The production and characterization of a monoclonal antibody specific for the 94,000 dalton enkephalin-degrading peptidase from rabbit kidney brush border

We have prepared a monoclonal antibody specific for a major 94,000 dalton protein from the brush border membrane of rabbit kidney cortex. The monoclonal antibody was used for the immunoaffinity purification of this protein after solubilization of brush border membranes with octylglucoside. The 94,000 dalton protein is a peptidase capable of cleaving the Gly3-Phe4 bond of methionine-enkephalin. Identification of this peptidase as a previously described 94,000 dalton enkephalinase of kidney cortex was confirmed by its sensitivity to EDTA and inhibitors such as thiorphan and phosphoramidon.     

Identification and partial purification of a band 3-like protein from rabbit renal brush border membranes

A monoclonal antibody against the membrane domain of human erythrocyte band 3 was tested for its ability to bind to rabbit renal brush border membranes. A single brush border protein with a molecular mass of 43 kDa was recognized by the band 3 antibody. Using DNase I coupled to an agarose-bead support this 43-kDa protein was partially purified by removing actin and a number of actin-bound proteins from the brush border membranes. The partially purified 43 kDa-band was eluted from sodium dodecyl sulfate-polyacrylamide gels and used to make a highly sensitive and specific guinea pig antiserum. This antiserum, but not serum from control guinea pigs, cross-reacts with purified band 3 from human, rabbit, and bovine erythrocytes confirming the immunologic similarity among these proteins. The 43-kDa protein can be stained by the periodic acid-Schiff base method and binds wheat germ agglutinin and concanavalin A, demonstrating that it is a glycoprotein. Furthermore, in the absence of dithiothreitol, the immunoreactive brush border protein migrates with a molecular mass of 86 kDa on an sodium dodecyl sulfate-polyacrylamide gel suggesting that under nonreducing conditions it exists as a dimer. The 43-kDa protein could be solubilized in octyl glucoside and was further purified using gel filtration chromatography. The amino acid composition of the 43-kDa brush border protein was obtained, and its similarity with erythrocyte band 3 is discussed.     

Isolation and properties of bovine kidney brush border vacuolar H(+)-ATPase. A proton pump with enzymatic and structural differences from kidney microsomal H(+)-ATPase

Vacuolar H(+)-ATPase was isolated from highly purified bovine kidney brush border, using a previously described immunoaffinity method. The affinity purified enzyme had reconstitutively active ATP-induced acidification that was inhibited by N-ethylmaleimide. The brush border H(+)-ATPase had a single pH optimum of 7.3, and a single Km for ATP of 360 microM. The enzyme showed no lipid activation; it had a substrate preference of ATP greater than ITP greater than UTP greater than GTP much greater than CTP, with an ATP:GTP selectivity of 1.69. The brush border H(+)-ATPase required no monovalent anion or cation for activity and was inhibited by the oxyanions NO3(-1) much greater than SO4(-2); sulfite stimulated activity at low concentrations and inhibited at higher concentrations. The inhibition produced by nitrate could not be attributed to dissociation of subunits from the enzyme. The divalent or trivalent cation preference was Mn+2 much greater than Mg+2 much greater than Co+2 greater than Al+3 greater than Ca+2 much greater than Ba+2,Sr+2; 1 mM Zn+2 inhibited the enzyme completely, but Cu+2 inhibited only 49% of activity at concentrations up to 5 mM. Sodium dodecyl sulfate-polyacrylamide gels of the brush border H(+)-ATPase showed subunits at Mr 70,000, a doublet at 56,000, 45,000, 42,000, 38,000, 33,000, 31,000, 15,000, 14,000, and 12,000. On two-dimensional gels, the pl value for the Mr 70,000 subunit was 6.3, for the Mr 56,000 was 6.4, and for the Mr 31,000 was 7.5-8.5, and microheterogeneity was observed in the Mr 56,000 and 31,000 subunits. A comparison of kidney cortex brush border H(+)-ATPase with kidney cortex microsomal H(+)-ATPase revealed differences in pH optimum, Km for ATP, lipid dependence, substrate preference, divalent ion preference, copper sensitivity, and in microheterogeneity of the Mr 56,000 and 31,000 subunits, providing evidence that different functional and structural classes of vacuolar H(+)-ATPase are segregated to specific membrane compartments.     

