enzymatically to simple molecules, sufficiently small in size, and in a form that permits absorption across the mucosal epithelium. This chapter explains in detail the mechanisms of salivary secretions, compositions of saliva, and the functions of saliva. The chapter also elaborates properties of bile as well as the synthesis of bile acids. The chapter explores the pathogenesis of the important gastrointestinal diseases of domestic animals, and the biochemical basis for their diagnosis and treatment. The chapter concludes with a discussion on disturbances of gastrointestinal function such as vomition, acute diarrheas, malabsorption, bacterial overgrowth, and ulcerative colitis.

Morphological, molecular, and functional changes in the chicken small intestine of the late-term embryo

The rapid development of the gastrointestinal tract posthatch has been described; however, little information exists concerning the development of the small intestine in the prehatch period. The present study examined the morphological, cellular, and molecular changes occurring in the small intestine toward the end of the incubation period by examining the expression of intestinal genes that code for brush border digestive enzymes and transporters, their biochemical activities, and the morphological changes in the mucosal layer. The results indicated that during the last 3 d of incubation the weight of the intestine, as a proportion of embryo weight, increased from approximately 1% on d 17 of embryonic age to 3.5% at hatch. At this time the villi could be divided into two main developmental stages, differing in their length and shape, with the larger villi often being pear-shaped and the smaller villi being narrower and having a rocket-like shape. However, on d 19 a further stage of villus development was observed. Activities of maltase, aminopeptidase, sodium-glucose transporter (SGLT)-1, and ATPase began to increase on d 19 and further increased on the day of hatch. The expression of mRNA for these brush-border membrane (BBM) enzymes and transporters was detected from d 15. Determining quantities relative to beta-actin indicated that expression of all parameters examined was low on d 15 and 17, increased 9- to 25-fold on d 19, and all decreased again on the day of hatch. Relative expression of mRNA of the different enzymes and transporters were correlated as were their activities (r = 0.75 to 0.96); however, expression was not correlated with enzymatic activities. The role of these parameters in the ontogeny of absorption is discussed. Thus, major changes in the expression and localization of the functional brush-border proteins prepare the framework for ingestion of carbohydrate- and protein-rich exogenous feed posthatch.

Activities of gastric, pancreatic, and intestinal brush-border membrane enzymes during postnatal development of dogs

OBJECTIVE

To measure activities of digestive enzymes during postnatal development in dogs.

SAMPLE POPULATION

Gastrointestinal tract tissues obtained from 110 Beagles ranging from neonatal to adult dogs.

PROCEDURE

Pepsin and lipase activities were measured in gastric contents, and amylase, lipase, trypsin, and chymotrypsin activities were measured in small intestinal contents and pancreatic tissue. Activities of lactase, sucrase, 4 peptidases, and enteropeptidase were assayed in samples of mucosa obtained from 3 regions of the small intestine.

RESULTS

Gastric pH was low at all ages. Pepsin was not detected until day 21, and activity increased between day 63 and adulthood. Activities of amylase and lipase in contents of the small intestine and pancreatic tissue were lower during suckling than after weaning. Activities of trypsin and chymotrypsin did not vary among ages for luminal contents, whereas activities associated with pancreatic tissue decreased between birth and adulthood for trypsin but increased for chymotrypsin. Lactase and gamma-glutamyltranspeptidase activities were highest at birth, whereas the activities of sucrase and the 4 peptidases increased after birth. Enteropeptidase was detected only in the proximal region of the small intestine at all ages.

CONCLUSIONS AND CLINICAL RELEVANCE

Secretions in the gastrointestinal tract proximal to the duodenum, enzymes in milk, and other digestive mechanisms compensate for low luminal activities of pancreatic enzymes during the perinatal period. Postnatal changes in digestive secretions influence nutrient availability, concentrations of signaling molecules, and activity of antimicrobial compounds that inhibit pathogens. Matching sources of nutrients to digestive abilities will improve the health of dogs during development.

