Na+-sugar cotransport system as a polarization marker during organization of epithelial membrane

The plasma membrane-associated protein RS1 decreases transcription of the transporter SGLT1 in confluent LLC-PK1 cells

Previously we cloned RS1, a 67-kDa polypeptide that is associated with the intracellular side of the plasma membrane. Upon co-expression in Xenopus laevis oocytes, human RS1 decreased the concentration of the Na(+)-D-glucose co-transporter hSGLT1 in the plasma membrane (Valentin, M., Kühlkamp, T., Wagner, K., Krohne, G., Arndt, P., Baumgarten, K., Weber, W.-M., Segal, A., Veyhl, M., and Koepsell, H. (2000) Biochim. Biophys. Acta 1468, 367-380). Here, the porcine renal epithelial cell line LLC-PK1 was used to investigate whether porcine RS1 (pRS1) plays a role in transcriptional up-regulation of SGLT1 after confluence and in down-regulation of SGLT1 by high extracellular D-glucose concentrations. Western blots indicated a dramatic decrease of endogenous pRS1 protein at the plasma membrane after confluence but no significant effect of D-glucose. In confluent LLC-PK1 cells overexpressing pRS1, SGLT1 mRNA, protein, and methyl-alpha-D-glucopyranoside uptakes were drastically decreased; however, the reduction of methyl-alpha-D-glucopyranoside uptake after cultivation with 25 mm D-glucose remained. In confluent pRS1 antisense cells, the expression of SGLT1 mRNA and protein was strongly increased, whereas the reduction of SGLT1 expression during cultivation with high D-glucose was not influenced. Nuclear run-on assays showed that the transcription of SGLT1 was 10-fold increased in the pRS1 antisense cells. The data suggest that RS1 participates in transcriptional up-regulation of SGLT1 after confluence but not in down-regulation by D-glucose.

Inhibition of cell differentiation by G alpha q in the renal epithelial cell line LLC-PK1

LLC-PK1, an epithelial cell line derived from the kidney proximal tubule, was used to study the ability of the G protein alpha-subunit, G alpha q, to regulate cell differentiation. A constitutively active mutant protein, alpha qQ209L, was expressed using the LacSwitch-inducible mammalian expression system. Induction of alpha qQ209L expression with isopropyl-beta-D-thiogalactopyranoside (IPTG) enhanced phospholipase C activity maximally by 6- to 7.5-fold. Increasing concentrations of IPTG progressively inhibited the activity of two differentiation markers, Na(+)-dependent hexose transport and alkaline phosphatase activity. Induction of alpha qQ209L expression also caused a change from an epithelial to a spindle-shaped morphology. The effects of alpha qQ209L expression on cell differentiation were similar to those observed with 12-O-tetradecanoylphorbol 13-acetate (TPA) treatment. However, protein kinase C (PKC) levels were downregulated in TPA-treated cells but not in alpha qQ209L-expressing cells, suggesting that the regulation of PKC by G alpha q may be different from regulation by TPA. Interestingly, the PKC inhibitor GF-109203X did not inhibit the effect of IPTG on the development of Na(+)-dependent hexose transport in alpha qQ209L-expressing cells. These data implicate PKC delta and PKC epsilon in the pathway used by G alpha q to block the development of Na(+)-dependent hexose transport in IPTG-treated cells.

Cholesterol synthesis inhibitors in cholesterol gallstone disease

Cholesterol synthesis inhibitors (HMG-CoA Reductase Inhibitors) are reported to decrease cholesterol saturation index of duodenal bile in hypercholesterolaemic subjects. The dissolution of gallstones in animals on treatment with these drugs created expectations of a therapeutical role for these drugs in cholesterol gallstone disease. However, in prospective studies with these drugs in humans, no effect on number and size of cholesterol gallstones was observed. This is likely the result of the fact that not just biliary secretion of cholesterol is decreased during treatment with these drugs in cholesterol gallstone disease, but phospholipids and bile salts as well. As a consequence, nucleation time of cholesterol crystals in gallbladder bile is not influenced by these drugs. Another important determinant in cholesterol gallstone disease, e.g. gallbladder motility, is not influenced by HMG-CoA reductase inhibitors. Although these drugs and their metabolites are secreted into the bile, they do not influence biliary lithogenicity. In conclusion, there seems to be no therapeutic role for HMG-CoA reductase inhibitors in the treatment of cholesterol gallstone disease, although no negative effects on determinants of cholesterol gallstone formation during treatment with these drugs are observed either.