Flow cytometry, a very useful technique for the characterization of intestinal membrane vesicles

The plasma membrane of enterocytes comprises two structurally and functionally distinct domains. These are the apical brush border, containing digestive hydrolases and glycocalyx, and the basolateral domain, characterized by other specific markers. Using a fast and easy subcellular fractionation, we purified four membrane vesicle fractions from rabbit small intestinal mucosa: brush border, basolateral, rough endoplasmic reticulum and Golgi + smooth endoplasmic reticulum. Using flow cytometry, the fluorescence polarization of diphenylhexatriene was determined in brush border and in basolateral + Golgi + smooth endoplasmic reticulum membrane fractions in order to investigate changes in the membrane fluidity of both fractions and to compare the results obtained with those of spectroscopic techniques. Moreover, it was possible with flow cytometry to detect and quantify basolateral and brush border markers by using polyclonal and monoclonal antibodies. The advantages of flow cytometry in the detection of brush border membrane markers found in small amounts in the basolateral domain are discussed. Finally, flow cytometry holds great promise for the analysis and sorting of subcellular fractions.     

Sugar hydrolases of the infant rat intestine and their arrangement on the brush border membrane

Lactase and maltase, the predominant sugar hydrolases associated with the intestinal brush border membrane of the suckling rat, were purified essentially free of the other to near homogeneity (lactase at specific activity 23, maltase at specific activity 58), and their specific physicochemical properties determined. Antisera prepared to each showed by immunodiffusion a single common precipitin line with pure enzyme and solubilized proteins of the brush border membrane. Brush border membranes were purified 26–35-fold from infant rat intestine. Membranes prepared from 10-day-old rats contained 32% protein, 43% lipid and 25% carbohydrate with lactase and maltase estimated to comprise in excess of 10% and 2%, respectively, of the membrane protein.Immunotitration curves of lactase and maltase showed equivalent antibody binding by the membrane-bound and free enzyme forms. Furthermore, antibody binding to one enzyme did not affect the immunotitration curve or the extractability (by papain or Triton X-100) of the other membrane-bound enzyme. It was concluded that the lactase and maltase molecules are attached singly on the external membrane surface in a spatially independent manner with their antigenic sites as freely available to antibody binding as exhibited by their papain-solubilized counterparts.     

Solubilization and purification of rat liver 5''-nucleotidase by use of a zwitterionic detergent and a monoclonal-antibody immunoadsorbent.

1. A variety of detergents were used to solubilize 5'-nucleotidase from rat liver plasma membranes. 2. The zwitterionic detergent Sulphobetaine 14 gave optimal solubilization by the criteria of release into a high-speed-centrifugation supernatant and the formation of the smallest and least polydisperse active enzyme observed on polyacrylamide-gel electrophoresis. 3. The Sulphobetaine 14-solubilized enzyme from rat liver was purified by using the conventional techniques of ion-exchange chromatography and gel filtration, or by an immunoaffinity step with a monoclonal antibody immunoadsorbent. 4. 5'-Nucleotidase was purified at least 12 000-fold relative to liver homogenate by the immunoaffinity purification scheme and had a specific activity in the range 285-340 mumol/min per mg of protein. The yield was in the range 9-16%. 5. The purified enzyme shows a major polypeptide band of apparent Mr 70 000 on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and a minor band of apparent Mr 38 000. 6. A rational approach to the general problem of the purification of minor intrinsic membrane proteins is discussed, with the use of polyacrylamide-gel electrophoresis to determine the most appropriate detergent and monoclonal antibodies in subsequent immunoaffinity purification.     

