Structural and topological homology between porcine intestinal and renal brush border aminopeptidase

Effect of cross-linkers on the structure and function of pig-renal sodium-glucose cotransporters after papain treatment

Kidney brush-border membranes contain two sodium-dependent glucose transporters, one with low and one with high affinity for phlorizin, the specific inhibitor of these transporters. Using Scatchard analysis of phlorizin binding and Western blotting with specific antibodies against these transporters, we demonstrate in this study that although both transporters were proteolysed by papain treatment, only the high-affinity phlorizin-binding sites were decreased. Papain treatment followed by cross-linking with homobifunctional disuccinimidyl tartarate restored only the structure of the low-affinity phlorizin-binding protein (approx. molecular mass 70 kDa) without modifying the phlorizin-binding sites. When disuccinimidyl tartarate was replaced with dithiobis(succinimidyl acetate), another homobifunctional cross-linker with a higher spacer arm, the low- and high-affinity sites were both restored, with reappearance of two phlorizin-binding proteins with approx. molecular masses of 70 and 120 kDa. We conclude that high-affinity phlorizin-binding sites depend on the presence of the heterodimeric 120 kDa protein.

Characterization of a 43 kD protein associated to aminopeptidase A from murine kidney

SDS-PAGE of affinity-purified APA under reducing conditions showed in addition to the specific APA band of M(r) 130 kD, a second band of M(r) 43 kD. Internal amino acid sequencing of three tryptic peptides from this second band, that was cut out of the polyacrylamide gel, matched the actin sequence. The identity of the 43 kD band was also confirmed by Western blotting.

Solubilization and molecular characterization of the nitrobenzylthioinosine binding sites from pig kidney brush-border membranes

The nitrobenzylthioinosine binding sites from luminal membranes of proximal tubule of pig kidney were solubilized by treatment of the brush-border membrane vesicles with the zwitterionic detergent CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate) in 2% solution. The high yield solubilization of a stable form of the transporter took place in the presence of adenosine in the medium of incubation with the detergent and the additional presence of glycerol as stabilizer. The solubilization of the NBTI-sensitive nucleoside transporter from pig kidney brush-border membranes did not change the nitrobenzylthioinosine (NBTI) binding characteristics; the only major change was a 3-fold decrease in the affinity. The carrier molecule was cross-linked to [3H]NBTI and by electrophoretic characterization under reducing conditions it displayed a molecular mass of 65 kDa. Treatment of the samples at low temperature prior to electrophoresis gave rise to the appearance of further bands corresponding to dimeric and tetrameric forms which interacted non-covalently. The removal of the N-linked oligosaccharides by treatment with endoglycosidase F shifted the molecular mass to 57 kDa. The chromatographic behaviour of the solubilized transporter was similar to that of human erythrocytes and differed from that found in pig erythrocytes. Since the molecular mass of the monomer before and after treatment with endoglycosidase F is the same for pig erythrocytes and pig kidney luminal membranes, the different chromatographic behaviour might result from tissue differences due to transcriptional variations or to posttranscriptional modifications of the transporter molecule.

Characterization of adenosine receptors in brush-border membranes from pig kidney

1. The adenosine receptors from pig kidney proximal tubules have been studied in membrane vesicle preparations derived from either luminal (brush-border membranes-BBM-) or basolateral (BL) sides. There was a substantial amount of A2-like NECA binding in both preparations, but the A1 subtype of adenosine receptors was not found in either BBM or BL membranes. The use of [3H]-CGS21680 which is a more specific ligand for A2a receptors revealed true adenosine receptors in the BBM. 2. The kinetic parameters for [3H]-CGS21680 binding to pig renal BBM were: Bmax = 1.48 pmol mg-1 protein and Kd = 150 nM. In the presence of Gpp(NH)p the affinity decreased (Kd = 220 nM), whereas the addition of Mg2+ induced a marked increase in affinity (Kd = 83 nM). These equilibrium constants are higher than those found for the A2a adenosine receptors present in pig brain striatal membranes (Kd = 12 nM), and are close to those found in rat renal BBM (Kd = 90 nM). 3. The order of potency of agonist and antagonists was not consistent with the presence of either A1 or A2 receptors, but it was very similar to the agonist order of potency for the A3 receptor subtype. Furthermore, the blockade of the [3H]-CGS21680 binding by both cholera and pertussis toxin further supports the view that the subtypes present in BBM are neither A1 nor A2. 4. Overall the results suggest the presence in BBM of an A3 receptor, or of a new subtype of adenosine receptor, which is linked to G proteins sensitive to both cholera and pertussis toxins.

Energetic coupling of Na-glucose cotransport

(1) Energetic coupling in Na-linked glucose transport in renal brush border membrane vesicles has been studied in terms of various carrier models differing with respect to reaction order (random vs. ordered), and to rate limitation of steps within the routes of carrier-mediated solute transfer (translation across the membrane barrier vs. binding/release between carrier and bulk solution). (2) By computer simulation it was found that effective energetic coupling requires the leakage routes to be significantly, if not predominantly, rate-limited by their (barrier-crossing) translatory steps. This does not apply to the transfer route of the ternary complex, as coupling is possible whether or not this route is rate-limited by the translatory step. (3) The system transports glucose in the absence of Na+ (uniport) and the unidirectional flux is stimulated by unlabeled glucose on the trans side (negative tracer coupling). It is concluded that glucose binds to the carrier on either side without Na, as would be consistent with either a random system or one mode of ordered system with mirror symmetry (glucose binds before Na) but inconsistent with either mode of glide symmetry. The tracer coupling appears to indicate that the rate coefficient of carrier-mediated glucose transfer exceeds that of the empty carrier. (4) The Na-linked zero-trans flow of glucose in either direction is strongly trans-inhibited by Na. This consistent with a random system in which Na blocks or retards the translocation of the glucose-free carrier, thereby reducing 'slipping' through an internal leakage route. It is also consistent with the above mentioned ordered system, (i.e., in the absence of Na-transport without D-glucose) if it is assumed that trans Na interferes with the dissociation of the ternary complex, thereby slowing the release of glucose. (5) Minimum equilibrium exchange of glucose is stimulated in the presence of Na. This appears to indicate that Na expands the flow density of carrier-mediated glucose transfer. This expansion does not result from a 'velocity effect' (the ternary complex moving faster than the binary glucose carrier complex), as Na fails to stimulate maximum equilibrium exchange. It can instead be accounted for by an 'affinity effect' (the affinity of the carrier for glucose being increased by Na) as Na depresses the Michaelis constant of equilibrium exchange.(ABSTRACT TRUNCATED AT 400 WORDS)

Intestinal uptake of dipeptides and beta-lactam antibiotics. I. The intestinal uptake system for dipeptides and beta-lactam antibiotics is not part of a brush border membrane peptidase