Differentiation-dependent expression of the Na+/glucose cotransporter (SGLT1) in LLC-PK1 cells: role of protein kinase C activation and ongoing transcription

We examined changes in the mRNA level of SGLT1, a Na+/glucose cotransporter, by the differentiation status of LLC-PK1 renal epithelial cells. Proliferating (undifferentiated) cells revealed no detectable SGLT1 mRNA by Northern blot analysis. However, when cells became confluent and differentiated into polarized monolayers, there was an abrupt appearance of the SGLT1 mRNA. When confluent (differentiated) cells were dedifferentiated by reseeding at a subconfluent density, SGLT1 mRNA levels decreased quickly to nondetectable levels (t1/2 = 1.5 h), while the mRNA levels of gamma-glutamyltranspeptidase, another differentiation marker, decreased only slowly (t1/2 > 40 h). This decrease in SGLT1 mRNA was completely blocked by H-7, a protein kinase inhibitor. Since protein kinase C was highly activated in the undifferentiated cells and treatment of differentiated cells with a phorbol ester also induced quick and complete loss of SGLT1 mRNA (t1/2 = 1.5 h) but not of gamma-glutamyltranspeptidase mRNA, protein kinase C activation appears to be involved in the dedifferentiation-induced decrease in SGLT1 mRNA. Although the phorbol ester-induced decrease in the SGLT1 mRNA level was blocked completely by inhibition of transcription, inhibitors of translation blocked the decrease in mRNA levels only partially.

Role of cell density/cell-cell contact, and growth state in expression of differentiated properties by the LLC-PK1 cell

Populations of the renal epithelial cell line, LLC-PK1, acquire many properties characteristic of the proximal tubular cell at confluence. At confluence cells both enter a nonproliferative state and develop extensive cell-cell contacts. To determine if one or both factors is responsible for acquisition of the differentiated phenotype, growth arrest was initiated in populations of varying densities by two procedures (serum deprivation and thymidine block) and expression of several differentiated properties (Na-hexose symport activity, gamma-glutamyl transpeptidase activity, alkaline phosphatase activity, and villin protein) was examined. Induction of growth arrest resulted in expression of all differentiated properties even in subconfluent populations. The level of expression in a population was proportional to cell density at the initiation of growth arrest; higher density was associated with increased expression. Evidence indicated the existence of some minimal density below which cells could not express detectable levels of differentiated properties in response to induction of growth arrest. The procedure used to initiate growth arrest did not affect this behavior, indicating that initiation of cell growth arrest rather than hormone deprivation was the inducing factor. These results indicate that both cell growth state and cell density independently modulate expression of differentiated properties by the LLC-PK1 cell. These results are incorporated into a model in which cells in the absence of "appropriate" cell-cell contact arrest at a differentiation-incompetent cell cycle point. In the presence of appropriate cell-cell contact (as yet undefined) cells arrest at a distinct differentiation-competent cell cycle point and initiate expression of the differentiated phenotype.

Reversibility of organic anion-induced cholestasis: association with compensatory hypersecretion of biliary phospholipid and protein in the dog

The effect of a concomitant infusion of organic anions, structurally related phthaleins, on bile flow was studied in anaesthetized dogs. A combination of rose bengal and sulfobromophthalein was found to uniquely and synergistically produce an acute, reversible form of intrahepatic cholestasis (< 10% of control level). This phenomenon was not observed with the administration of those individual organic anions at concentrations previously associated with the induction of intrahepatic cholestasis. The infusion of either a micelle forming bile salt, sodium taurocholate, or a non-micelle forming bile salt, sodium dehydrocholate, rapidly reversed the intrahepatic cholestasis (within 20 min after bile salt infusion). During the choleretic phase immediately following the bile salt infusion, a transient but marked hypersecretion, a disproportionately increased output in relation to that of bile acids, of biliary phospholipid (176% of control level by taurocholate and 138% of control level by dehydrocholate), and an even more striking amount of biliary protein hypersecretion were observed (392% of control level by taurocholate and 357% of control level by dehydrocholate). Although the significance of these new post-cholestatic observations requires clarification, it is suggested that the intrahepatic cholestasis induced by organic anions reflects a reversible defect in the mechanism(s) involved in transcellular transport.