Mouse leukotriene A4 hydrolase is expressed at high levels in intestinal crypt cells and splenic lymphocytes

LTA4 hydrolase (EC 3.3.2.6) is a dual-function enzyme that is essential for the conversion of leukotriene A4 (LTA4) to leukotriene B4 (LTB4) and also possesses an aminopeptidase activity. To characterize the expression of this unusual enzyme, we have cloned the mouse LTA4 hydrolase cDNA. The deduced amino acid sequence revealed 92% identity with the human sequence. Cloning and analysis of genomic sequences of mouse LTA4 hydrolase indicated that it is a single-copy gene spanning over 40kb and containing 20 exons. LTA4 hydrolase is widely expressed, with the highest levels of expression occurring in the small intestine, followed by the spleen. In situ hybridization revealed that LTA4 hydrolase is localized in the crypt cells of the small intestine, white pulp of the spleen, bronchiolar epithelium of the lung, myocardium, adrenal cortex, epithelium of the seminal vesicles, proximal tubules and the collecting ducts of the kidney, and occasional hepatocytes. Thus the widespread distribution of LTA4 hydrolase in various cell types in the tissues suggests that LTB4 may possess biological activities other than those known at present. It is also plausible that the widespread occurrence of LTA4 hydrolase in various tissues may correspond more with its function as an aminopeptidase than its function as an LTA4 hydrolase.

Cloning and characterization of a microsomal aminopeptidase from the intestine of the nematode Haemonchus contortus

In order to characterise the integral membrane glycoprotein H11 from the intestinal microvilli of the nematode Haemonchus contortus, cDNA libraries prepared using mRNA from adult worms from the UK and Australia were immunoscreened with anti-H11 sera. Antibodies affinity purified on the protein expressed by insert DNA (295 bp) of a positive clone from a UK library bound specifically to H11. A longer clone (948 bp) was obtained from the Australian library by hybridisation. Using a primer based on sequence common to these, a polymerase chain reaction product of 3.3 kb was generated from cDNA from UK H. contortus. The sequences from the UK and Australian nematodes were essentially identical over the 929 bp region in which both were represented. All three cloned DNAs hybridised to mRNA of about 3.5 kb. Analysis of the deduced amino acid sequence, which showed 32% identity with those of mammalian microsomal aminopeptidases, indicated that H11 has a short N-terminal cytoplasmic tail, a single transmembrane region and a long extracellular region with putative N-linked glycosylation sites and the HEXXHXW motif characteristic of microsomal aminopeptidases. Microsomal aminopeptidase activity co-purifies with H11. It is inhibited by bestatin, phenanthroline and amastatin. The recombinant protein has been expressed in active form in insect cells.

The characterization of two aminopeptidase activities from the cyanobacterium Anabaena flos-aquae

Aminopeptidase activity, indicated by hydrolysis of the synthetic substrate alanine p-nitroanilide, was identified in the cyanobacterium Anabaena flos-aquae. On purification, 2 enzymes were separated by gel filtration chromatography, a 188 kDa multimer (AP-I) and a 59 kDa monomeric metalloprotein (AP-II). Their activities against a range of alanine-containing peptides were screened. Both enzymes were capable of removing a variety of N-terminal residues, including proline. Neither removed N-terminal acidic residues. The activity of AP-I appeared to be limited to di- and tri-peptides, while AP-II was capable of hydrolysing (Ala)5. It was not possible to assign the active-site chemistry of AP-I to one of the known hydrolase subgroups as none of the potential inhibitors tested had a significant inhibitory effect. This is the first reported purification of aminopeptidases from a cyanobacterium.

Widespread tissue distribution of aminopeptidase A, an evolutionarily conserved ectoenzyme recognized by the BP-1 antibody

Early B-lineage cells in mice express a cell surface glycoprotein, recognized by the BP-1 and 6C3 monoclonal antibodies, that has been identified as aminopeptidase A (APA E.C.3.4.11.7). In the present studies we obtained evidence by DNA "zoo-blot" analysis that the APA gene is highly conserved. This ectoenzyme catalyzes the removal of N-terminal Glu- and Asp-residues to convert angiotensin II to angiotensin III, a degradation step important in local regulation of blood pressure in mammals. To gain further insight into the physiology of this molecule, which is shared between immune and vascular systems, we examined the tissue distribution of BP-1 mRNA using a cDNA probe and of the protein antigen using the BP-1 antibody for immunohistology. APA transcripts were present in all tissues examined. Abundant BP-1/APA was found in the intestinal brush border of the small intestine, renal glomeruli, proximal renal tubules, pulmonary alveolar walls and vascular endothelium in many organs. Other tissues containing the BP-1 antigen included stromal cells in the thymus cortex, bile canaliculi in liver, gall bladder epithelium, interlobular ducts in pancreas, the ovarian theca interna, basement membrane of the epididymis and the splanchnopleure in placenta. APA enzyme activities have been identified in most of these locations, in keeping with identification of the BP-1/6C3 antigen as APA. The data suggest this ectopeptidase may serve diverse physiologic roles in a broad spectrum of tissues.