Monoclonal Antibodies to and Immunoaffinity Purification of Choline Acetyltransferase from Bovine Brain

Three hybridomas producing monoclonal antibodies to bovine brain choline acetyltransferase (ChAT) have been established by fusion of the spleen cells from a mouse immunized with purified enzyme with myeloma NS-1 cells. All three clones produced IgGl antibodies that reacted with enzyme protein denatured with sodium dodecyl sulfate. By using one of the monoclonal antibodies, a rapid and efficient immunoaffinity purification procedure of bovine ChAT has been established. Immunoblot analysis and immunoaffinity purification indicated that bovine ChAT is a single 68-kilodalton protein. The monoclonal antibodies will offer us a good tool to isolate the cDNA clones encoding ChAT.     

Microdomains of distinctive glycoprotein composition in the kidney proximal tubule brush border

Two membrane proteins, maltase and gp330 (the pathogenic antigen of Heymann nephritis), present in the proximal tubule brush border have recently been independently purified and found to be large glycoproteins of similar molecular weight (Mr = approximately 300,000) by SDS PAGE. To determine the relationship between the two, monoclonal antibodies raised against the purified proteins were used for comparative immunochemical analyses and immunocytochemical localization. When a detergent extract of [35S]methionine-labeled rat renal cortex was used for immunoprecipitation with monoclonal antimaltase IgG, a single band of approximately 300 kdaltons was precipitated, whereas a single 330-kdalton band was precipitated with monoclonal anti-gp330 IgG. Monoclonal antimaltase (gp300) IgG also immunoprecipitated maltase activity from solubilized renal maltase preparations, whereas monoclonal anti-gp330 IgG failed to do so. When cyanogen bromide-generated peptide maps of the two proteins were compared, there were many similar peptides, but some differences. When maltase and gp330 were localized by indirect immunofluorescence and by indirect immunoperoxidase and immunogold techniques at the electron microscope level, they were found to be differently distributed in the brush border of the initial (S1 and S2) segments of the proximal tubule: maltase was concentrated (approximately 90%) on the microvilli, and gp330 was concentrated (approximately 90%) in the clathrin-coated apical invaginations located at the base of the microvilli. We conclude that maltase (gp300) and the Heymann nephritis antigen (gp330) are structurally related membrane glycoproteins with a distinctive distribution in the proximal tubule brush border which may serve as markers for the microvillar and coated microdomains, respectively, of the apical plasmalemma.     

Arylamine N-acetyltransferase from chicken liver. I. Monoclonal antibodies, immunoaffinity purification, and amino acid sequences

Five monoclonal antibodies against arylamine acetyltransferase (EC 2.3.1.5) from the chicken liver were established by immunizing a mouse with a partially purified enzyme preparation. None of the antibodies cross-reacted with arylamine N-acetyltransferase from the livers of cow, rabbit, and rat, nor with arylalkylamine N-acetyltransferase from the chicken pineal gland, indicating a high specificity of the antibodies. By using the antibodies, two immunoaffinity purification procedures were elaborated: A partially purified enzyme preparation was incubated with the monoclonal antibody, and the resulting enzyme-IgG complex was separated by a protein A-Sepharose column. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a single protein band with a molecular mass of 34 kDa in addition to the heavy and light chains of IgG. Secondly, an immunoaffinity column was prepared by immobilizing a monoclonal antibody to Sepharose 4B. After a partially purified enzyme preparation was absorbed on the column, N-acetyltransferase activity was eluted with 1 M NaCl and 1 M urea. The eluted sample contained a single 34-kDa protein. The purified enzyme preferred arylamines to arylalkylamines as substrates, indicating that it was arylamine N-acetyltransferase. The purified protein was subjected to digestion by lysylendopeptidase and separated by high performance liquid chromatography. Partial amino acid sequences of three peptides were determined by a gas-phase sequence analyzer.     

Sugar hydrolases of the infant rat intestine and their arrangement of the brush border membrane.

