Purification of a new intestinal anti-proliferative factor from normal human small intestine.

Previous studies suggest that intestinal cell proliferation may be controlled by endogenous mitosis inhibitors. We describe here the isolation of a protein named intestinal anti-proliferative factor (IAF) from human small intestine. Successive DEAE anion exchange, isoelectric focusing and gel filtration chromatographies led to a purified anti-proliferative protein fraction used to produce antibodies. Using these antibodies as affinity chromatography ligand, IAF was purified from human small intestine cytosolic fraction. IAF was a potent inhibitor of adenocarcinoma colon cells (HT-29 D4 line) DNA synthesis and proliferation with 50% inhibition observed at picomolar concentrations. Analyzed on SDS/PAGE under reducing conditions, this protein migrates with an apparent molecular mass of 120 kDa and amino acid sequence of two internal peptides displays no homology with another listed protein. Cell cycle studies showed that the growth inhibitory effect was maximal between mid G1 and early S phases. Moreover, flow cytometry studies demonstrated that IAF inhibited the progression of HT-29 D4 cells from G1 to S phase. Northern blot analysis using a dipeptidyl peptidase i.v. probe revealed that the growth arrest mediated by IAF was not linked to differentiation processes. By Western blotting with polyclonal antibodies against IAF, we found that this protein was not detected in differentiated colonic carcinoma. Our results suggest that IAF might regulate intestinal cell proliferation.

Inhibition of calcium influx during hypoxia/reoxygenation in primary cultured rat hepatocytes.

Calcium has been demonstrated to play an important role in hepatocyte damage during ischemia/reperfusion phases. Calcium influx was determined in primary cultured rat hepatocytes submitted to a succession of warm hypoxia and reoxygenation phases in the presence of diltiazem, gallopamil and a Na+/H+ antiport inhibitor, HOE-694. Only diltiazem significantly inhibited calcium influx with higher potency after reoxygenation than after hypoxia only, suggesting a complex mechanism of action of diltiazem which could act on different physiological functions involved in Ca2+ invasion of hepatocytes after hypoxic insult.

Intestinal lactase-phlorizin hydrolase (LPH): the two catalytic sites; the role of the pancreas in pro-LPH maturation.

Brush border lactase-phlorizin hydrolase carries two catalytic sites. In the human enzyme lactase comprises Glu-1749, phlorizin hydrolase Glu-1273. The proteolytic processing of pro-lactase-phlorizin hydrolase by (rat) enterocytes stops two amino acid residues short of the N-terminus of 'mature' final, brush border lactase-phlorizin hydrolase. Only these two amino acid residues are removed by luminal pancreatic protease(s), probably trypsin.

Thyroid hormone regulation of the Na+/glucose cotransporter SGLT1 in Caco-2 cells.

The expression of the Na+/glucose cotransporter (SGLT1) in response to thyroid hormone [3,5,3'-tri-iodo-l-thyronine (T3)] was investigated in the enterocytic model cell line Caco-2/TC7. In differentiated cells, T3 treatment induces an average 10-fold increase in glucose consumption as well as a T3 dose-dependent increase in SGLT1 mRNA abundance. Only cells grown on glucose-containing media, but not on the non-metabolizable glucose analogue alpha-methylglucose (AMG), could respond to T3-treatment. The Vmax parameter of AMG transport was enhanced 6-fold by T3 treatment, whereas the protein abundance of SGLT1 was unchanged. The role of Na+ recycling in the T3-related activation of SGLT1 activity was suggested by both the large increase in Na+/K+ATPase protein abundance and the inhibition, down to control levels, of AMG uptake in ouabain-treated cells. Further investigations aimed at identifying the presence of a second cotransporter that could be expressed erroneously in the colon cancer cell line were unsuccessful: T3-treatment did not modify the sugar-specificity profile of AMG transport and did not induce the expression of SGLT2 as assessed by reverse transcription-PCR. Our results show that T3 can stimulate the SGLT1 cotransport activity in Caco-2 cells. Both transcriptional and translational levels of regulation are involved. Finally, glucose metabolism is required for SGLT1 expression, a result that contrasts with the in vivo situation and may be related to the fetal phenotype of the cells.

Renal neutral alpha-D-glucosidase has no role in transport of D-glucose derived from maltose hydrolysis.