Purification and characterization of an aminopeptidase A from Staphylococcus chromogenes and its use for the synthesis of amino-acid derivatives and dipeptides

An aminopeptidase with original specificity was purified 3800-fold to homogeneity from a cellular extract of Staphylococcus chromogenes. The enzyme was specific for acidic amino acids (Asp and Glu) at the N-terminus of peptides and thus can be classified as an aminopeptidase A. However, its specificity was not restricted to acidic amino acids: alpha-hydroxy acids such as L-malic and L-lactic acids were also accepted in position P1. The enzyme had a broad specificity for the residue at position P' 1, accepting all types of amino acids, including Pro, in this position. The optimal conditions for the hydrolysis of Asp-Phe-NH2 were pH 9.5 and 60 degrees C. The enzyme was inhibited by chelating agents and serine-protease inhibitors. The activity lost by treatment with chelating agents could be restored by Mn2+ or Zn2+ which also stimulated the native enzyme. This suggests that it is a metalloprotease with a serine residue essential for the activity. The native enzyme had an apparent molecular mass of 430 kDa on gradient-gel electrophoresis and subunits of 43 kDa as determined by SDS/PAGE. The enzyme catalyzed the synthesis of peptide and amino acid derivatives such as Asp-Phe-OMe (Aspartame) and malyl-Tyr-OEt from L-Asp and L-malic acid as acyl donors and L-Phe-OMe and L-Tyr-OEt as nucleophiles, respectively. The use of the enzyme as a reagent in protease-catalyzed peptide synthesis, N-terminal protection and subsequent deprotection, is described.

Angiotensinase A (aminopeptidase A): properties of chromatographically purified isoforms from human kidney

Angiotensin-II-cleaving angiotensinase A (aminopeptidase A, E.C. 3.4.11.7, ATA) plays an important role in glomerular haemodynamics. the pathophysiology of essential arterial hypertension and the induction of vascular disorders. In order to study biochemical and immunological properties of ATA, two isoforms (I and II) of the glycoprotein were isolated for the first time from human kidney cortex. Kidney cortex homogenate, digested with bromelain, was fractionated by ammonium sulphate precipitation and subsequent hydrophobic interaction chromatography, using a fast protein liquid chromatographic (FPLC) system. By anion-exchange FPLC (Mono Q column), the isoforms of ATA were eluted in two distinct peaks and were further purified by size-exclusion FPLC and preparative polyacrylamide gel electrophoresis. Biochemical, immunological and immunohistological characterization disclosed differences in the intrarenal localization, glycosylation Michaelis constant and apparent molecular mass (native and sodium dodecyl sulphate gel electrophoresis) but similar properties in the double-immunodiffusion technique. Polyclonal rabbit antibodies, raised against ATA isoforms I and II, precipitated an analogous antigen in urine from patients with renal tubular damage.

Purification and characterization of neuron-specific surface antigen defined by monoclonal antibody BM88

Monoclonal antibody BM88 recognizes a neurospecific surface antigen in the CNS and the PNS. In the present study, the antigen recognized by BM88 was immunopurified from pig brain and shown to be a 22-kDa polypeptide by reducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Under nonreducing conditions a protein of 40 kDa was obtained, a result indicating that the antigen is composed of two polypeptide chains of equal molecular weight linked by disulfide bridges. Gel filtration of the purified antigen in the presence of Emulphogene suggested that it may be either a monomeric or a dimeric protein. However, in the presence of Triton X-100 a monomeric structure was implied. N-Glycanase digestion indicated that the protein is probably not glycosylated. The purified antigen was characterized as an integral membrane protein by hydrophobic chromatography and phase-separation experiments with Triton X-114. The antigen, or at least the antibody binding region of the molecule, is very susceptible to protease attack, as judged by protease digestion experiments on brain membranes. By using very low concentrations of papain combined with short incubation times, the antigen was converted to a 16.3-kDa membrane-associated polypeptide as assessed by immunoblotting. This polypeptide contained the BM88 binding epitope. Soluble BM88 immunoreactive polypeptides were not obtained. Bacillus cereus phospholipase C was also unable to solubilize the antigen from the membrane. Our results suggest that the molecule, possessing at least one small extramembranous domain, is attached to the membrane via a polypeptide chain.