Surface binding and uptake of cadmium (Cd2+) by LLC-PK1 cells on permeable membrane supports

Recent studies have shown that Cd2+ has relatively specific damaging effects on cell-cell junctions in the renal epithelial cell line, LLC-PK1. The objective of the present studies was to examine the surface binding and uptake of Cd2+ by LLC-PK1 cells in relation to the disruption of cell-cell junctions. LLC-PK1 cells on Falcon Cell Culture Inserts were exposed to CdCl2 containing trace amounts of 109Cd2+ from either the apical or the basolateral compartments, and the accumulation of 109Cd2+ was monitored for up to 8 h. The integrity of cell-cell junctions was assessed by monitoring the transepithelial electrical resistance. The results showed that the cells accumulated 3-4 times more Cd2+ from the basolateral compartment than from the apical compartment. The accumulation of Cd2+ from the basolateral compartment occurred in two phases: a rapid, exponential phase that occurred in 1-2 h and coincided with a decrease in transepithelial resistance, and a slower, linear phase that continued for 6-8 h. The Cd2+ that accumulated during the rapid phase was easily removed by washing the cells in EGTA, indicating that most of it was bound to sites on the cell surface. By contrast, most of the Cd2+ that accumulated during the slower phase could not be removed by EGTA, indicating that it had been taken up by the cells. Additional studies showed that the rapid phase of Cd2+ accumulation was enhanced when Ca2+ was present at low concentrations (0.1 mM), and was greatly reduced when Ca2+ was present at high concentrations (10 mM).(ABSTRACT TRUNCATED AT 250 WORDS)

Heterogeneity of the Na(+)-H+ antiport systems in renal cells

This study analyzes the differential characteristics of the Na(+)-H+ antiport systems observed in several epithelial and non-epithelial renal cell lines. Confluent monolayers of LLC-PK1A cells have a Na(+)-H+ antiport system located in the apical membrane of the cell. This system, however, is not expressed during cell proliferation or after incubation in the presence of different mitogenic agents. In contrast, confluent monolayers of MDCK4 express minimal Na(+)-H+ antiport activity in the confluent monolayer state but reach maximal antiport activity during cell proliferation or after activation of the cells by different mitogenic agents. Similar results were obtained with the renal fibroblastic cell line BHK. The system present in MDCK4 cells is localized in the basolateral membrane of the epithelial cell. In LLC-PK1A cells, an increase in the extracellular Na+ concentration produces a hyperbolic increase in the activity of the Na(+)-H+ antiporter. In MDCK4 and BHK cells, however, an increase in external Na+ produces a sigmoid activation of the system. Maximal activation of the system occur at a pHo 7.5 in LLC-PK1A cells and pHo 7.0 in MDCK4 cells. The Na(+)-H+ antiporter of LLC-PK1A cells is more sensitive to the inhibitory effect of amiloride (Ki 1.8 x 10(-7) M) than is the antiporter of MDCK4 cells (Ki 7.0 x 10(-6) M). Moreover, 5-(N-methyl-N-isobutyl)amiloride is the most effective inhibitor of Na(+)-H+ exchange in LLC-PK1A cells, but the least effective inhibitor in MDCK4 cells. Conversely, the analog, 5-(N,N-dimethyl)amiloride, is the most effective inhibitor of Na(+)-H+ exchange in MDCK4 cells, but is the least effective inhibitor in LLC-PK1A cells. These results support the hypothesis that Na(+)-H+ exchange observed in LLC-PK1A and other cell lines may represent the activity of different Na(+)-H+ antiporters.