Lactase and maltase, the predominant sugar hydrolases associated with the intestinal brush bordermembrane of the suckling rat, were purified essentially free of the other to near homogeneity (lactase at specific activity 23, maltase at specific activity 58), and their specific physiocochemical properties determined. Antisera prepared to each showed by immunodiffusion a single common precipitin line with pure enzyme and solubilized proteins of the brush border membrane. Brush border membranes were purified 26--35-fold from infant rat intestine. Membranes prepared from 10-day-old rats contained 32% protein, 43% lipid and 25% carbohydrate with lactase and maltase estimated to comprise in excess of 10% and 2%, respectively, of the membrane protein. Immunotitration curves of lactase and maltase showed equivalent antibody binding by the membrane-bound and free enzyme forms. Furthermore, antibody binding to one enzyme did not affect the immunotitration curve or the extractability (by papain or Triton X-100) of the other membrane-bound enzyme. It was concluded that the lactase and maltase molecules are attached singly on the external membrane surface in a spatially independent manner with their antigenic sites as freely available to antibody binding as exhibited by their papain-solubilized counterparts.     

Intestinal absorption of dipeptides and beta-lactam antibiotics. II. Purification of the binding protein for dipeptides and beta-lactam antibiotics from rabbit small intestinal brush border membranes

By photoaffinity labeling of brush border membrane vesicles from rabbit small intestine with photoreactive derivatives of beta-lactam antibiotics and dipeptides, a binding protein for dipeptides and beta-lactam antibiotics with an apparent molecular weight of 127,000 was labeled. The labeled 127 kDa polypeptide could be solubilized with the non-ionic detergents Triton X-100, n-octyl glucoside or CHAPS. If the vesicles were solubilized prior to photoaffinity labeling, no clear incorporation of radioactivity into the 127 kDa polypeptide occurred indicating a loss of binding ability upon solubilization. By affinity chromatography of solubilized brush border membrane proteins on an agarose wheat germ lectin column, the binding protein for dipeptides and beta-lactam antibiotics of Mr 127,000 was retained on the column. With N-acetyl-D-glucosamine the photolabeled binding protein for beta-lactam antibiotics and dipeptides was eluted together with the brush border membrane-bound enzyme aminopeptidase N. Separation from aminopeptidase N and final purification was achieved by anion-exchange chromatography on DEAE-sephacel. Polyclonal antibodies against the purified binding protein were raised in guinea pigs. The photolabeled 127 kDa protein could be precipitated from solubilized brush border membranes with these antibodies. Incubation of brush border membrane vesicles with antiserum prior to photoaffinity labeling significantly reduced the extent of labeling of the 127 kDa protein. Treatment of brush border membrane vesicles with antiserum significantly inhibited the efflux of the alpha-aminocephalosporin cephalexin from the brush border membrane vesicles compared to vesicles treated with preimmune serum. These studies indicate that the binding protein for dipeptides and beta-lactam antibiotics of apparent molecular weight 127,000 in the brush border membrane of rabbit small intestinal enterocytes is directly involved in the uptake process of small peptides and orally active beta-lactam antibiotics across the enterocyte brush border membrane.     

Characterization of a processing protease that converts the precursor form of gamma-glutamyltranspeptidase to its subunits

Previously it was found that the proteolytic processing of precursors of gamma-glutamyltranspeptidase takes place on the brush border membrane of the kidney. The activity of the processing protease in purified brush border membranes was examined using endogenous substrates labeled with [3H]fucose and [35S]methionine. On incubation with brush border membranes in vitro, the precursors were converted stoichiometrically to two subunits, and the reaction followed first order kinetics with a rate constant k of -0.048 min-1. The enzyme responsible for this conversion was membrane-bound, had a weakly basic optimum pH and was inhibited by serine protease inhibitors. These results suggest that the precursor of gamma-glutamyltranspeptidase is processed to the mature form by a serine protease bound to the brush border membrane of kidney.     