To reinvestigate the "hydrolase-related transport" concept, neutral alpha-D-glucosidase, a membrane-bound disaccharidase of renal proximal tubule, was first purified from brush-border membranes and then asymmetrically reincorporated into egg phosphatidylcholine vesicles. Proteolytic treatments and immunotitration studies demonstrated that this enzyme was integrated in native and artificial membrane vesicles with a similar topology. The uptake of free glucose and glucose produced by maltose hydrolysis was studied using 1) proteoliposomes containing integrated neutral alpha-D-glucosidase, in combination with other membrane proteins, and 2) proteoliposomes containing only the other membrane proteins but incubated in a medium containing neutral alpha-D-glucosidase in its hydrophilic form. No modification was observed in the uptake of free D-glucose or D-glucose produced by maltose hydrolysis, regardless of enzyme localization. In contrast to previous findings on the hydrolase-related transport concept, these results rule out any participation of neutral alpha-D-glucosidase in the transport of free glucose or glucose produced by maltose hydrolysis. Hydrolytic activity and transmembrane transport appear to be two independent and sequential steps.

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.

Do pancreatic proteases play a role in processing prolactase and/or in the postweaning decline of lactase?

To assess the role of pancreatic proteases in the proteolytic processing and in the postweaning decline of lactase-phlorizin hydrolase (LPH), we have determined lactase activity and the different LPH forms in postweaned rats in which a jejunal loop was excluded from contact with pancreatic secretions by a jejunal bypass procedure. As a control for the absence of pancreatic proteases, pro-sucrase-isomaltase (proSI), which is known to be split by pancreatic proteases into heterodimeric SI, was used. Nearly all proLPH was processed to mature LPH, indistinguishable from LPH isolated from control animals. SI was found only in the unsplit pro form, whereas it was normally processed to the heterodimeric SI in the control tissues. There were no significant differences in lactase and sucrase activities in operated and in sham-operated control animals. We conclude that pancreatic secretions are not essential for the processing of proLPH to LPH or in the postweaning decline of LPH.

Potassium uptake and water content in hepatocytes isolated from rat livers preserved in Euro-Collins and UW solutions and after transplantation.

Isolated hepatocytes from the rat were used to assess the maintenance of liver cell function in relation to the composition of the preservation medium. After separation by collagenase, they were incubated in Krebs-Ringer-Bicarbonate medium (KRB), Euro-Collins (EC), or University of Wisconsin (UW) solutions. Potassium influx, cell volume, and transaminase release were measured in cells freshly separated from control livers or from livers preserved in vitro up to 12 h in these media or having undergone orthotopic liver transplantation (OLT). While ion exchange levels were retained in all media, cells shrank significantly in UW but were able to restore their volume after 3 h of liver preservation. With regard to in vivo conditions, UW appears to be the best medium to prevent edema and to maintain more stable potassium exchange and enzyme production. These results are of value for liver transplantation in humans.

Short-chain phosphatidylcholines as superior detergents in solubilizing membrane proteins and preserving biological activity.

The solubilization of plasma and organelle membranes by diheptanoylphosphatidylcholine (DHPC) has been studied. This short-chain phosphatidylcholine is shown to act as a mild detergent, solubilizing effectively both kinds of membranes at DHPC concentrations of 10-20 mM (0.5-1%). The size of the resulting mixed protein-lipid-DHPC micelles ranges between 5 and 8 nm. The protein conformation and hence the enzymatic activity are well preserved over a rather large DHPC concentration range (up to 4-5 times the DHPC concentration required for solubilizing the membranes). Evidence is presented that short-chain phosphatidylcholines are superior to most detergents commonly used by biochemists. This is true not only regarding its excellent dispersing power on both phospholipid bilayers (Gabriel & Roberts, 1986) and biological membranes but also as to its capacity to preserve the native protein structure and hence enzymatic activity in the solubilized state. Due to its special properties DHPC lends itself very well not only to membrane solubilization but also to the purification of the solubilized membrane proteins and reconstitution of the proteins into simple lipid bilayers. Concerning the mechanism of membrane solubilization, evidence indicates that DHPC interacts primarily with the lipid bilayer of the membrane and not with the membrane proteins. DHPC solubilizes membranes by being distributed into the lipid bilayer and breaking it up. In the resulting small mixed micelles, the protein remains associated with its preferred intrinsic membrane lipids and is thus stabilized. The protein-intrinsic lipid complex is successfully shielded from unfavorable contacts with H2O by DHPC-intrinsic lipid interactions.

Oligomeric structure of the sodium-dependent phlorizin binding protein from kidney brush-border membranes.