The uptake of beta-lactam antibiotics into small intestinal enterocytes occurs by the transport system for small peptides. The role of membrane-bound peptidases in the brush border membrane of enterocytes from rabbit and pig small intestine for the uptake of small peptides and beta-lactam antibiotics was investigated using brush border membrane vesicles. The enzymatic activity of aminopeptidase N was inhibited by beta-lactam antibiotics in a non-competitive manner whereas dipeptidylpeptidase IV was not affected. The peptidase inhibitor bestatin led to a strong competitive inhibition of aminopeptidase N whereas the uptake of cephalexin into brush border membrane vesicles was only slightly inhibited at high bestatin concentrations (greater than 1 mM). Modification of brush border membrane vesicles with the histidine-modifying reagent diethyl pyrocarbonate led to a strong irreversible inhibition of cephalexin uptake whereas the activity of aminopeptidase N remained unchanged. A modification of serine residues with diisopropyl fluorophosphate completely inactivated dipeptidylpeptidase IV whereas the transport activity for cephalexin and the enzymatic activity of aminopeptidase N were not influenced. With polyclonal antibodies raised against aminopeptidase N from pig renal microsomes the aminopeptidase N from solubilized brush border membranes from pig small intestine could be completely precipitated; the binding protein for beta-lactam antibiotics and oligopeptides of apparent Mr 127,000 identified by direct photoaffinity labeling with [3H]benzylpenicillin showed no crossreactivity with the aminopeptidase N anti serum and was not precipitated by the anti serum. These results clearly demonstrate that peptidases of the brush border membrane like aminopeptidase N and dipeptidylpeptidase IV are not directly involved in the intestinal uptake process for small peptides and beta-lactam antibiotics and are not a constituent of this transport system. This suggests that a membrane protein of Mr 127,000 is (a part of) the uptake system for beta-lactam antibiotics and small peptides in the brush border membrane of small intestinal enterocytes.

Identification and characterization of the major stilbene-disulphonate- and concanavalin A-binding protein of the porcine renal brush-border membrane as aminopeptidase N

A 130 kDa glycoprotein (GP 130) was purified from porcine renal brush-border membranes by affinity chromatography using immobilized 4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonate (SITS)- and concanavalin A-Sepharose. GP 130 was the major concanavalin A-binding protein in porcine renal brush-border membranes and also bound Ricinus communis (castor-bean) and wheat-germ agglutinins. Endo-beta-N-acetylglucosaminidase F reduced the molecular mass of GP 130 by 20 kDa as determined by SDS/PAGE, whereas endo-beta-N-acetylglucosaminidase H reduced the molecular mass by 5 kDa, showing that GP 130 contained both complex and high-mannose carbohydrate structures. Western-blot analyses using an antibody raised against GP 130 showed that it was localized to the brush-border membrane fraction and was present in a membrane fraction of the pig kidney cell line LLC-PK1. The N-terminal sequence and amino acid composition of GP 130 showed that GP 130 is similar to rat kidney zinc peptidase and human intestinal aminopeptidase N. GP 130 had aminopeptidase N enzymic activity and was inhibited by bestatin (Ki = 36 microM), 1,10-phenanthroline (Ki 30 microM), Zn2+ (Ki 26 microM), Cu2+ (Ki 260 microM), pre-incubation with EDTA and by a polyclonal antibody against GP 130. Bicarbonate and iodide blocked the binding of GP 130 to the SITS-affinity resin, showing that GP 130 has an anion-binding site. Neither these anions nor stilbene disulphonates affected the aminopeptidase N activity of GP 130.

Association of the intestinal brush-border membrane phospholipase A2 and lysophospholipase activities (phospholipase B) with a stalked membrane protein

We have attempted to determine the size and membrane orientation of a recently described rat jejunal brush-border protein possessing phospholipase A2 and lysophospholipase activities (phospholipase B) (Pind, S. and Kuksis, A. [1988] Biochim, Biophys. Acta 938, 211-221). The phospholipase A2 and lysophospholipase activities were renatured following nonreducing sodium dodecyl sulphate polyacrylamide gel electrophoresis of the total membrane proteins and were shown to migrate as a component of a protein band having a relative molecular mass of 170 kDa. This band accounted for approximately 1% of the total Coomassie Blue staining proteins. Phospholipase B was also shown to be solubilized from the membranes, in an active form, by a proteolytic digestion with papain. Papain solubilization resulted in a loss of the hydrophobic properties observed for the intact phospholipase. These results suggest that the active site of the phospholipase projects from the luminal surface of the membrane vesicles. In support of this, phospholipase activity towards exogenous, detergent-solubilized phosphatidylcholine was demonstrated under conditions in which the membranes remained intact. We conclude that the phospholipase B has the characteristics of a stalked, brush-border membrane protein and may be considered as another digestive enzyme anchored in this membrane.

Antigenic expression of aminopeptidase M, dipeptidyl-peptidase IV and endopeptidase by primary cultures from rabbit kidney proximal tubule

Techniques using microdissected tubules from rabbit kidney allow the isolation of well defined segments which can be cultured to obtain pure renal cell epithelia. From microdissected proximal tubules, we obtained epithelia the cells of which exhibit some of the antigenic expressions of the initial proximal cells. For this purpose, we used three monoclonal antibodies raised against apical brush border membranes of the proximal tubules. We determined with precision the identity and some of the molecular characteristics of the antigens bound by these three antibodies and found that they correspond to three hydrolases present in the brush borders of proximal renal cells (amino-peptidase, dipeptidyl-peptidase IV and endopeptidase). These apical markers are expressed by the growing cells of primary cultures from proximal tubules, suggesting strongly that they are effectively proximal cells and that no appreciable dedifferentiation occurred during the growth process. We have also shown that apical expression of these hydrolases on the plasma membrane of the epithelium occurred only after several days of culture and determined the complete polarization of the cells. Electron microscopy studies confirmed the degree of polarization of the cultured cells by the presence of numerous microvilli on their apical face.

Biochemical localization of hepatic surface-membrane Na+,K+-ATPase activity depends on membrane lipid fluidity

Membrane proteins of transporting epithelia are often distributed between apical and basolateral surfaces to produce a functionally polarized cell. The distribution of Na+,K+-ATPase [ATP phosphohydrolase (Na+/K+-transporting), EC 3.6.1.37] between apical and basolateral membranes of hepatocytes has been controversial. Because Na+,K+-ATPase activity is fluidity dependent and the physiochemical properties of the apical membrane reduces its fluidity, we investigated whether altering membrane fluidity might uncover cryptic Na+,K+-ATPase in bile canalicular (apical) surface fractions free of detectable Na+,K+-ATPase and glucagon-stimulated adenylate cyclase activities. Apical fractions exhibited higher diphenylhexatriene-fluorescence polarization values when compared with sinusoidal (basolateral) membrane fractions. When 2-(2-methoxyethoxy)ethyl 8-(cis-2-n-octylcyclopropyl)octanoate (A2C) was added to each fraction, Na+,K+-ATPase, but not glucagon-stimulated adenylate cyclase activity, was activated in the apical fraction. In contrast, further activation of both enzymes was not seen in sinusoidal fractions. The A2C-induced increase in apical Na+,K+-ATPase approached 75% of the sinusoidal level. Parallel increases in apical Na+,K+-ATPase were produced by benzyl alcohol and Triton WR-1339. All three fluidizing agents decreased the order component of membrane fluidity. Na+,K+-ATPase activity in each subfraction was identically inhibited by the monoclonal antibody 9-A5, a specific inhibitor of this enzyme. These findings suggest that hepatic Na+,K+-ATPase is distributed in both surface membranes but functions more efficiently and, perhaps, specifically in the sinusoidal membranes because of their higher bulk lipid fluidity.