Aminopeptidase A activity of the murine B-lymphocyte differentiation antigen BP-1/6C3

The predicted amino acid sequence of the cDNA encoding the murine B-lymphocyte differentiation antigen BP-1/6C3 suggested that it is a member of the zinc-dependent metalloprotease family, possibly an aminopeptidase related to aminopeptidase N [microsomal aminopeptidase; alpha-aminoacyl-peptide hydrolase (microsomal), EC 3.4.11.2]. In the present studies, we examined the enzymatic activity of this antigen. From brush border preparations of the small intestine, a rich source of many endopeptidases and exopeptidases, the BP-1 antibody selectively removed aminopeptidase A [APA; L-alpha-aspartyl(L-alpha-glutamyl)-peptide hydrolase, EC 3.4.11.7] activity. The APA activity of a panel of cell lines correlated in linear fashion with cell-surface levels of the BP-1/6C3 antigen. APA activity was demonstrated for the BP-1/6C3 antigen immunopurified from the pre-B-cell membrane. This activity was enhanced by alkaline earth metals such as Ca2+ and was abrogated by amastatin and angiotensin, which are known competitive inhibitors of APA. The data indicate that the murine BP-1/6C3 antigen is active APA, an enzyme that catalyzes specifically the removal of unsubstituted, N-terminal glutamic acid and aspartic acid residues from peptides.

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.

Molecular organization of the intestinal brush border

The brush border of enterocytes represents one of the more specialized apical poles of epithelial cells. It is formed by particularly well-developed apical plasma membrane microvilli, whose shape is ensured by a highly organized cytoskeleton. The molecular organization of the cytoskeleton is described. Whereas several cytoskeleton proteins are ubiquitous, villin is highly specific for intestinal cells and can be used as a differentiation marker of these cells. The major glycoproteins, in particular hydrolases, of the brush border membrane have been characterized. They have many common structural features, in particular their mode of integration into the membrane by their N-terminal hydrophobic sequences that also plays the role of the 'signal peptide' responsible for their co-translational insertions into the endoplasmic reticulum. Studies on the biosynthesis and intracellular pathway of aminopeptidase N strongly suggest that sorting of apical and basolateral glycoproteins could occur after their integration into the basolateral domain.

Lactotransferrin receptor of mouse small-intestinal brush border. Binding characteristics of membrane-bound and triton X-100-solubilized forms

A specific lactotransferrin receptor was identified in the mouse small-intestinal brush-border membrane and the binding features were investigated in homologous and heterologous systems. The receptor was found to be specific for lactotransferrins isolated from milk of various species, but the affinity was higher toward the homologous ligand (Ka = 3.5 x 10(6) M-1 compared with 2.6 x 10(6) M-1 for both human and bovine lactotransferrins). However, the number of binding sites (n) was the same for the three lactotransferrins, namely 0.53 x 10(12)/micrograms of membrane protein. The binding of mouse lactotransferrin to its receptor was found to be pH-dependent, with an optimal binding at pH 5.5, and seemed unlikely to be carbohydrate-mediated. The receptor was demonstrated to be devoid of any affinity for human and mouse serotransferrins or for a 'serotransferrin-like' protein isolated from mouse milk. The receptor was solubilized with 1% Triton X-100 with good yield. The solubilized receptor was found to retain lactotransferrin-binding activity and sensitivity to pH.

Purification and Some Properties of a Membrane-Bound Aminopeptidase A from Streptococcus cremoris

A membrane-bound l -α-glutamyl (aspartyl)-peptide hydrolase (aminopeptidase A) (EC 3.4.11.7) from Streptococcus cremoris HP has been purified to homogeneity. The free γ-carboxyl group rather than the amino group of the N-terminal l -α-glutamyl (aspartyl) residue appeared to be essential for catalysis. No endopeptidase activity could be established with this enzyme. The native enzyme is a polymeric, most probably trimeric, metalloenzyme (relative molecular weight, approximately 130,000) which shows on sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels apparent high relative molecular weight values due to (lipid?) material dissociable with butanol. The subunit (relative molecular weight, approximately 43,000) is catalytically inactive. The enzyme is inactivated completely by dithiothreitol, chelating agents, and the bivalent metal ions Cu 2+ and Hg 2+ . Of the sulfhydryl-blocking reagents tested, only p -hydroxymercuribenzoate appeared to inhibit the enzyme. Activity lost by treatment with a chelating agent could be restored by Co 2+ and Zn 2+ . The importance of the occurrence of an aminopeptidase A in S. cremoris with respect to growth in milk is discussed.

