Isolation of brush border membranes in vesicular form from the intestinal spiral valve of the small dogfish (Scyliorhinus canicula).

A simple, rapid method for the preparation of purified brush border membranes in vesicular form from rabbit kidney proximal tubules has been applied with closely similar results to the intestinal spiral valve of the small dogfish (Scyliorhinus conicula). Since the dogfish belongs to one of the most ancient species of fish, it may be suggested that the method is generally applicable to all species later evolved which possess a brush border membrane at the mucosal surface of the cells of the intestine or kidney.     

A rapid method for the isolation of kidney brush border membranes

A simple rapid method for the preparation of purified brush border membranes from rabbit kidney proximal tubules is described. The method is based on hypotonic lysis, Ca²⁺ aggregation of contaminants and differential centrifugation. In contrast to most other published methods, the brush border membranes are free of contamination by basolateral membranes.     

A rapid method for the isolation of kidney brush border membranes.

A simple rapid method for the preparation of purified brush border membranes from rabbit kidney proximal tubules is described. The method is based on hypotonic lysis, Ca2+ aggregation of contaminants and differential centrifugation. In contrast to most other published methods, the brush border membranes are free of contamination by basolateral membranes.     

Subcellular localization of rat kidney phosphate independent glutaminase

The phosphate independent glutaminase is contained in the brush border membrane of the rat kidney proximal tubule cells. This glutaminase activity cofractionates with the brush border membrane marker activities, alkaline phosphatase and γ-glutamyltranspeptidase, during differential centrifugation. About 30% of these activities are recovered with the mitochondrial fraction, the remainder is pelleted in the heavy microsomal fraction. The phosphate independent glutaminase in both fractions bands, during isopycnic centrifugation, with a mean density of 1.16–1.17 and is coincident with both brush border membrane marker activities. The isolation of intact, individual kidney cells was accomplished by initial perfusion of the kidneys in situ with a collagenase-papain solution followed by a brief incubation in the same enzyme solution. Incubation of isolated cells with a higher concentration of papain results in selective release of the phosphate independent glutaminase. The fact that this occurs without appreciable release of a cytoplasmic marker activity, lactate dehydrogenase, suggests that the phosphate independent glutaminase may be localized on the external surface of the kidney cells.     

Studies of vertebrate kidney. VI. Histochemical localization of phospholipids in kidneys of fishes from different habitats.

Six fish species living in different habitats such as fresh water, estuarine, and marine were studied for the distribution of phospholipids in various regions of the kidney. Well known histochemical methods, including those for choline-containing phospholipids were employed. The distribution pattern of phospholipids in different parts of the kidney such as the brush border, basal border and cytoplasmic granules of the proximal tubule cells, the cytoplasmic granules of the distal tubule cells, glomeruli and interstitial cells is given. Choline-containing phospholipids are present in the brush border of the proximal tubules of all the species studied and in the basal border of some. In the discussion an attempt at correlation of this histochemical pattern with the excretory functions and osmoregulation in these fishes is given.     

Cytoskeletal proteins of the rat kidney proximal tubule brush border

Cytoskeletal components backing the brush border of the rat kidney proximal tubule cell were identified and compared with those of the well characterized intestinal brush border by immuneoverlay and immunocytochemistry. Antibodies reactive against the intestinal microvillus core components, villin and fimbrin, as well as against the terminal web components, spectrin (fodrin) and myosin, were used. Proteins of similar molecular weight to these intestinal brush border cytoskeletal components were identified in isolated kidney brush borders by immuneoverlay. Spectrin, a major component of the terminal web region of both cell types, was more concentrated in the kidney brush border relative to both actin and myosin. By immunofluorescence, villin and fimbrin were localized in the microvilli, and spectrin and myosin were localized to the terminal web region of the brush border. In addition, spectrin was found along the basolateral membranes of the proximal tubule cell, and myosin was detected in a punctate staining pattern throughout its cytoplasm. By immunoelectron microscopy using immunogold labeling procedures, fimbrin and villin were localized in the terminal web as well as in microvilli, and spectrin and myosin were localized to fibrils in the terminal web. A key difference between the epithelia of the two organs is the extensive network of clathrin coated pits found in the terminal web region of the kidney but not the intestinal brush border. The clathrin-rich terminal web region of the kidney, like the intestinal brush border, proved to be quite stable and resistant to disruption by non-ionic detergents and harsh mechanical treatment.     

The conversion of the precursor form of γ-glutamyltranspeptidase to its subunit form takes place in brush border membranes

The subcellular distributions of the precursor form and mature form of γ-glutamyltranspeptidase of rat kidney were studied by labeling the enzyme with [³H] fucose in vivo. In trans Golgi elements and basolateral membranes, γ-glutamyltranspeptidase was present as a precursor form with a single polypeptide chain. However, the brush border membranes contained the heavy and light subunits as well as precursor. These results suggest that the precursor is converted to the mature form after its transport to the brush border membranes.     