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.

Monoclonal autoantibodies specific for kidney proximal tubular brush border from mice with experimentally induced chronic graft-versus-host disease

Nine hybridomas producing monoclonal autoantibodies specific for kidney proximal tubular brush border were found in 600 hybridomas derived from (C57BL/6J X DBA/2)F1 mice injected with DBA/2 T cells. None of the 1100 hybridomas derived from nonautoimmune (C57BL/6J X DBA/2)F1 mice produced antibodies with a similar specificity. Four of these nine monoclonal antibodies were characterized further. They did not bind to cryosections of liver, lung, stomach, or intestine. Three bound to kidney proximal tubular brush border of mouse, cattle, sheep, pigs, rabbits, rats, and humans, whereas the fourth was specific only for murine brush border. All four precipitated from mouse kidney microvilli, a protein with an apparent molecular weight of 160,000 under reducing as well as nonreducing conditions. Removal of asparagine-linked carbohydrate with EndoF reduced the molecular weight of the 160,000 protein by about 20,000. One of the three multi-species-specific antibodies bound to pig kidney aminopeptidase, a glycosylated enzyme located on the microvilli of kidney proximal tubular brush border. Three antibodies have a heavy-chain variable region encoded by VH genes of the J558 family, whereas the heavy-chain variable region of the fourth is encoded by a VH gene of the 7183 family. Attempts to passively transfer immune complex glomerulonephritis to normal mice by injection of the purified monoclonal antibodies or by growth of the corresponding hybridoma cells in mice have so far been unsuccessful. However, antibodies recognizing the 160,000 molecule are present in the serum of mice with chronic graft-versus-host disease and can be eluted from kidneys with immune complex glomerulonephritis.

Immunocytochemical localization of aminopeptidase N on the cell surface of isolated porcine thyroid follicles

The ultrastructural location of aminopeptidase N on the cell surface of isolated porcine thyroid follicle cells was studied with immunocytochemistry using antibodies against intestinal aminopeptidase N and protein A-colloidal gold. Gold particles, indicating immunoreactivity, were selectively attached to the apical cell surface. Occasionally, there was a sparse labelling of the basal cell surface. In follicles kept at 4 degrees C most gold particles at the apical cell surface appeared as clusters, with each gold particle situated at a constant distance of about 20 nm from the membrane surface. The gold particles were concentrated on the membranes of microvilli, in comparison to the smooth (intermicrovillar) portions of the apical plasma membrane. In follicles incubated at 37 degrees C for 5-180 min gold particles were slowly internalized by predominantly smooth-surfaced micropinocytic vesicles and subsequently appeared in colloid droplets and lysosomes. Gold particles were not observed in Golgi cisternae. TSH did not appear to influence the rate of internalization. TSH-induced pseudopods were unlabeled. Our electron-microscopic observations confirm previous immunofluorescence-microscopic evidence that aminopeptidase N is selectively expressed in the apical plasma membrane domain in the thyroid follicle cell. Furthermore, aminopeptidase N appears to be distributed in microdomains within the apical plasma membrane. Earlier indications of molecular differences between the pseudopod membrane and the apical plasma membrane proper are further emphasized.

Apical trehalase expression associated with cell patterning after inducer treatment of LLC-PK1 monolayers

Trehalase, a differentiation-specific marker of renal proximal tubule brush border membrane, is expressed in confluent long-term cultures of the renal epithelial cell line LLC-PK1. The level of trehalase is greatly increased after treatment of cultures with differentiation inducers such as hexamethylene bisacetamide (HMBA), accompanied by increases in other apical membrane-associated differentiated functions (Yoneyama and Lever: J. Cell. Physiol. 121: 64-73, 1984). In the present study, we utilize a polyclonal antibody specific for renal trehalase to demonstrate that trehalase expression induced in LLC-PK1 cultures after HMBA treatment is localized in cells forming a three-dimensional network of strands across the confluent monolayer. The antitrehalase antibody recognized an apical membrane antigen of apparent molecular weight 100-110 kD both in LLC-PK1 cultures and in the corresponding pig renal brush border membranes. Strand formation and total trehalase activity increased in parallel as a function of inducer concentration and duration of exposure. Strand formation and trehalase expression were also greatly enhanced in monolayers grown on a Nuclepore filter support even in the absence of inducer. Strand formation was not a prerequisite for induced trehalase expression in culture, since strands did not develop in cultures treated with N, N'-dimethylformamide (DMF) and equally potent inducer of trehalase expression. In this case, cells which expressed increased levels of trehalase were dispersed at random over the monolayer. Induction of strand formation and trehalase expression by HMBA required a minimum exposure period of 48 hr and persisted up to a week after removal of inducer. By contrast, the response to DMF required continuous presence of inducer. Levels of trehalase declined even in the continuous presence of inducer in local regions of low cell density created by wound-repair of the monolayer. In addition to the membrane-bound form, trehalase activity was also recoverable from the culture medium, but release of trehalase was not affected by inducers. These observations are consistent with the view that a cell type committed to express a program of differentiation after HMBA treatment or growth on a permeable support is organized in specific cell patterns visible as strands over the confluent cell monolayer.

Purification and properties of detergent-solubilized pig kidney trehalase

Trehalase (alpha, alpha-trehalase, EC 3.2.1.28) was solubilized from the brush border membrane of pig kidney cortex by Triton X-100 and sodium deoxycholate in the presence of inhibitors of proteolytic enzymes. The kidney enzyme was purified 3060-fold using gel filtration, ion exchange chromatography, Con A-Sepharose chromatography, phenyl-Sepharose CL-4B hydrophobic interaction chromatography, Tris-Sepharose 6B affinity chromatography, and hydroxylapatite chromatography. Tris-Sepharose 6B was utilized to absorb contaminant proteins. Purity was estimated as 99% or greater, based on amino-terminal amino acid analysis. The purified enzyme had a specific activity of 278 units/mg protein, showed one major band after silver staining, and had an estimated molecular weight of 80,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme was a glycoprotein and contained 2 mol of glucosamine per mole of trehalase. Kidney trehalase was inhibited by Tris, HgCl2, and phlorizin with Ki values of 3.8 mM, 11 microM, and 2.4 mM, respectively. Inclusion of Cl- in the reaction mixture protected the enzyme from inactivation by HgCl2. The apparent Km for trehalose was calculated to be 2.1 mM. Kidney trehalase was highly specific for trehalose and exhibited an optimal pH of 5.9. The isoelectric point was between pH 4.7 and 4.4, as measured by chromatofocusing.