Brush border membrane hydrolysis of S-benzyl-cysteine-p-nitroanilide, and activity of aminopeptidase M

A peptidase activity which can hydrolyze cysteinylglycine and S-benzyl-cysteine-p-nitroanilide was purified from rat renal brush border membranes. The purified peptidase exhibits an even greater specific activity when assayed with substrates for aminopeptidase M, leucine-p-nitroanilide and alanine-p-nitroanilide. All three activities copurify and coelectrophorese. In addition titration of the three activities in isolated brush border membrane vesicles with Fab antibodies prepared against the highly purified peptidase produced similar inactivation profiles. Therefore, the activity within brush border membrane towards S-benzyl-cysteine-p-nitroanilide is due to the action of aminopeptidase M (EC 3.4.11.2.)     

Subcellular localization of enterokinase in human small intestine

Enterokinase (enteropeptidase, EC 3.4.4.8) was found to be purified to the same extent as sucrase and alkaline phophatase when human intestinal brush border membrane was isolated. It is concluded that, in man as in other mammals, enterokinase activity occurs in close association with the brush border membrane.However, a second localization was also found. A fraction of the mucosal homogenate containing only small amounts of brush border but large amounts of endoplasmic reticulum, basolateral membranes and mitochondria (Fraction P₁) contained a disproportionately high amount of enterokinase. The enzyme in this particulate fraction occurred in a not fully active form.     

Affinity purification of insulin-degrading enzyme and its endogenous inhibitor from rat liver.

A metallothiol protease called insulin-degrading enzyme (IDE) seems to be implicated in insulin metabolism to terminate the response of cells to hormone, as well as in other biological functions, including muscle differentiation, regulation of growth factor levels, and antigen processing. In order to obtain highly pure and biologically active IDE, we have developed an immunoaffinity method using a monoclonal antibody to this enzyme (9B12). When the cytosolic fraction of rat liver was first applied to a 9B12-coupled Affi-Gel 10 column, more than 97% of the insulin-degrading activity was absorbed. Among various kinds of buffers successfully eluting the enzyme, only the buffer with a high pH (pH 11) could retain the full biological activity of this enzyme. IDE was further purified via two steps of chromatography using Mono Q anion exchange and Superose 12 molecular sieve columns. The final preparation showed a single band at 110 kDa on reduced sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). In the eluate from the immunoaffinity column, the inhibitory activity associated with the enzyme was also observed. To better recover this endogenous inhibitor, heat-treated cytosolic fraction was fractionated by ammonium sulfate precipitation and applied to the immunoaffinity column on which IDE had been adsorbed. Then, IDE and its inhibitor could be co-eluted with pH 11 as a complex form. After heat treatment of this fraction, the inhibitor was further purified using the same series of chromatography as IDE to more than 20,000-fold; it showed a 14 kDa band on SDS-PAGE. It inhibited both the insulin degradation by IDE in a competitive manner and the cross-linking of 125I-insulin to IDE. Highly purified IDE and the endogenous inhibitor will be useful tools for better understanding the various biological functions of this enzyme.     

Distribution and biosynthesis of aminopeptidase N and dipeptidyl aminopeptidase IV in rat small intestine