Body fluid osmolytes and urea and ammonia flux in the colon of two chondrichthyan fishes, the ratfish, Hydrolagus colliei, and spiny dogfish, Squalus acanthias

The present study has examined the role of the colon in regulating ammonia and urea nitrogen balance in two species of chondrichthyans, the ratfish, Hydrolagus colliei (a holocephalan) and the spiny dogfish, Squalus acanthias (an elasmobranch). Stripped colonic tissue from both the dogfish and ratfish was mounted in an Ussing chamber and in both species bi-directional urea flux was found to be negligible. Urea uptake by the mucosa and serosa of the isolated colonic epithelium through accumulation of ¹⁴C-urea was determined to be 2.8 and 6.2 fold greater in the mucosa of the dogfish compared to the serosa of the dogfish and the mucosa of the ratfish respectively. Furthermore, there was no difference between serosal and mucosal accumulation of ¹⁴C-urea in the ratfish. Through the addition of 2 mM NH₄Cl to the mucosal side of each preparation the potential for ammonia flux was also examined. This was again found to be negligible in both species suggesting that the colon is an extremely tight epithelium to the movement of both urea and ammonia. Plasma, chyme and bile fluid samples were also taken from the agastric ratfish and were compared with solute concentrations of equivalent body fluids in the dogfish. Finally molecular analysis revealed expression of 3 isoforms of the urea transport protein (UT) and an ammonia transport protein (Rhbg) in the gill, intestine, kidney and colon of the ratfish. Partial nucleotide sequences of the UT-1, 2 and 3 isoforms in the ratfish had 95, 95 and 92% identity to the equivalent UT isoforms recently identified in another holocephalan, the elephantfish, Callorhinchus milii. Finally, the nucleotide sequence of the Rhbg identified in the ratfish had 73% identity to the Rhbg protein recently identified in the little skate, Leucoraja erinacea.     

Evidence of digoxin metabolism by the kidney

By performing single pass experiments in the dog, we could identify by thin layer chromatography a digoxin metabolite produced by the kidney. In vitro studies verify that this new species is produced by the brush border membrane of the renal tubular cell.     

Studies on vertebrate kidney. V. PAS-positive lipids in kidneys of fishes from different habitats.

Five fish species living in different habitats, i.e. fresh water, estuarine and marine, were studied for the distribution of PAS-positive materia in various regions of the kidney, 10 minutes' oxidation with 0-5 per cent. HIO4 being employed prior to treatment with Schiff's reagent. PAS-positive material was detected in different sites of the kidney, i.e. brush border of proximal tubules, proximal tubule cells' cytoplasm, distal tubule cells' cytoplasm, glomerulus, basal cell border of proximal tubules and the interstitial cells. Of these sites, the brush border of the proximal tubule of Scoliodon sorrakowah showed the presence of PAS-positive lipids. Elsewhere the PAS-positive reaction was due to carbohydrates. Free aldehyde groups were absent. In Tilapia mossambica and Labeo rohita, PAS staining was enhanced after chloroform-methanol extraction, particularly in the brush border of the proximal tubule. The significance of these findings is discussed.     

The histochemical demonstration of brush border endopeptidase.