Reconstitution of brush border membrane proteins in phosphatidylcholine vesicles. Biochemical and functional characterization

Horse kidney brush border membrane proteins were incorporated into phosphatidylcholine vesicles. Structural analysis of proteoliposomes prepared with various lipid:protein ratios showed that: (a) only a few of the proteins present in the crude brush border extract are integrated, (b) all known membrane hydrolases are integrated, and (c) these proteoliposomes are homogeneous vesicles. Papain solubilization of brush border membrane hydrolases, i.e. aminopeptidase M, neutral alpha-glucosidase, gamma-glutamyltransferase and alkaline phosphatase, performed in parallel on native membrane vesicles and proteoliposomes, revealed similar kinetics. Analysis of membrane vesicles and proteoliposomes on sucrose density gradients either without any treatment, or after papain treatment showed that: (a) in proteoliposomes, neutral alpha-glucosidase is associated with radiolabelled phosphatidylcholine, and (b) papain-treated vesicles and proteoliposomes released enzyme activity in the same way. These results suggest that the integration mechanism of brush border membrane proteins may be similar in proteoliposomes and native membrane vesicles. Transport experiments under equilibrium exchange conditions showed that the uptake properties of proteoliposomes are similar to those of brush border membrane vesicles.

Aminopeptidase N- and human blood group A-antigenicity along the digestive tract and associated glands in the rabbit

The cellular localization of an aminopeptidase N homologous to the brush-border intestinal enzyme and that of human blood group A-substances were investigated using the immunofluorescence technique on thin frozen sections (200 nm) of the digestive tract and associated glands of A+ and A- rabbits. Aminopeptidase N was found to be a common specific marker of both the apical region of plasma membrane of acinar cells in submaxillary and parotid glands and pancreas and the brush border of jejunum and colon absorbing cells. In hepatocytes, the enzyme was localized in the sinusoidal domains. Soluble A-substances were present in mucus secretory granules of intestinal goblet cells and those of stomach and gall bladder mucous cells. In contrast, the mucous acini of sublingual and submaxillary glands were devoid of A-antigenicity. The columnar cells of striated ducts of these glands exhibited A-antigenicity. Soluble A-substances were also found in zymogen granules of parotid and pancreas acinar cells and those of stomach chief cells. Moreover, in all cells secreting A-substances, and in the non-secreting absorbing intestinal cells, the glycoproteins of the plasma membrane bore A-determinants. Aminopeptidase N was one of the membrane-bound glycoproteins that bore A-determinants in cells that expressed A-antigenicity.

Rat intestinal brush border membrane trehalase: some properties of the purified enzyme

Rat intestinal brush border trehalase (EC 3.2.1.28) solubilized by Triton X-100 or Emulphogen BC 720 has been purified almost to homogeneity in a five steps procedure including DEAE cellulose, Sephadex G-200, preparative flat bed electrofocusing and hydroxylapatite. The apparent molecular weight was estimated to be about 65,500 daltons by mannitol density gradient ultracentrifugation. The optimum pH of the enzyme was between 5.5 and 5.7 in phosphate, maleate or citrate buffers. The apparent Km for trehalose was found to be 10 mM in maleate buffer pH 6.0. The isoelectric point was 4.9. Tris, P-aminophenylglucoside, sucrose and maltose are fully competitive inhibitors with Kis of 2.2, 1.8, 7.7 and 170 mM, respectively. The inhibition by Phloridzin appeared to be of the mixed type with a Ki of 1.7 mM. Trehalase is heat stable up to 50 degrees C and the activation energy is 10.96 kcal/mol. Schiff's staining on polyacrylamide gel and interaction with Con-A-Sepharose indicate that rat trehalase is a glycoprotein.

Structural state of the Na+/D-glucose cotransporter in calf kidney brush-border membranes. Target size analysis of Na+-dependent phlorizin binding and Na+-dependent D-glucose transport

Target sizes of the renal sodium-D-glucose cotransport system in brush-border membranes of calf kidney cortex were estimated by radiation inactivation. In brush-border vesicles irradiated at -50 degrees C with 1.5 MeV electron beams, sodium-dependent phlorizin binding, and Na+-dependent D-glucose tracer exchange decreased exponentially with increasing doses of radiation (0.4-4.4 Mrad). Inactivation of phlorizin binding was due to a reduction in the number of high-affinity phlorizin binding sites but not in their affinity. The molecular weight of the Na+-dependent phlorizin binding unit was estimated to be 230 000 +/- 38 000. From the tracer exchange experiments a molecular weight of 345 000 +/- 24 500 was calculated for the D-glucose transport unit. The validity of these target size measurements was established by concomitant measurements of two brush-border enzymes, alkaline phosphatase and gamma-glutamyltransferase, whose target sizes were found to be 68 570 +/- 2670 and 73 500 +/- 2270, respectively. These findings provide further evidence for the assumption that the sodium-D-glucose cotransport system is a multimeric structure, in which distinct complexes are responsible for phlorizin binding and D-glucose translocation.

A domain-specific marker for the hepatocyte plasma membrane. II. Ultrastructural localization of leucine aminopeptidase to the bile canalicular domain of isolated rat liver plasma membranes

Leucine aminopeptidase (LAP) is an integral membrane glycoprotein localized to the apical membrane domain of intestinal and kidney epithelial cells. By indirect immunofluorescence, we have shown that antibodies raised against rat intestinal LAP recognized a similar protein concentrated in the bile canalicular (BC) domain of the hepatocyte in situ (Roman, L.M., and A.L. Hubbard, 1983, J. Cell Biol., 96:1548-1558). We have extended this localization to the ultrastructural level. When a saponin-permeabilized, agarose-embedded plasma membrane (PM) fraction was incubated with affinity-purified anti-LAP, 85% of the protein A-gold particles associated with the three recognizable PM domains were present in the BC. The levels of labeling on the other two domains (sinusoidal and lateral) did not exceed that observed with nonimmune controls. The concentration of LAP in the BC domain in isolated PM sheets prompted us to use this antigen for the affinity isolation of BC membrane (Roman, L.M., and A.L. Hubbard, 1984, J. Cell Biol., 98:1497-1504, companion paper).

Effect of K+ and H+ on sodium/citrate cotransport in renal brush-border vesicles

The uptake of citrate by renal brush-border vesicles, prepared according to the method of Vannier, occurs by Na+-linked cotransport. It is 'positive rheogenic', i.e., stimulated by an (inside) negative, and inhibited by an (inside) positive electrical potential. The question arises whether, besides Na+, other ions (e.g., K+ and H+) participate in the cotransport. As to K+, neither an inward nor an outward directed K+ gradient has a significant effect on the citrate movement, but at equal concentrations of K+ inside and outside, equilibrium exchange of citrate, and to a smaller extent, the Na+-linked net uptake of citrate, are significantly stimulated. This observation is consistent with a hypothetical model in which K+ acts by accelerating both the empty and the fully loaded translocator. As to H+, citrate uptake is also stimulated by decreasing extravesicular pH, an effect previously attributed to protonization of the citrate anion in the assumption that the resulting secondary citrate anion is more acceptable to the translocator site. It was found, however, that the pH effect is still apparent if the concentration of the secondary citrate is kept constant by adjusting the total citrate concentration. This is taken as an argument against the above assumption and as being consistent with H+-linked cotransport. After the overshoot peak citrate exits slowly, and even after several hours does not attain equilibrium distribution, presumably owing to trapping by vesicular calcium.