The regional, cellular and subcellular distribution patterns of aminopeptidase N and dipeptidyl aminopeptidase IV were examined in rat small intestine. Aminopeptidase N of brush border membrane had maximal activity in the upper and middle intestine, while dipeptidyl aminopeptidase IV had a more uniform distribution profile with relatively high activity in the ileum. Along the villus and crypt cell gradient, the activity of both enzymes was maximally expressed in the mid-villus cells. However there was substantial dipeptidyl aminopeptidase IV activity in the crypt cells. Both enzymes were primarily associated with brush border membranes in all segments, however, in the proximal intestine, a significant amount of dipeptidyl aminopeptidase IV activity was associated with the cytosol fraction. The cytosol and brush border membrane forms of dipeptidyl aminopeptidase IV were immunologically identical and had the same electrophoretic mobility on disc gels. In contrast, the soluble and brush border membrane-bound forms of aminopeptidase N were immunologically distinct. When the total amount of aminopeptidase N and dipeptidyl aminopeptidase IV was determined by competitive radioimmunoassay, there were no regional or cellular differences in specific activity (enzyme activity/mg of enzyme protein) of either enzyme in brush border membrane and homogenate. The specific activity of both enzymes in a purified Golgi membrane fraction as measured by radioimmunoassay was about half that of the brush border membrane fraction. These results suggest that (1) aminopeptidase N and dipeptidyl aminopeptidase IV have different regional, cellular and subcellular distribution patterns; (2) there are enzymatically inactive forms of both enzymes present in a constant proportion to active molecules and that (3) a two-fold activation of precursor enzyme forms occurs during transfer from the Golgi membranes to the brush border membranes.     

Immunoaffinity purification and characterization of vacuolar H+ATPase from bovine kidney

Vacuolar proton-translocating ATPase from bovine kidney was purified in one step by immunoprecipitation and immunoaffinity chromatography using an immobilized anti-H+ATPase monoclonal antibody. The monoclonal antibody affinity matrix coprecipitated polypeptides with Mr of 70,000, a cluster at 56,000, 45,000, 42,000, 38,000, 33,000, 31,000, 15,000, 14,000, and 12,000 from solubilized bovine kidney microsomal membranes, a pattern that was unaffected by different detergent washing conditions. A nearly identical pattern of polypeptides was observed in H+ATPase partially purified by an entirely independent method. The immunoaffinity purified H+ATPase had reconstitutively active ATP-induced acidification and potential generation that was inhibited by N-ethylamaleimide. The purified enzyme had specific activities as high as 3.1 mumol/min/mg protein, dual pH optima at 6.5 and 7.2, and a Km for ATP of 150 microM. The substrate preference was ATP greater than ITP much greater than UTP greater than GTP greater than CTP. The affinity purified H+ATPase was stimulated by phosphatidyl glycerol greater than phosphatidyl inositol much greater than phosphatidyl choline greater than phosphatidyl serine. The immunoaffinity purified enzyme did not require monovalent anions or cations for activity, and the divalent cation preference for activity was Mn, Mg much greater than Ca greater than Co much greater than Sr, Ba. The enzyme was not inhibited by ouabain, azide, or vanadate, but had kappa 1/2 inhibitory concentrations of 22.2 microM for N-ethylmaleimide, 14.9 microM for NBD-Cl, 4.9 microM for N,N'-dicyclohexylcarbodiimide, 13.8 microM for 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid, and 315 microM for Zn, values close to those for inhibition of proton transport in the native vesicles. The affinity purified kidney enzyme has similarities to but also significant differences in structural and enzymatic properties from those reported for other vacuolar H+ATPase.     

Conformational change of rabbit aminopeptidase N into enterocyte plasma membrane domains analyzed by flow cytometry fluorescence energy transfer

Membrane vesicle preparations are very appropriate material for studying the topology of glycoproteins integrated into specialized plasma membrane domains of polarized cells. Here we show that the flow cytometric measurement of fluorescence energy transfer used previously to study the relationship between surface components of isolated cells can be applied to membrane vesicles. The fluorescein and rhodamine derivatives of a monoclonal antibody (4H7.1) that recognized one common epitope of the rabbit and pig aminopeptidase N were used for probing the oligomerization and conformational states of the enzyme integrated into the brush border and basolateral membrane vesicles prepared from rabbit and pig enterocytes. The high fluorescent energy transfer observed in the case of pig enzyme integrated into both types of vesicles and in the case of the rabbit enzyme integrated into basolateral membrane vesicles agreed very well with the existence of a dimeric organization, which was directly demonstrated by cross-linking experiments. Although with the latter technique we observed that the rabbit aminopeptidase was also dimerized in the brush border membrane, no energy transfer was detected with the corresponding vesicles. This indicates that the relative positions of two associated monomers differ depending on whether the rabbit aminopeptidase is transiently integrated into the basolateral membrane or permanently integrated into the brush border membrane. Cross-linking of aminopeptidases solubilized by detergent and of their ectodomains liberated by trypsin showed that only interactions between anchor domains maintained the dimeric structure of rabbit enzyme whereas interactions between ectodomains also exist in the pig enzyme. This might explain why the noticeable change in the organization of the two ectodomains observed in the case of rabbit aminopeptidase N does not occur in the case of pig enzyme.     