Immunodetection of solubilized kidney brush-border proteins on Western blots using antibodies against the 70 kDa phlorizin binding component of sodium-glucose cotransporter allows to identify an additional protein band with apparent molecular mass of 120 kDa in the presence of reducing agent dithiothreitol. Antibodies specifically eluted from the 70 kDa protein still recognize the 120 kDa protein on Western blot. The lack of dissociation of the 120 kDa protein from native brush borders or Triton X-100 extract in the presence of dithiothreitol can be improved by an extended incubation at 25 degrees C; this protein is full dissociated when purified by electroelution from polyacrylamide gel and gives two subunits with apparent molecular masses of 70 and 60 kDa by Coomassie staining and Western blot analysis. The effect of dithiothreitol on the renal brush-border membrane phlorizin binding is studied; a decrease in the number of high-affinity phlorizin binding sites without modification of the affinity to the binding molecule is observed. These data suggest that the high-affinity phlorizin binding moiety of sodium-glucose cotransporter exists in the kidney as a dimeric structure.

Effect of human native low-density and high-density lipoproteins on prostaglandin production by mouse macrophage cell line P388D1: possible implications in pathogenesis of atherosclerosis.

Macrophages have been shown to play a key-role in the development of atherosclerotic lesions. Monocyte attraction and activation in the arterial wall lead to foam cell formation, cholesterol accumulation and secretion of inflammation mediators. Among macrophage secretions, prostacyclin and thromboxane are prostaglandins involved in the regulation of coagulation and vascular permeability. In this study, we have evaluated the effects of human native low-density and high-density lipoproteins on macrophage prostaglandin production (P388D1 mouse cell line). Lipoprotein fractions were purified from venous blood of healthy volunteers by sequential ultracentrifugation. After lipoprotein incubation with cells, supernatants were extracted and prostaglandins quantified by high-performance liquid chromatography. Our technique allows the determination of the main classes of prostaglandins. In the presence of low-density lipoproteins, time-course study showed an increase in total prostaglandin production within 10 min (50 times basal secretion level). This increase was dose-dependent. A steady-state was obtained at 20 mg protein LDL/1. Stimulation of thromboxane B2 and prostacyclin was predominant, with a main effect on the proaggregant thromboxane. Production of the proinflammatory PGF2 alpha and the immunoregulatory PGE2 was lower. In the presence of high-density lipoproteins, P388D1 cells also increased their total prostaglandin secretion at 30 min, in a dose-dependent manner. This increase was directly related to a stimulation of prostacyclin, with no significant effect on thromboxane. Our results demonstrate that normal low-density lipoproteins can stimulate macrophage prostaglandin secretions, with putative deleterious effects on the arterial wall, in particular thrombus formation. On the other hand, high-density lipoproteins, by mainly stimulating prostacyclin, could theoretically have a beneficial influence.

Immunological recognition of sodium/D-glucose cotransporter from renal brush border membranes by polyclonal antibodies.

Antisera prepared in rabbit to a D-glucose-inhibitable phlorizin binding component of the pig kidney brush border membrane precipitated more than 90 percent of the D-glucose-inhibitable phlorizin binding activity from a Triton extract. These antibodies also stimulated D-glucose uptake by native brush border membranes at low D-glucose concentrations (1 mM) and inhibited it at higher D-glucose concentrations. Immunoblotting was used to locate polypeptide subunits of the glucose transporter in polyacrylamide gels of proteins extracted from the brush border membranes. The antibodies labelled the Mr 70,000 phlorizin-binding component in both reducing and non reducing conditions. Two additional polypeptides with relative molecular mass of 120,000 and 45,000 were also recognized under the same conditions; they might correspond, respectively, to another Na+/D-glucose cotransport unit and to a post mortem degradation product.

Characterization of sodium and pyruvate interactions of the two carrier systems specific of mono- and di- or tricarboxylic acids by renal brush-border membrane vesicles.