Temperature dependence of D-glucose transport in reconstituted liposomes

Sodium-dependent D-glucose uptake into proteoliposomes reconstituted from dimyristoylphosphatidylcholine (DMPC) and hog kidney brush border membrane extract is strongly affected by temperature and the physical state of the membranes. This dependence is defined by a nonlinear Arrhenius plot with a break point at 23 degrees C, a temperature not significantly different from the phase transition temperature of the pure lipid (24 degrees C). The transport process is characterized by different activation energies: 35.1 kcal/mol below and 5.5 kcal/mol above the transition temperature. The shift in the break point for the D-glucose transport activity from 15 degrees C, in the brush border membranes, to 23 degrees C in the reconstituted system leads us to conclude that the lipids surrounding the sodium/D-glucose cotransport system can exchange readily with the bulk lipid used for reconstitution. The results thus provide no evidence for the presence of an annulus of specific lipids surrounding the transport system.

Association of renal dipeptidase with the Triton-insoluble fraction of kidney microvilli

Renal dipeptidase, previously identified as a component of renal microvilli, has been investigated to determine its orientation within this organelle. Digestion of porcine renal microvilli with papain released essentially all of aminopeptidase M, an outer membrane marker enzyme from the microvilli within one hour; whereas less than 10% of renal dipeptidase was released under the same conditions. Antibody to purified renal dipeptidase produced 50% inhibition of the purified enzyme at an antibody/antigen molar ratio of 2:1. Inhibition by the renal dipeptidase-directed antibody was not observed when the enzyme was bound within the microvillar structure. Demembranation of the microvilli with Triton X-100 resulted in a distribution of 68% of renal dipeptidase in the insoluble pellet and 32% in the soluble supernatant. The same detergent treatment released 92% of animopeptidase M into the supernatant. These results indicate that renal dipeptidase is not located at the luminal surface of the microvillus membrane where it would be available for release of papain, inhibition by antibody, or solubilization by detergent. Fractionation of the Triton-insoluble pellet with 2 M NaCl resulted in the release of 64% of the peptidase into a pellicle fraction separated from insoluble pellet and soluble supernatant. Finally extraction of Triton-insoluble pellet with 0.05 mM ATP-0.10 mM MgCl2 X 6 H2O solubilized 57% of the renal dipeptidase.

A domain-specific marker for the hepatocyte plasma membrane: localization of leucine aminopeptidase to the bile canalicular domain

Indirect immunofluorescence was used to establish a domain-specific marker for hepatocyte plasma membranes. In frozen sections of fixed rat liver (0.5-4 microns), antibodies directed against rat intestinal leucine aminopeptidase (LAP) recognized an antigen that was restricted to the bile canalicular plasma membrane. Fluorescence was not observed on the sinusoidal or lateral membranes, and intracellular staining was not detected. The liver antigen was identified as LAP, based on its chemical similarity to intestinal LAP. First, immunoprecipitation experiments using trypsin-solubilized intestinal LAP (G-200 fraction, 91% pure) established a correlation between the loss of LAP enzyme activity from the soluble fraction and the appearance in the specific immunoprecipitates of polypeptides migrating on SDS PAGE between 110,000 and 130,000 daltons. The antigen precipitated from a detergent extract of liver plasma membranes had the same electrophoretic mobility. Second, the chymotryptic map of the major band in the liver immunoprecipitate was similar to that of purified intestinal LAP.

Influence of sodium ions on detergent solubilization of pig brush border D-glucose transport system for reconstitution experiments

The D-glucose uptake by liposomes resulting from the association of egg lecithins with solubilized membrane proteins was measured in order to assess their sodium dependent D-glucose transport activity. Membrane proteins were extracted by Triton X-100 solubilization of pig kidney brush border membrane vesicles, which were suspended either in KCl medium or in NaCl medium. When measured by equilibrium isotope exchange procedure in sodium conditions, the D-glucose uptake by sodium detergent extract associated to liposomes occurred with a higher velocity than that obtained with liposomes reconstituted from potassium detergent extract. No differences were observed in the permeability or in the protein content of two types of liposomes. These results are discussed in terms of activation of D-glucose transport system induced by sodium ions before membrane protein solubilization.

Synthesis of [3H]phlorizin and its binding behavior to renal brush-border membranes

Tetra- and tribromophlorizin have been synthesized under mild brominating conditions. With catalytic debromination in the presence of hydrogen or tritium gas, bromine atoms in the derivatives were completely substituted by hydrogen or tritium. The product was identical to the native phlorizin and was chemically pure. Tritiated phlorizin with extremely high specific radioactivity (45 Ci/mmol) was obtained when hydrogen gas was replaced by tritium gas. While the brominated compounds showed little inhibition of sodium D-glucose co-transport by isolated renal brush-border membranes. [3H]phlorizin had the same binding affinity to the brush-border membranes as native phlorizin and a Ki value of 1.2 microM for the sodium-dependent D-glucose transport. Binding studies performed using a flow-dialysis method resulted in 150 pmol of phlorizin-binding sites per milligram of membrane protein. This radioactive phlorizin can be a useful tool for determining D-glucose-(phlorizin) binding sites at a low phlorizin concentration in membranes, in nonvesicle forms such as collapsed membrane vesicles, and in purified protein fractions.

Renal sodium-D-glucose cotransport system. Involvement of tyrosine residues in sodium-transporter interaction

Using brush-border membrane vesicles isolated from calf kidney cortex the effect of tyrosine-reactive reagents on sodium-dependent D-glucose transport was investigated. Treatment of the membranes for 60 min with NBD-Cl (7-chloro-4-nitrobenzo-2-oxa-1,3-diazole), N-acetylimidazole or tetranitromethane decreased D-glucose uptake 50, 70 and 40%, respectively. Tracer exchange experiments revealed that the inhibition of transport is due to a direct modification of the sodium-D-glucose cotransport system. The modification by NBD-Cl decreases the apparent Vmax of the transport system with respect to its interaction with sodium. In addition, the rate of inactivation of the transport system by NBD-Cl is reduced in the presence of high concentrations of sodium. The results indicate that tyrosine residues play an essential role in sodium-D-glucose cotransport and are probably involved in the binding and/or transport of sodium by the sodium-D-glucose cotransport system.