Subcellular and molecular mechanisms of bile secretion

One of the liver's principal functions is the formation of bile, which is requisite for digestion of fat and elimination of detoxified drugs and metabolites. Bile is a complex fluid made up of water, electrolytes, bile acids, pigments, proteins, lipids, and a multitude of chemical breakdown products. In this review, we have summarized the source of various biliary components, the route by which they end up in bile, including the underlying subcellular and molecular mechanisms, and their contribution to bile formation. One of the reasons why bile formation is so complex is that there are many mechanisms with overlapping substrate specificities, i.e., many biochemically unrelated biliary constituents share common transport mechanisms. Additionally, biliary constituents may reach bile by more than one pathway. Some biliary components are critical for bile formation; others are of minor significance for bile formation but play a major physiological role. The major driving force for bile formation is the uptake and transcellular transport of bile salts by hepatocytes. The energy for bile formation comes from the sodium gradient created by the basolateral Na+/K(+)-ATPase, to which bile salt transport is coupled. The secretory pathway for bile salts involves uptake at the basolateral surface of the hepatocyte, vectorial transcellular movement, and transport across the canalicular membrane into the canalicular lumen. Hydrophilic bile salts are taken up via a sodium-dependent, saturable, carrier-mediated process coupled to the Na+/K(+)-ATPase. This uptake mechanism is also shared by other substrates, such as electroneutral lipids, cyclic oligopeptides, and a wide variety of drugs. Hydrophobic bile acids are taken up by a sodium-independent facilitated carrier-mediated mechanism in common with other organic ions, including sulfated bile acids, sulfobromophthalein, bilirubin, glutathione, and glucuronides, or by nonsaturable passive diffusion. Two major carrier proteins have been identified on the hepatocyte basolateral membrane: a 48-kDa protein that appears to be involved with Na(+)-dependent bile salt uptake, and a 54-kDa protein, thought to be associated with Na(+)-independent bile salt uptake. The intracellular transport of bile salts may involve cytosolic carrier proteins, of which several have been identified. Some evidence suggests a vesicular transport mechanism for bile salts. Since bile acids clearly do not enter the cell by endocytosis, formation of transport vesicles must be a more distal event in the transcellular translocation process. Some bile salts appear to be transported within the same unilamellar vesicles that are involved in the secretion of cholesterol and phospholipid.(ABSTRACT TRUNCATED AT 400 WORDS)

Influence of PMA and a low extracellular Ca2+ concentration on the development of the Na(+)-dependent hexose carrier in LLC-PK1 cells

We have analyzed the development of Na(+)-dependent hexose transport during differentiation and during polarization of LLC-PK1, an established cell line with characteristics of the proximal tubule. When cell-cell contact was disturbed by a low extracellular Ca2+ concentration or by a phorbol myristate acetate (PMA) treatment, the development of Na(+)-dependent hexose transport was completely inhibited. The effect of PMA on the development of hexose transport could be uncoupled from its effect on the tight junctions. The PMA concentration needed for the latter effect was approx. 10-fold higher than for the former. As the primary cause of the PMA effect, an influence on the cytoskeleton is suggested. In contrast to PMA, the concentration dependence of both phenomena on the extracellular Ca2+ concentration was almost the same. Moreover, the incorporation of hexose carriers in the plasma membrane could be induced by changing the extracellular CA2+ concentration from low to normal. We conclude that there is a relation between the formation of tight junctions and the development of the Na(+)-dependent hexose carrier, possibly because Ca(2+)-dependent cell adhesion molecules play a role in both phenomena. However, a direct relation between Ca(2+)-dependent elements of the tight junctions and the insertion of the hexose carrier can not be excluded. The Ca(2+)-dependent development seems to be a common characteristic of apical membrane proteins in contrast to the development of the basolateral membrane protein, (Na(+)+K+)-ATPase.

Antibodies to a renal Na+/glucose cotransport system localize to the apical plasma membrane domain of polar mouse embryo blastomeres

Mouse preimplantation embryos were examined for the cell surface expression of epitopes that cross-react with antibodies to a 75-kDa subunit of a purified porcine renal brush border Na+/glucose cotransport system. A Na+ cotransport system is hypothesized to reside in the apical plasma membrane domain of mouse polar blastomeres and to be associated with the induction of their apical-basal polarity. Western blot analysis showed that unfertilized oocytes as well as preimplantation embryos contain a cross-reacting antigen with an apparent molecular weight of about 75,000. Embryos and their isolated blastomeres were double-labeled and assayed by indirect immunofluorescence (IIF) for the expression of epitopes (visualized by labeling with rabbit antiserum or mouse monoclonal IgG to cotransporter followed by the appropriate rhodamine-conjugated second antibodies) and for the development of cell surface polarity (visualized by the apical restriction of fluoresceinated succinylated concanavalin A binding; FS Con A). IIF did not detect these epitopes until after the second cleavage when 4-cell embryos expressed low-to-moderate levels. Although epitopes were expressed on all surfaces of 4-cell blastomeres, some blastomeres expressed more epitopes on their apical surfaces than on their basolateral ones. All precompaction 8-cell embryos expressed epitopes, with expression being greater apically on some blastomeres. The level of expression appeared to reach a maximum on morulae and to decline on cavitating embryos. Assays performed on isolated blastomeres from postcompaction embryos showed that by the 16-cell stage epitope expression appeared to become restricted to FS Con A-labeled apical plasma membrane domains and was no longer evident on basolateral domains. This apparent apical restriction of epitope expression was confirmed by electron microscopic examination of immunogold-labeled isolated polar 16-cell blastomeres. These results demonstrate that preimplantation mouse embryos contain an antigen(s) that is immunologically and structurally similar to a 75-kDa renal Na+/glucose cotransporter. The onset of cell surface expression of this antigen precedes development of the stable polar phenotype.