A histochemical method for the demonstration of a brush border endopeptidase is described based on results of biochemical and histochemical experiments. The substrate of choice is Glut-Ala-Ala-Ala-MNA which displays a very good localization ability and suitable kinetic properties. Km estimated in rat kidney homogenate amounts to 2.35 X 10(-4) M. pH optimum of this endopeptidase associated with the brush border membrane is in the alkaline range. The activity is dependent on the buffer used. In phosphate and cacodylate buffers of pH 7.2 about 30% lower activity in rat kidney and about 25% lower activity in rat small intestine than in Tris-HCl buffer of the same pH was found. The most suitable diazonium salt for the detection "in situ" is Fast Blue B. It inhibits the endopeptidase activity of rat kidney by about 85% at pH 7.2 AND BY ABOUT 55% AT PH 6.0. The best results are obtained in cryostat sections adherent to semipermeable membranes treated with chloroform-acetone before the incubation. A microdensitometric evaluation of the reaction product is possible and results are in good agreement with those of the biochemical determination. When Suc-Ala-Ala-Ala-INA is used as substrate hexazonium-p-rosaniline is the most suitable coupling agent although it inhibits more than Fast Blue B. The reaction using acylated trialanyl naphthylamides as substrates runs in two steps. Endopeptidase sets free Ala-NA which is attacked by aminopeptidase M. Aminopeptidase M is not reaction rate or localization limiting factor because its activity in the brush border is very high and the enzyme is anchored to the cell membrane very closely to endopeptidase. In homogenates of rat kidney and jejunal mucosa the endopeptidase activity was inhibted by EDTA (2X10(-3) M) by 75% in the kidney and by 68% in the jejunum, by DFP (10(-3) M) by 41% in the kidney and by 35% in the intestine, by Mn2+ (5X10(-3) M) by 25% in the kidney and by 30% in the intestine. No inhibition was exerted by E 600. In sections the results were similar. 1,10-phenanthroline (10(-2) M) caused a substantial inhibition. Endopeptidase activity was detected in the brush border of cells of proximal convuluted tubules of the kidney and in the brush border of differentiated enterocytes of the small intestine. In the same species enterocytes display a lower activity than kidney tubular cells. There are species differences in the distribution pattern of endopeptidase in the kidney. In the rabbit and man the positive reaction occurs in the whole cortex. It is distributed unevenly, however. In the rat the tubules of the inner cortex display a very high activity. In the outer cortex straight portions react strongly. In the rabbit kidney cells of the parietal layer of Bowman's capsule display a weak reaction as well. No sex differences were found in the distribution pattern of endopeptidase in the rat kidney. In the intestine of all species examined a proximo-distal gradient was found...     

Characterization of antigenic sialoglycoprotein subunits of the placental brush border membranes: Comparison with liver and kidney membrane subunits by two-dimensional electrophoresis

The sialoglycoprotein subunits of human placental brush border membranes were labeled by sequential treatment with periodate and (³H)-sodium borohydride, which trititates sialic acid, and by lactoperoxidase-catalyzed (¹²⁵I) iodination of tyrosine residues. The labeled subunits were characterized with respect to their affinity for antisera raised against Triton X-100 extracts of placental brush border membranes. The immunochemically reactive components were analyzed by two-dimensional electrophoresis according to a modification of the O'Farrell technique [20] enabling the assignment of estimated M_r? and pI. Of the 33 ³H-labeled brush border subunits present in Triton X-100-solubilized membrane preparations, 18 subunits reacted with antiplacental brush border antisera insolubilized on CNBr-activated Sepharose or in immunoprecipitates. Fourteen of these tritiated subunits were also labeled with ¹²⁵I, confirming that these are glycoproteins. The plasma membranes of normal human liver and microsomes from kidney were examined for the placental brush border glycoprotein subunits by reaction with insolubilized antiplacental brush border antisera and two-dimensional electrophoresis of the reacting tritium-labeled subunits. Comparison of the two-dimensional electrophoretic maps of the immunochemically reacting glycoproteins from liver, kidney, and placenta resulted in the identification of seven placental subunits in common with liver and kidney on the basis of antigenic cross-reactivity, M_r?, and pI. Four placental glycoproteins were not found in the other tissues and are potentially specific to the placenta. Three of the placental subunits were only seen in placenta and kidney. Three of the subunits ran at the dye front and could not be assigned molecular weights. One of the subunits was poorly labeled by tritiation of sialic acid and was not considered.     

Variations in the distribution pattern of acid and alkaline phosphatase activity in the kidney of some Selachians

Summary Notable species differences in the distribution pattern of acid phosphatase activity are described in the brush border cells in the convoluted tubules (Hauptstück) of Selachian kidney. In representatives of Ord. Rajiformes (Myliobatis aquila L., Raja clavata L., and Torpedo marmorata Risso) a typical droplet staining of acid phosphatase occured throughout the cells. The staining pattern highly resembles the lysosomal activity of the enzyme in the proximal convoluted tubules of the rat kidney. In kidneys of Mustelus laevis Risso and Scyllium stellare Risso, which both belong to the order Squaliformes, however, a dense uniform and rather finely granulated staining occured in the apical zone of the cells. All acid phosphatase positive structures are believed to be lysosomes and their derivates. Topographical coincidence between material stained for acid phosphatase and PAS positive structures is also described.Marked species differences in the brush border alkaline phosphatase activity also described here, correspond to the development of the brush border as revealed by the PAS staining method.Supported by Yugoslav Academy of Sciences and Arts and by grant from the Institute of Biology, University of Zagreb.     

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.     