Evidence that the hydrophobic domain of rat renal gamma-glutamyltransferase spans the brush border membrane

Lactoperoxidase and glucose oxidase catalyzed 125I-iodination was used to specifically label isolated rat renal brush border membrane vesicles from either side of the membrane. Autoradiography of total membrane proteins demonstrated that asymmetric labeling was achieved. Specific immunoprecipitates of aminopeptidase M, an established transmembrane protein, and of gamma-glutamyltransferase were isolated from vesicles solubilized with Triton X-100 or with papain. Following electrophoresis and autoradiography, the immunoprecipitates of the two solubilized forms of each enzyme derived from externally labeled vesicles exhibited the same intensity of labeling. In these experiments, and small subunit of the gamma-glutamyltransferase was preferentially labeled suggesting that, compared to the large subunit, it is more exposed on the external surface of the membrane. With the samples derived from internally labeled vesicles, the triton-solubilized form of each enzyme was intensely labeled, whereas the papain-solubilized forms contained insignificant amounts of radioactivity. Thus, the extent of contramembrane labeling was minimal. These experiments, the large subunit of the gamma-glutamyltransferase was preferentially labeled. The similarity of the labeling patterns obtained for aminopeptidase M and gamma-glutamyltransferase suggests that the hydrophobic domain of the two amphipathic enzymes are selectively labeled from the internal surface and that the gamma-glutamyltransferase may also be a transmembrane protein.

Immunochemical analysis of high molecular mass urinary proteins

Urinary high molecular mass proteins (fraction P) solubilized in Triton X-100 and by papain have been compared with the solubilized human renal brush border membrane proteins. Crossed immunoelectrophoresis of Triton X-100 fraction P extract, by means of two polyspecific antisera directed against either renal membrane or fraction P, revealed eleven immunoprecipitates antigenically identical with detergent renal membrane antigens. Among them, five hydrolases were identified by zymogram staining: microvillus aminopeptidase, maltase, trehalase, gamma-glutamyltransferase and alkaline phosphatase. Eight papain-solubilized fraction P proteins and Triton X-100-solubilized membrane extract presented 'identity' patterns in tandem crossed immunoelectrophoresis, but differed in their amphiphilicity, as demonstrated by the change of precipitation pattern on charge-shift caused immunoelectrophoresis. Among the eleven detergent-solubilized fraction P antigens, nine were proved to be amphiphilic proteins and six presented bidirectional charge shifting properties similar to those of renal membrane antigens. Quantitatively, five detergent fraction P proteins were found in the same amounts as in renal membrane extract, two in lesser amounts and four in greater. Moreover, the same two plasma proteins were identified in fraction P as in the renal membrane. Thus important similarities exist between the urinary fraction P and the native renal membrane.

Temperature dependence of solute transport and enzyme activities in hog renal brush border membrane vesicles

The temperature dependence of sodium-dependent and sodium-independent D-glucose and phosphate uptake by renal brush border membrane vesicles has been studied under tracer exchange conditions. For sodium-dependent D-glucose and phosphate uptake, discontinuities in the Arrhenius plot were observed. The apparent activation energy for both processes increased at least 4-fold with decreasing temperature. The most striking change in the slope of the Arrhenius plot occurred between 12 and 15 degrees C. The sodium-independent uptake of D-glucose and phosphate showed a linear Arrhenius plot over the temperature range tested (35-5 degrees C). The behavior of the transport processes was compared to the temperature dependence of typical brush border membrane enzymes. Alkaline phosphatase as intrinsic membrane protein showed a nonlinear Arrhenius plot with a transition temperature at 12.4 degrees C. Aminopeptidase M, an extrinsic membrane protein exhibited a linear Arrhenius plot. These data indicate that the sodium-glucose and sodium-phosphate cotransport systems are intrinsic brush border membrane proteins, and that a change in membrane organization alters the activity of a variety of intrinsic membrane proteins simultaneously.

Aminopeptidase N is a marker for the apical pole of porcine thyroid epithelial cells in vivo and in culture

An aminopeptidase N has been detected by immunofluorescence in the apical plasma membrane of porcine thyroid cells, facing the follicular lumen. Freshly isolated cells obtained by tissue trypsinization, lose their polarity and exhibit a homogeneous enzyme distribution over the whole plasma membrane. In thyrotropin-stimulated cultured cells organized into follicles, the enzyme is localized the apical cell pole. In monolayer cells, on the other hand, the enzyme is distributed over the whole surface facing the medium. In both types of cultures fluorescence is also observed in intracytoplasmic organelles. In vivo, aminopeptidase ia a marker of the apical part of the thyroid plasma membrane, but its in vitro localization depends upon cell differentiation related to the culture conditions.

Topology and some properties of the renal brush border membrane-bound peptidase(s) participating in the metabolism of S-carbamidomethyl glutathione

Topological features and some properties of the membrane-bound peptidase(s) participating in the metabolism of a glutathione S-conjugate in the kidney were studied. S-Carbamidomethyl glutathione, a model compound for glutathione S-conjugate, was demonstrated to be sequentially hydrolyzed by gamma-glutamyltransferase (5-glutamyl)-peptide:amino-acid 5-glutamyltransferase; EC 2.3.2.2) and peptidase(s) bound to rat renal brush border membrane vesicles. Hydrolysis of S-carbamidomethyl cysteinylglycine was found to be inhibited by 1,10-o-phenanthroline, suggesting a participation of a metal-requiring peptidase in this process. The hydrolytic activity of the membranous peptidase was markedly depressed by cysteinylglycine S-acetyldextran polymer (molecular weight, 500 000), a nonpermeating derivative for cysteinylglycine. Papain treatment of brush border membrane vesicles resulted in the solubilization of most hydrolytic activity toward S-carbamidomethyl cysteinylglycine. Amino-peptidase M was also solubilized from the membrane and the increase in the specific activity of this enzyme in the papain-soluble fraction was in parallel within that of the peptidase activity for hydrolysis of S-carbamidomethyl cysteinylglycine. The hydrolytic activity of purified brush border membrane vesicles toward S-carbamidomethyl glutathione was fully reconstituted by the combined use of purified gamma-glutamyltransferase and aminopeptidase M. These findings indicated that, as in the case of the cleavage of gamma-glutamyl linkage of glutathione and related compounds, hydrolysis of the S-substituted cysteinylglycine occurred exclusively on the lumenal surface of renal brush border membrane as catalyzed mainly by aminopeptidase M.

Crossed-immunoelectrophoretic study on human renal brush border membrane vesicles

The human kidney brush border membrane proteins were studied by crossed-immunoelectrophoresis. An antiserum against membrane vesicles was raised in rabbits and used in establishing a reference immunoelectrophoregram with the antigens released by Triton X-100. Among the precipitates observed, the following hydrolases were identified by zymogram staining: Microvillus aminopeptidase (EC 3..4.11.2), gamma-glutamyltransferase (EC 2.3.2.2), maltase (EC3.2.1.20) and trehalase (EC 3.2.1.28). Depletion of the antiserum with sealed, right-side-out vesicles was performed. No precipitates could be seen when the Triton X-100 extract was electrophoresed in a gel containing the depleted antibody. It is therefore suggested that the precipitation of membrane components by the complete antibody is mainly due to externally-located determinants and that the precipitates of the reference pattern correspond to membrane components pointing, at least in part, towards the tubular lumen. Evidence was also noted for a differential removal of antibodies directed against the different antigens. Such an observation could not be explained by the antigen accessibility nor by its amount in the membrane. Parallel crossed-immunoelectrophoresis of Triton X-100 and papain extracts gave rise to an "identity" pattern for only some antigens, particularly for microvillus aminopeptidase and maltase. It is thus strongly suggested that the papain-released form of these enzymes bears nearly all the antigenicity of the whole molecule.