Identification and characterization of brush-border membrane-bound neutral metalloendopeptidases from rat small intestine

Neutral metalloendopeptidase enzymes were identified and partially characterized in the brush-border membranes of rat small intestinal mucosal cells using insulin B chain and glutaryl-trialanine-4-methoxy-beta-naphthylamide as substrates. Three different molecular species of endopeptidase were identified by disc gel electrophoresis. These enzymes were shown to be distinct from pancreatic endopeptidases on the basis of the following: enrichment in the brush-border membrane fraction, site of hydrolysis of peptide substrates, sensitivity to specific proteinase inhibitors, and the presence of brush-border membrane-associated endopeptidase activity in mucosal cells of Thirty-Vella loops. Hydrolysis of the substrates was shown to be a two-step process involving initial cleavage by endopeptidase with secondary hydrolysis of the peptide products by brush-border membrane aminopeptidase N. Hydrolysis of both substrates was maximum at a neutral pH and was strongly inhibited by metal chelating agents, phosphoramidone, and amastatin. Intestinal perfusion studies using glutaryl-trialanine-4-methoxy-beta-naphthylamide suggest that these enzymes play a physiologic role in protein digestion. It was concluded that neutral endopeptidases are integral components of the intestinal brush-border membrane and work in concert with aminopeptidase N to hydrolyze dietary protein. This process may be of nutritional importance in normal subjects and those with diminished exocrine pancreatic function.

Purification and characterization of amphiphilic trehalase from rabbit small intestine

Rabbit intestinal trehalase (alpha,alpha-trehalose glucohydrolase, EC 3.2.1.28) was solubilized with Triton X-100 and purified in the presence of EDTA. The purified enzyme was homogeneous on polyacrylamide gel electrophoresis in the presence of Triton X-100 or SDS. It showed amphiphilic properties on gel filtration. polyacrylamide gel electrophoresis, charge-shift electrophoresis and phenyl-Sepharose chromatography. Its molecular weight was estimated to be about 330 000 by gel filtration under nondenaturing conditions and in the presence of Triton X-100, the value being in satisfactory agreement with the sum of the weight of one Triton X-100 micelle and twice the molecular weight (105 000) of purified hydrophilic trehalase which had been deprived of the anchor segment. The two purified trehalases gave almost the same molecular weights (about 75 000) on SDS-polyacrylamide gel electrophoresis. These results suggest that intestinal trehalase consists of two subunits with a molecular weight of 75 000 and that its anchor segment is small (less than 5000). Triton X-100 extracts freshly prepared from intestinal microvilli essentially showed one form of trehalase, which behaved on phenyl-Sepharose and Con A-Sepharose chromatography in the same manner as purified amphiphilic trehalase.

Studies on the multiple forms of aminopeptidase A in bovine seminal vesicle secretion

After gel filtration, anion exchange chromatography and chromatofocusing aminopeptidase A (AP-A) of bovine seminal vesicle secretion (VS-S) was found to exist in multiple forms. Depending on the pH used (pH 6.5-8.5) gel filtration of VS-S revealed 1-3 forms of AP-A. At pH 8.5 two dissimilar low-molecular-weight forms of AP-A converted into aggregated high-molecular-weight form. The aggregated AP-A was dissociated into an intermediate form with Triton X-100 and/or sodium deoxycholate and further into two low-molecular-weight forms with thiol compounds and neuraminidase. The aggregated, intermediate and low-molecular-weight forms of AP-A displayed some differences in catalytic properties, modifier characteristics and thermal inhibition.