Isolation ofn-ethylmaleimide-labelled phlorizin-sensitived-glucose binding protein of brush border membrane from rat kidney cortex

A glucose receptor with high affinity for phlorizin from isolated brush border of rat kidney was labelled specifically withN-[¹⁴C]ethylmaleimide and then extracted from the membranes.After the solubilization of the brush borders with sodium dodecyl sulphate theN-[¹⁴C]ethylmaleimide-labelled receptor protein was isolated and was found to have a molecular weight of approximately 30 000 as determined by sodium dodecyl sulphate-polyacrylamide gel disc electrophoresis. The receptor protein eluted from the sodium dodecyl sulphate-containing gels migrates as a single band on sodium dodecyl sulphate-free polyacrylamide gels.The receptor protein can also be released from the brush borders with low concentrations of sodium deoxycholate. Under these conditions the molecular weight of theN-[¹⁴C]ethylmaleimide-labelled receptor protein is approximately 60 000 in contrast to the protein component solubilized with sodium dodecyl sulphate. Since this detergent is known to dissociate the brush border membrane into its protein components, our results suggest that the phlorizin- sensitive glucose receptor protein has a molecular weight of about 30 000.     

Characterization of an insoluble adenosine deaminase complexing protein from human kidney

Evidence for the presence of an insoluble form of adenosine deaminase complexing protein in human kidney has been obtained. An initial study demonstrated that binding of monomeric adenosine deaminase to particulate material from kidney was saturable and could be blocked by preincubating the enzyme with soluble complexing protein. Treatment of particulate material with deoxycholate, followed by immunoassay of the detergent extract, confirmed the presence of an insoluble form of complexing protein in the kidney. Several other human organs examined by this technique contained smaller amounts of insoluble complexing protein. Complexing protein isolated from the soluble and particulate fractions of kidney homogenates were found to be structurally similar. The proteins had the same subunit M_r and showed complete crossreactivity with antiserum to soluble complexing protein. Indirect immunoperoxidase staining of renal cortical tissue revealed that complexing protein was concentrated in the brush border of the proximal tubules. These results indicate that (a) the soluble and insoluble forms of complexing protein from human kidney may be products of the same gene(s) and (b) a portion of the complexing protein in human kidney is bound to the brush border membranes of cells lining the proximal tubules.     

Analysis of the pH dependence of folate binding and transport by rat kidney brush border membrane vesicles

Folate reabsorption by the mammalian kidney occurs following a tight binding reaction with the renal brush border membrane. Previous studies have shown that transport of folic acid (PteGlu) by rat kidney brush border membrane vesicles occurs maximally at pH 5.6 via a saturable system that is associated with a binding component. The present studies have shown that the pH dependency of transport was due to the development of the transmembrane pH gradient (7.3 in/5.6 out), not to the acidic pH per se. The pH gradient-mediated transport was stimulated by an inwardly directed ionic gradient, either of NaCl or choline chloride. These gradients also stimulated the membrane binding of PteGlu suggesting that NaCl and choline chloride may have increased PteGlu transport by altering binding to the brush border membrane. Renal brush border membrane vesicular transport of PteGlu was not affected by induction of a relatively positive intravesicular space. Transport was inhibited by 4,4'-diisothiocyano-2,2'-disulfonic acid stilbene, an anion exchange inhibitor. The results suggest that rat kidney brush border membrane transport of PteGlu is initiated by association with a specific membrane protein, followed by transfer of folate across the membrane. The overall activity is influenced by a transmembrane pH gradient.     

Localization of dehydropeptidase-I, an enzyme processing glutathione, in the rat kidney

An antibody prepared against dehydropeptidase-I, one of the glutathione processing enzymes, from the renal membrane fraction of rats was employed to localize at the light microscopic level the enzyme in the kidney using the avidin/biotin-peroxidase complex method. Dehydropeptidase-I was found to be present on both the brush border and the basolateral membranes of proximal tubular cells. Furthermore, the enzyme activity in the isolated brush border and basolateral membrane fractions was also determined. Distribution profiles of the enzyme activity showed good agreement with the results of the immunohistochemical observations.     

Ubiquinone,nonheme iron,and flavins in the renal brush border plasma membranes

The specific levels of ubiquinone, nonheme iron, and flavins have been estimated in renal brush border membrane preparations. In all cases, the levels were clearly lower than those of kidney mitochondria, on the basis of both protein and cytochrome content. These results suggest that kidney mitochondria and brush border membranes differ in the composition of their electron transfer systems.     

Luxol Fast Blue Combined With the Periodic Acid-Schiff Procedure for Cytological Staining of Kidney

Rat kidneys fixed in Regaud's fluid were stained by luxol fast blue (LFB), by the periodic acid-Schiff (PAS) method, and by LFB combined with PAS. When used separately the PAS stains the brush border, hyaline droplets and basement membranes reddish, the LFB stains the mitochondria, hyaline bodies and basement membranes greenish-blue. The combined LFB-PAS method stains the brush border reddish and the mitochondria dark blue, while the hyaline bodies and basement membranes are purplish colored. The LFB-PAS method provides color contrasts which show cytological features that are particularly significant in the kidney.