The experiments reported in this paper aim at characterizing the carboxylic acid transport, the interactions of pyruvate and citrate with their transport sites and specificity. The study of these carriers was performed using isotopic solutes for the influx measurements in brush-border membrane vesicles under zero trans conditions where the membrane potential was abolished with KCl preloading with valinomycin or equilibrium exchange conditions and delta psi = 0. Under zero trans condition and delta psi = 0, the influence of pyruvate concentrations on its initial rates of transport revealed the existence of two families of pyruvate transport sites, one with a high affinity for pyruvate (Kt = 88 microM) and a low affinity for sodium (Kt = 57.7 mM) (site I), the second one with a low affinity for pyruvate (Kt = 6.1 mM) and a high affinity for sodium (Kt = 23.9 mM) (site II). The coupling factor [Na]/[pyruvate] stoichiometry were determined at 0.25 mM and 8 mM pyruvate and estimated at 1.8 for site I, and 3 when the first and the second sites transport simultaneously. Under chemical equilibrium (delta psi congruent to 0) single isotopic labeling, transport kinetics of pyruvate carrier systems have shown a double interaction of pyruvate with the transporter; the sodium/pyruvate stoichiometry also expressed according to a Hill plot representation was n = 1.7. The direct method of measuring Na+/pyruvate stoichiometry from double labeling kinetics and isotopic exchange, for a time course, gives a n = 1.67. Studies of transport specificity, indicate that the absence of inhibition of lactate transport by citrate and the existence of competitive inhibition of lactate and citrate transports by pyruvate leads to the conclusion that the low pyruvate affinity site can be attributed to the citrate carrier (tricarboxylate) and the high pyruvate affinity site to the lactate carrier (monocarboxylate).

Use of mild detergent gel electrophoresis for isolation and characterization of the kidney brush border D-glucose transporter.

Gradient gel electrophoresis was performed under mild detergent conditions to separate pig kidney brush border membrane proteins and to identify the smallest functional molecular protein entity of the D-glucose transporter. The various protein bands obtained from the nondenaturing gel system in a semipreparative scale were eluted by electrodialysis. These proteins were then reintegrated into proteoliposomes and tested for D-glucose-inhibitable [3H]phlorizin binding. The D-glucose transporter had a molecular mass of 70 kDa in mild detergent electrophoresis conditions and in subsequent SDS analysis.

Diethylpyrocarbonate inhibition of sodium-glucose cotransport in kidney brush-border membrane vesicles.

Exposure of kidney brush-border membrane vesicles to the acylating reagent diethylpyrocarbonate resulted in inactivation of the glucose transporter, as demonstrated by inhibition of sodium-coupled D-glucose transport and phlorizin binding. The transport site(s) was protected against inactivation by the simultaneous presence of sodium ions and D-glucose, and were partially protected by phlorizin. Transport activity was not restored by hydroxylamine; this rules out the possibility of diethylpyrocarbonate interaction with histidine, serine or tyrosine transporter residues. Dithiothreitol, a thiol protector, slightly prevented diethylpyrocarbonate inactivation. It is therefore suggested that (an) amino group(s) in the translocation complex is involved, at the level of the sugar transport site and the preferential protection of D-glucose against diethylpyrocarbonate inactivation related to a conformation change caused by the simultaneous binding of sodium and D-glucose to the cotransporter.

Separation and reconstitution of sodium-dependent glucose transport activity from renal brush-border membranes using gel-filtration chromatography.

Pig kidney brush-border membrane vesicles were solubilized using a final concentration of 1% Triton X-100, found optimal for quantitative reconstitution of D-glucose transport into liposomes. Using reconstituted proteoliposomes, selective permeability towards D-glucose compared to other sugars tested was shown as well as the main features of D-glucose transport in native membranes, namely sodium dependence and phlorizin inhibition of D-glucose accumulation. After removal of Triton X-100 from the detergent extract, some membrane proteins (about 40%), which are insoluble in the absence of detergent, were isolated. Among these proteins resolubilized by 1% Triton X-100, the component catalyzing the D-glucose transport was located by gel-filtration chromatography separation, using reconstitution of transport as the assay. The active fraction displayed a molecular size of 50 A; when analyzed on SDS polyacrylamide gel electrophoresis, it contained one major protein subunit with an apparent molecular weight close to 65,000. We conclude that this protein fraction is involved in D-glucose transport by renal brush borders.

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.

Glucose transport by horse kidney brush borders. I.--Transport properties of brush border membrane closed vesicles.

Brush border membranes isolated from horse kidney cortex as closed right-side out vesicles show selective permeability when analyzed on sucrose and dextran gradients. These vesicles can actively accumulate D-glucose. The preservation of the glucose transport system is demonstrated by the following features: (a) the uptake and release rates of D-glucose are higher in the presence of a sodium gradient, showing that D-glucose transport is a sodium-dependent process; (b) this transport, specific for the D-isomer, is inhibited by phlorizin; (c) the D-glucose transport system is saturable; (d) no inhibition of D-glucose transport is found with C-mannose; (e) the D-glucose uptake is sensitive to osmotic variations.