Human intestinal brush border peptidases

Hydrolysis of small peptides, like disaccharide hydrolysis, is an important function of the intestinal brush border, but little is known of the individual human peptidases. The purposes of this study were to detect all human brush border enzymes hydrolyzing dipeptides and tripeptides, identify the most discriminating substrate for each enzyme in order to permit assays in crude mixtures, and begin biochemical characterization of each enzyme. Four brush border peptidases were identified. Enzymes I (aspartate aminopeptidase, E.C. 3.4.11.7) and III (amino-oligopeptidase, E.C. 3.4.11.2) are known brush border enzymes. Enzymes II (membrane Gly-Leu peptidase) and IV (zinc stable Asp-Lys peptidase) have not been identified in human brush border previously. They are distinct from dipeptidyl aminopeptidase IV, carboxypeptidase, and gamma-glutamyl transferase. The substrate most discriminating for each enzyme is alpha-Glu-beta-naphthylamide for I (100% of the brush border activity for this substrate is due to enzyme I), glycylleucine for II (80%), leucyl-beta-naphthylamide for III (91%), and aspartyl-lysine in 5 mM Zn2+ for IV (63%). The enzymes are immunologically distinct and antibodies to each one localize to the brush border on immunohistochemical staining. Purification of 142-, 79-, 158-, and 46-fold was achieved for enzymes I through IV, respectively. Biochemical characteristics include slightly alkaline pH optima, molecular weights of 91,000-190,000, and evidence of metal ion involvement in activity. These studies provide necessary information for determining the role of brush border peptidase deficiencies in human disease.

Purification of three aminopeptidases from human maternal serum

Three aminopeptidases (I--III) were purified from maternal serum using sequential chromatographic fractionations. Aminopeptidase I was specific for N-terminal alpha-L-dicarboxylic acid residues and activated by alkaline earth metals (Ba2+, Ca2+, Sr2+). It is concluded that aminopeptidase I is aminopeptidase A (L-alpha-aspartyl-(L-alpha-glutamyl)-peptide hydrolase, EC 3.4.11.7). Aminopeptidase II hydrolysed all tested substrates including L-cystine and Bz-L-cysteine derivatives but preferred L-leucine derivatives. The properties of aminopeptidase II are equal to those described for the cystine aminopeptidase (oxytocinase) (EC 3.4.11.3.). Aminopeptidase III preferred L-alanine derivatives as substrates. It was activated by Co2+, but strongly inhibited by amastatin, puromycin and L-methionine. The characteristics are reminiscent of those of alanine aminopeptidase (EC 3.4.11.-).

Comparative characterization of some enterocytic brush border membrane enzymes in mammals and fish

The properties of the detergent- and protease-forms of alanine aminopeptidase and alkaline phosphatase of enterocytes in rabbits, cows, dogs and trout were investigated. The hydrophobic parts of the enzymes perform not only anchor functions, but also regulatory ones. It is suggested that these functions are of peculiar regularity, but vary in different enzymes of one species as well as in the same enzyme of different species.

Aminopeptidase A in reproductive organs of the male rat: evidence for high activity in the posterior lobe of the prostate

Of the reproductive organs of the male rat a high level of hydrolysis of alpha-L-glutamyl-beta-napthylamide (GluNA) and alpha-L-aspartyl-beta-naphthylamide (AspNA) in the presence of Ca2+ (5mM) (aminopeptidase A) was found in the posterior lobe of the prostate. Histochemically, this enzyme was localized in the epithelial cells of acini, which were grouped in the dorsal part and sharply separated from non-active acini in the anterior part of the lobe. A single peak of Ca2+-activated GluNA and AspNA hydrolysis was obtained after chromatofocusing at pI 4.9 and on anion exchange chromatography this activity eluted at 0.09 M NaCl. After gel filtration on Sepharose 6B a major peak of activity was found at the elution volume (Ve/Vo = 2.28). In all of these fractionation procedures aminopeptidase A was partially or totally overlapped by other aminopeptidases hydrolysing various amino acid-beta-naphthylamides. A pooled enzyme preparation gave an optimum at pH 7.3. The hydrolysis of GluNA was markedly enhanced in the presence of Ba2+, Ca2+ and Sr2+, but the hydrolysis of AspNA was activated only by Ca2+ and Sr2+. Castration caused a significant decrease in the hydrolysis of GluNA by the posterior lobe, but did not influence the low levels of activity in other parts of the prostate or in the seminal vesicles.

Purification and partial characterization of aminopeptidase A from the serum of pregnant and non-pregnant women