Some kinetic properties of gamma-glutamyltransferase from rabbit liver

gamma-Glutamyltransferase ((5-glutamyl)-peptide: amino-acid 5-glutamyltransferase, EC 2.3.2.2) of rabbit liver (detergent form) was purified 1100-fold in order to study its kinetic properties. Kinetic studies were conducted from pH 6.0 to 12.0 in the absence and presence of the acceptor substrate glycylglycine using gamma-glutamyl-3-carboxy-4-nitroanilide as the donor. The existence of more than one binding site for both donor and acceptor is postulated on kinetic evidence such as donor substrate activation, donor substrate inhibition and acceptor substrate activation. Homotropic interaction is also observed, in the form of negative cooperativity, in donor substrate binding, in the absence of acceptor at pH less than 9.0 and positive cooperativity (n = 2), in the absence or presence of acceptor at pH greater than 9.0. Hydrolase reaction reaches a maximum of activity at pH 10 (pK 8.6). Transferase activity under conditions of maximal velocity is maximal at pH 9.0 (pK 7.1). The ratio of transferase activity/hydrolase activity is maximal at pH 7.0-7.5. At low donor substrate concentrations, maximal activity is attained at pH 7.5.

Enzymatic and immunological properties of the protease form of aminopeptidase N and A from pig and rabbit intestinal brush border

Immunological homology was shown between the active site regions of pig and rabbit aminopeptidases N and between those of the corresponding aminopeptidases A. However, no homology was detectable between the aminopeptidases N and A (EC 3.4.11.-) in a given species. The dimeric structure of pig aminopeptidases did not significantly modify their catalytic properties in aqueous solution compared to those of the monomeric rabbit enzymes. Only a slight difference in binding conditions was noted in the case of aminopeptidases N. Aminopeptidase A activity towards acidic substrates was enhanced by physiological concentrations of Ca2+ while that towards neutral substrates was considerably reduced. Therefore, acidic amino acid residues in proteins and peptides may be assumed to be mostly split off in vivo by aminopeptidase A, neutral residues by aminopeptidases N and basic residues by both enzymes. The respective specificity of aminopeptidase A and N for acidic and neutral amino acid residues was found to be mainly due to a more productive binding mode of the substrate rather than to a better affinity.

Partial purification of hog kidney sodium-D-glucose cotransport system by affinity chromatography on a phlorizin polymer

A brush border membrane fraction isolated from hog kidney cortex was solubilized with 0.5% Triton X-100 and subjected to affinity chromatography on a phlorizin polymer. As demonstrated by transport studies with reconstituted proteoliposomes, the polymer adsorbs the sodium-dependent D-glucose transport system. The latter can be eluted from the polymer by 0.5 M D-glucose. The purified fraction contains 0.4% of the membrane protein extract and exhibits a 20--30-fold higher transport activity than the crude membrane extract. Other brush border membrane proteins such as alkaline phosphatase and aminopeptidase M are markedly reduced in the purified fraction. Thus, affinity chromatography on a phlorizin polymer is a suitable tool for the isolation of the sodium-glucose transport system present in brush border membranes.

Inactivation of renal gamma-glutamyl transferase by 6-diazo-5-oxo-L-norleucylglycine, an inactive precursor of affinity-labeling reagent

In vitro experiments showed that 6-diazo-5-oxo-L-norleucylglycine, a dipeptide analog of L-glutaminylglycine, inactivates gamma-glutamyl transferase bound to renal brush border membrane vesicles but does not inactivate the purified transferase. The rate of inactivation of the membrane-bound enzyme decreased markedly in the presence of dipeptides, such as L-leucylglycine and L-alanylglycine, or in the presence of o-phenanthroline, an inhibitor of renal peptidases. The presence of L-cysteinylglycine S-acetyldextran polymer (Mr 500,000), which does not permeate membranes, protected the membrane-bound transferase from inactivation by 6-diazo-5-oxo-L-norleucyglycine. This and other findings suggest that the norleucylglycine derivative was hydrolyzed by peptidase(s) bound to the outer surface of the brush border membranes and that the 6-diazo-5-oxo-L-norleucine thus released acts as an affinity-labeling reagent for the membrane-bound transferase. Similar effects were observed in vivo. Intravenous administration of 6-diazo-5-oxo-L-norleucylglycine to mice resulted in a marked decrease in renal transferase activity. Mice thus pretreated with 6-diazo-5-oxo-L-norleucylglycine, but not an untreated group, excreted significant amounts of S-carbamido[14C]methylglutathione in their urine within 30 min of intravenous administration of this compound. This finding suggests that the renal transferase was involved in the hydrolysis of the glutathione S-conjugate in the glomerular filtrate in vivo and that the administered 6-diazo-5-oxo-L-norleucylglycine underwent hydrolysis peptidase(s)-catalyzed to liberate 6-diazo-5-oxo-L-norleucine that reacted with the membrane-bound gamma-glutamyl transferase.

A neutral endopeptidase in the microvillar membrane of pig intestine. Partial purification and properties

An enzyme hydrolysing [125I]iodo-insulin B chain was enriched in preparations of intestinal microvilli. The activity could be solubilized by Triton X-100 and was partially (76-fold) purified. It was very sensitive to inhibition by phosphoramidon and was also inhibited by chelating agents. In its enzymic, molecular and immunological properties the intestinal enzyme closely resembled kidney microvillar neutral endopeptidase (kidney-brush-border neutral proteinase, EC 3.4.24.11).

The molecular forms of gamma-glutamyl transferase in bile and serum of icteric rats

Alterations in the molecular form of gamma-glutamyl transferase (5-glutamyl)-peptide:amino-acid 5-glutamyltransferase, EC 2.3.2.2.) were studied in the bile and serum of rats under surgical ligation of the bile duct. Polyacrylamide gel electrophoresis of the bile, followed by the enzyme stain, revealed a major, slowly migrating broad band and a minor, faster migrating band. The former was converted to the latter upon limited proteolysis of the bile with a very small amount of papain. This conversion was accompanied by a decrease in molecular size of the enzyme. Both enzyme forms were specifically adsorbed to a concanavalin A-Sepharose column. Most of the papain-treated enzyme preparation could be eluted from the column by alpha-methyl-D-glucoside, a haptenic sugar of this lectin. On the other hand, the predominant form of the enzyme in the untreated bile was eluted only in the presence both of the sugar and Triton X-100. Based on the chromatographic behavior of the two enzyme forms (detergent-solubilized and protease-solubilized form) purified from rat renal brush border membrane on concanavalin A-Sepharose column, it was concluded that the predominant form of the enzyme in the bile was the detergent-solubilized form and that the minor component represents the protease-solubilized enzyme. The serum from icteric rats was also found to contain both types of the enzyme. However, the relative amount of the protease-solubilized form to the detergent-solubilized form in the serum was much greater than that in the bile. These findings suggested that gamma-glutamyl transferase in the hepatobiliary membrane systems was solubilized into the bile mainly as the detergent-solubilized form, and that, during the process of translocation into the blood circulation, the enzyme was partly converted to the protease-solubilized form by some protease-like action.