Characterization of aminopeptidase N from Torpedo marmorata kidney

Summary— A major antigen of the brush border membrane of Torpedo marmorata kidney was identified and purified by immunoprecipitation. The sequence of its 18 N terminal amino acids was determined and found to be very similar to that of mammalian aminopeptidase N (EC 3.4.11.2). Indeed aminopeptidase N activity was efficiently immunoprecipitated by monoclonal antibody 180K1. The purified antigen gives a broad band at 180 kDa after SDS-gel electrophoresis, which, after treatment by endoglycosidase F, is converted to a thinner band at 140 kDa. This antigen is therefore heavily glycosylated. Depending on solubilization conditions, both the antigen and peptidase activity were recovered either as a broad peak with a sedimentation coefficient of 18S (2% CHAPS) or as a single peak of 7.8S (1% CHAPS plus 0.2 % C₁₂E₉), showing that Torpedo aminopeptidase N behaves as an oligomer stabilized by hydrophobic interactions, easily converted into a 160 kDa monomer. The antigen is highly concentrated in the apical membrane of proximal tubule epithelial cells (600 gold particles/μm² of brush border membrane) whereas no labeling could be detected in other cell types or in other membranes of the same cells (basolatéral membranes, vacuoles or vesicles). Monoclonal antibodies prepared here will be useful tools for further functional and structural studies of Torpedo kidney aminopeptidase N.     

Analytical isolation of plasma membranes of intestinal epithelial cells: identification of Na, K-ATPase rich membranes and the distribution of enzyme activities.

A procedure was developed for the analytical isolation of brush border and basal lateral plasma membranes of intestinal epithelial cells. Brush border fragments were collected by low speed centrifugation, disrupted in hypertonic sorbitol, and subjected to density gradient centrifugation for separation of plasma membranes from nuclei and core material. Sucrase specific activity in the purified brush border plasma membranes was increased fortyfold with respect to the initial homogenate. Basal lateral membrane were harvested from the low speed supernatant and resolved from other subcellular components by equilibrium density gradient centrifugation. Recovery of Na, K-ATPase activity was 94%, and 61% of the recovered activity was present in a single symmetrical peak. The specific activity of Na, K-ATPase was increased twelvefold, and it was purified with respect to sucrase, succinic dehydrogenase, NADPH-cytochrome c reductase, nonspecific esterase, beta-glucuronidase, DNA, and RNA. The observed purification factors are comparable to results reported for other purification procedures, and the yield of Na, K-ATPase is greater by a factor of two than those reported for other procedures which produce no net increase in the Na, K-ATPase activity. Na, K-ATPase rich membranes are shown to originate from the basal lateral plasma membranes by the patterns of labeling that were produced when either isolated cells or everted gut sacs were incubated with the slowly permeating reagent 35S-p-(diazonium)-benzenesulfonic acid. In the former case subsequently purified Na, K-ATPase rich and sucrase rich membranes are labeled to the same extent, while in the latter there is a tenfold excess of label in the sucrase rich membranes. The plasma membrane fractions were in both cases more heavily labeled than intracellular protein. Alkaline phosphatase and calcium-stimulated ATPase were present at comparable levels on the two aspects of the epithelial cell plasma membrane, and 25% of the acid phosphatase activity was present on the basal lateral membrane, while it was absent from the brush border membrane. Less than 6% of the total Na, K-ATPase was present in brush border membranes.