Aminopeptidase A (L-alpha-aspartyl(L-alpha-glutamyl)-peptide hydrolase, EC 3.4.11.7) was purified from human maternal and control sera using CM-cellulose chromatography, DEAE-Sephacel chromatography, Sephacryl S-300 gel filtration and hydroxyapatite chromatography. The purification coefficients were 3069 and 5210 and the yields 6.3 and 6.1% for the maternal and control serum, respectively. The purified enzymes appeared free from other serum aminopeptidases in polyacrylamide gel electrophoresis. The biochemical and physical characteristics of the enzymes from maternal and control sera were similar. A molecular weight of 260 000, an optimum at pH 6.75-7.25 and a fairly good stability of the enzymes at 4 and -18 degrees C were recorded. The alkaline earth metals (Ca2+, Ba2+, Sr2+) were the activators of alpha-L-glutamyl-beta-naphthylamide hydrolysis, while alpha-L-aspartyl-beta-naphthylamide hydrolysis was markedly potentiated with Ca2+ but not with Ba2+ at all. The most rapid hydrolysis was shown with GluNA (Km with Ba2+ 0.156 +/- 0.014 mM and 0.136 +/- 0.009 mM in maternal and control serum, respectively), while only minimal hydrolysis of some neutral and basic amino-acid-beta-naphthylamides were observed. The contribution of the placenta to the elevated aminopeptidase A levels in the pregnancy plasma could not be solved on the basis of the present observations.

Purification and characterization of kidney and intestinal brush-border membrane trehalases from the rabbit

Trehalase (alpha, alpha-trehalose glucohydrolase, EC 3.2.1.28) was solubilized from the brush-border membrane of rabbit intestine and kidney by Emulphogen BC 720. The intestinal and kidney enzymes were purified 10 400-times and 4457-times respectively, in a five-step procedure, including DEAE-Trisacyl, chromatofocusing, AcA 34 gel filtration, HA Ultrogel and preparative polyacrylamide gel electrophoresis. The purified enzymes were homogeneous on polyacrylamide gel electrophoresis. The specific activities of kidney and intestinal pure trehalase were identical. Kidney and intestinal trehalases have the same molecular weight (about 85 000 by Sephadex G-200 gel filtration and 75 000 by SDS-polyacrylamide gel electrophoresis). A Stokes radius of 38 A was determined. Detergent solubilized trehalase is not retarded by phenyl-Sepharose CL-4B chromatography. The isoelectric point, measured by chromatofocusing, is between pH 3.8 and 4.2 for kidney trehalase and between pH 4.6 and 4.8 for intestinal trehalase. The enzymic properties for both kidney and intestinal trehalases are identical. The optimum pH is between 5.5 and 6.0. Trehalase is heat stable up to 50 degrees C. The apparent Km was found to be 3.5 mM in maleate buffer pH 6.0. The activation energy of trehalase is 11.17 kcal/mol. Tris, sucrose and phloridzin are fully competitive inhibitors with Ki of 3.7 mM, 3.1 mM, 1.1 mM respectively. Schiff's staining on polyacrylamide gel and interaction with Con A-Sepharose indicate that trehalase is a glycoprotein. Trehalase accounts for 0.1% and 0.3% of total brush-border membrane protein of intestine and kidney, respectively.

Aspartate-specific peptidases in Salmonella typhimurium: mutants deficient in peptidase E

The only dipeptide found to serve as a leucine source for a Salmonella strain lacking peptidases N, A, B, D, P, and Q was alpha-L-aspartyl-L-leucine. A peptidase (peptidase E) that specifically hydrolyzes Asp-X peptides was identified and partially purified from cell extracts. The enzyme (molecular weight, 35,000) is inactive toward dipeptides with N-terminal asparagine or glutamic acid. Mutants (pepE) lacking this enzyme were isolated by screening extracts for loss of the activity. Genetic mapping placed the pepE locus at 91.5 map units and established the gene order metA pepE zja-861::Tn5 malB. Duplications of the pepE locus showed a gene dosage effect on levels of peptidase E, suggesting that pepE is the structural gene for this enzyme. Mutations in pepE resulted in the loss of the ability to grow on Asp-Pro as a proline source but did not affect utilization of other dipeptides with N-terminal aspartic acid. Loss of peptidase E did not cause a detectable impairment in protein degradation. Two other peptidases present in cell extracts of mutants lacking peptidases N, A, B, D, P, Q, and E also hydrolyze many Asp-X dipeptides.