Endopeptidase of the brush border membrane of rat enterocyte. Separation from aminopeptidase and partial characterization

The brush border of the enterocytes of the rat was isolated by the method of differential centrifugation with CaCl2 according to Schmitz. This material was solubilized with papain, trypsin and Triton X-100. The greatest amount of membrane enzymes was released to the supernatant (105 000 X g) with the use of Triton X-100. The tritonized supernatant was treated in the next step by papain, bromelain, ficin and trypsin (individually or in combinations). After simultaneous proteolysis with papain and bromelain a partial separation of the aminopeptidase from the endopeptidase by Sephadex G-200 chromatography was observed. These two enzyme activities were distinctly separated by isoelectric focusing at pH 4--6. Two enzymatically active bands (RF 0.13 and 0.24) in the aminopeptidase fraction and one single active band (RF 0.16) in the endopeptidase fraction using polyacrylamide gel electrophoresis were found. Co-migrating proteins to all of these activities were detected. Endopeptidase activity splits 3-carboxypropionyltrialanin-4-nitroanilide (SucAla3NAp) in the position P2-P1. Liberated aminoacyl-NAP may be further split to generate chromogenic 4-nitroaniline through aminopeptidase activity. Endopeptidase of the brush border of the rat enterocytes is characterized by the following properties: 1) molecular mass 130000 +/- 15 000 dalton; 2) Km value (substrate: SucAla3NAp) 1.1 X 10(-3) M; 3) pI 5.23; 4) ph optimum 8.5; 5) 50% activity remains after 15 min of preincubation at 50 degrees C; 6) activity is strongly inhibited by EDTA, p-chloromercuribenzoate, Mn2 and Co2.

Proteins of the kidney microvillar membrane. Aspartate aminopeptidase: purification by immunoadsorbent chromatography and properties of the detergent- and proteinase-solubilized forms

Aminopeptidase A (aspartate aminopeptidase, EC 3.4.11.7) was purified 2000-fold from pig kidney cortex. The essential step in the purification was chromatography on an immunoadsorbent column prepared from a rabbit antiserum raised against pig intestinal aminopeptidase A. Glutamyl and aspartyl substrate were attacked most rapidly and their hydrolyses were stimulated by Ca2+. The 2-naphthylamide derivatives of neutral and basic amino acids were also hydrolysed by aminopeptidase A, but at rates about two orders of magnitude lower, and Ca2+ was inhibitory. The possibility that these atypical substrates were hydrolysed by traces of aminopeptidase M (EC 3.4.11.2) contaminating the preparation could be excluded on several grounds. Aminopeptidase A was sensitive to inhibition by chelating agents and the inactive enzyme could be reactivated by Ca2+ or Mn2+. Atomic absorption spectrophotometry revealed 1 g-atom of Ca/143000 g of protein. Two forms of the enzyme were purified: an amphipathic form solubilized from the membrane by Triton X-100 (detergent form) and a hydrophilic form released by incubation with trypsin (proteinase form). The detergent form exhibited charge-shift in crossed immunoelectrophoresis when anionic or cationic detergents were present. On gel filtration, mol.wts. of 350000--400000 and 270000 were calculated for the detergent and proteinase forms. Electron microscopy after negative staining of the proteinase form revealed a dimeric structure. Electrophoresis of either form in the presence of sodium dodecyl sulphate revealed four polypeptides with mobilities corresponding to apparent mol.wts. of 155000, 110000, 90000 and 45000. All four bands stained positively for carbohydrate. Pig serum possesses weak aminopeptidase A activity; immunological experiments showed it to be a similar protein.

Apical membrane aminopeptidase appears at site of cell-cell contact in cultured kidney epithelial cells

A dog kidney epithelial cell line (MDCK), grown in monolayer, displayed in vitro an asymmetric localization of surface proteins. Aminopeptidase [alpha-aminoacylpeptide hydrolase (microsomal), EC 3.4.11.2] was found only in the apical face whereas Na+, K+-ATPase (ATP phosphohydrolase, EC 3.6.1.3) was found in the basolateral faces. These two faces are delineated by the junctional complex at which close cell-cell contact occurs. alpha-Actinin, a protein associated with plasma membranes, was concentrated near the region of cell-cell contact. When membrane proteins in the apical surface were crosslinked and subsequently removed from the surface by endocytosis, crosslinked antigens reappeared in the apical face at the region of cell-cell contact. Antigens that were not crosslinked were also (re)inserted in the same region. This process was not affected by cycloheximide, presumably because a large pool of apical membrane proteins (observed in small cytoplasmic vesicles) was used to replace the endocytosed antigens. It is psoposed that the region containing the junctional complex is involved in guiding apical membrane proteins to their final location.

Localization and biosynthesis of NADH-cytochrome b5 reductase, an integral membrane protein, in rat liver cells. II. Evidence that a single enzyme accounts for the activity in its various subcellular locations

NADH-cytochrome b5 reductases of rat liver microsomes, mitochondria, and heavy and light Golgi fractions (GF3 and GF 1+2) were compared by antibody inhibition and competition experiments, by peptide mapping, and by CNBr fragment analysis. The water-soluble portion of the microsomal enzyme, released by lysosomal digestion and purified by a published procedure, was used to raise antibodies in rabbits. Contaminant antimicrosome antibodies were removed from immune sera by immunoadsorption onto the purified antigen, and the F(ab')2 fragments of the pure antireductase antibody thus obtained were found to inhibit the NADH-cytochrome c reductase activity equally well in the four membrane fractions investigated, with similar dose-response relationships. Moreover, the purified water-soluble fragment of microsomal reductase, which by itself is very inefficient in reducing cytochrome c, competed for antibody binding with the membrane-bound enzymes, and therefore prevented the inhibition of their activity not only in microsomes but also in the other fractions. The reductases isolated from detergent-solubilized microsomes, mitochondria, GF3, and GF1+2 by immunoadsorption had identical mobilities in SDS polyacrylamide gels. The corresponding bands were eluted from gels, fragmented with pepsin or CNBr treatment, and the two families of peptides thus obtained were analyzed by two-dimensional mapping and SDS polyacrylamide gel electrophoresis, respectively. Both analyses failed to reveal differences among reductases of the four fractions. These findings support the hypothesis that NADH-cytochrome b5 reductase in its various subcellular locations is molecularly identical.