Purification and molecular characterization of rat intestinal brush border membrane dipeptidyl aminopeptidase IV

Dipeptidyl aminopeptidase IV (EC 3.4.14.-) was solubilized from a particulate membrane fraction of rat intestinal mucosa with Triton X-100. The solubilized enzyme was purified to homogeneity following ammonium sulfate fractionation, chromatography on DEAE-Sepharose and hydroxyapatite, gel filtration and preparative polyacrylamide gel electrophoresis. The final enzyme preparation had a specific activity of 55 units/mg protein representing a 1373 fold purification over the starting material. Purity was judged by polyacrylamide gel electrophoresis and double immunodiffusion. The molecular weight of the native undenatured enzyme was estimated to be 230000 by gel filtration and polyacrylamide gel electrophoresis. Electrophoresis under denaturing conditions (sodium dodecyl sulfate) indicated that the protein consists of two identical 98 kDa subunits. Dipeptidyl aminopeptidase IV is a glycoprotein containing approx. 8% carbohydrate by weight. A detailed analysis of the individual sugar components demonstrated that fucose, galactose, glucose, mannose, sialic acid and hexosamine sugars were present. The nature of the constituent asparagine linked oligosaccharide side chains was further examined following cleavage from the peptide backbone by hydrazinolysis. Following high voltage paper electrophoresis approx. 80% of the isolated oligosaccharide was found with the neutral fraction while the remaining 20% consisted of a single acidic component. Gel filtration of the neutral oligosaccharide fraction indicated that it contains approx. 19 sugar residues.

The activity of membrane enzymes in homogenate fractions of rat kidney after administration of lead

Rats received one or two consecutive daily ip injections, each 0.5 mg Pb2+/100 g body weight, and the kidneys were studied 48 or 24 hr, respectively, after the injection. Renal brush border preparations from Pb2+-treated rats exhibited significant decreases in the activity of alanine aminopeptidase and gamma-glutamyl transpeptidase, greater after two injections, yet the amount of brush border protein remained unchanged. Moreover, the activity of alkaline phosphatase in the brush border was significantly increased after Pb2+. No significant changes in urine volume, urinary protein, or enzymes could be detected in these experiments. The enzymatic changes observed in the brush border after acute exposure to Pb2+ contrasted with those after exposure to Hg2+ where both the structure and enzymatic functions were severely damaged and after exposure to Cd2+ where enzymatic alterations were not accompanied by cytological changes.

Photoaffinity labeling of membrane-bound porcine aminopeptidase N

To investigate the possible role of aminopeptidase N (alpha-aminoacyl-peptide hydrolase (microsomal), EC 3.4.11.2) in the transport of amino acids from oligopeptides, the modified amino acids Phe(N3) and Phe(N3, I) and the tetrapeptides Phe(N3) or Phe(N3, I)-L-or-DAla-Gly-Gly have been synthesized. The azido-amino acids were radioactively labeled by tritium or 125I before their coupling with the tripeptides. Their utilization as photoaffinity labels for aminopeptidase N has been studied. The modification imposed at the N-terminal residue of the tetrapeptides has not impaired their hydrolysis by porcine aminopeptidase N (same kinetic parameters as unmodified peptides). In addition, evidence is presented for a specific and reversible interaction in the dark of the azido-derivatives at the substrate recognition site of the enzyme. Upon photolysis, irreversible inactivation of aminopeptidase N and covalent attachment of Phe(N3, I) have been demonstrated. Soluble and membrane-bound aminopeptidases are both labeled to the same extent indicating that the free azido-amino acid preferentially reacts with the external part of the enzyme. Although the linkage of the azido-derivative is not strictly restricted to the region of the active site, the values obtained strongly suggest that 1 mol probe has been covalently attached per mol monomer of inhibited aminopeptidase.

Presence of free hydrophobic peptides in the brush border and basolateral membranes of pig enterocytes

Short peptides containing approx. 60% of hydrophobic amino acids have been extracted by chloroform/methanol from purified brush border and basolateral membranes of pig enterocytes. These peptides can be separated from membrane lipids by thin-layer chromatography on Kieselgel plates using chloroform/methanol/water as developer. Their molecular weight is approx. 8000 as judged by SDS-gel electrophoresis. But, this value may be overestimated. They are devoid of cystine and methionine. They contain no N-terminal amino acid detectable by the dansyl and Edman degradation techniques. Extraction of papain-treated, right side out brush border vesicles led to mixtures containing the above peptides and the anchors which normally bind a variety of hydrolases to the external surface of the brush border. Peptides and anchors could not be separated by high performance thin-layer chromatography and SDS-gel electrophoresis. Their amino acid compositions were similar. However, several lines of evidence did not support the assumption that the peptides existing in non-treated brush border membranes can be identified to anchors left inside the bilayer after proteolytic cleavage of surface hydrolases. It is not yet known whether these peptides represent other hydrophobic fragments (leader or stop-transfer sequence, for instance) left in the membrane during the co-translational processing of certain proteins or constitute an independent population of molecules.