Development of the Na(+)-dependent hexose carrier in LLC-PK1 cells is dependent on microtubules

The Na(+)-dependent hexose carrier, an endogenous apical marker, develops during differentiation of LLC-PK1, an established cell line with characteristics of the proximal tubule. This development was inhibited by the microtubule-disrupting drugs, colchicine and nocodazole, while it was insensitive to lumicolchicine. This strongly suggests that microtubules are involved in the plasma membrane expression of the Na(+)-dependent hexose carrier. We also analyzed the increase in activity of endogenous apical and basolateral membrane proteins during the polarization process. The development of three apical (Na(+)-dependent hexose carrier, gamma-glutamyltransferase and alkaline phosphatase) and one basolateral membrane protein (Na+/K(+)-ATPase) was studied during the reorganization of LLC-PK1 cells into a polarized epithelium. Colchicine inhibited the rapid, transient increase in the expression of the Na(+)-dependent hexose carrier during this polarization process. A similar result was observed for the development of the other apical proteins, while the development of Na+/K(+)-ATPase seemed to be largely insensitive to colchicine. Our results are in agreement with the model that the vesicles containing the apical membrane proteins use microtubules as tracks to reach the plasma membrane. The transport of vesicles containing basolateral membrane proteins clearly occurs by a different pathway which is independent on an intact microtubular network. Since the inhibition by the microtubule-disrupting drugs was complete, it can be concluded that after disruption of microtubules, the apical vesicles do not use the basolateral pathway by default.

Effects of attachment substrates on the growth and differentiation of LLC-PK1 cells

The growth and differentiation of an established renal epithelial cell line, LLC-PK1, on membrane bound mussel adhesive protein (MAP), collagen, and extracellular matrix (ECM) in serum-containing medium was studied. Cell attachment and growth on uncoated- vs. protein-coated cellulose nitrate and acetate membranes did not differ significantly, and confluence was achieved on all membranes. However, cells remained in a single monolayer only when plated on collagen or ECM. LLC-PK1 monolayers grown on ECM-coated membranes displayed the highest transepithelial D-glucose transport (333 +/- 22 ng.cm-2.min-1) whereas cells plated on collagen-coated membranes displayed the lowest (94 +/- 23 ng.cm-2.min-1). Glucose flux values increased with age of the culture, reaching a plateau at 28 d postseeding. These results indicate that the underlying substratum and cell age can affect differentiation of renal epithelial cells in vitro.

Morphology of the differentiation and maturation of LLC-PK1 epithelia

In the present study, a stereologic approach was utilized to quantitatively assess morphological changes during the differentiation of LLC-PK1 cells into an epithelial membrane. This renal epithelial cell line has been described to undergo morphological changes during differentiation and maturation from subconfluent culture to a confluent epithelial layer. An increase in the number of apical microvilli, interpreted as an areal increase in this membrane domain was reported. This morphological differentiation was found to be accompanied by an increase in the expression of apical Na(+)-dependent hexose transport and the activities of certain brush border enzymes. Since no data are available that quantify the morphologic changes during LLC-PK1 differentiation, a quantitative morphologic-stereologic-investigation was performed for an early (6 days) and a late (12 days) state of confluence of LLC-PK1 monolayer cultures. The following morphological parameters were determined by light and electron microscopic morphometry: volume fractions (Vv) of nuclei, mitochondria, and lysosomes, and surface densities (Sv) of the apical and basolateral cell membrane domains. For the apical membrane surface, the microvillous fraction has been measured separately. Since the stereologic approach used in the present study allows the determination of absolute cell volumes, the absolute measures of organelle volumes (V) and membrane surfaces (S) per average cell can be calculated from volume and surface densities. Although no changes in cell density were found for 6 and 12 day old LLC-PK1 monolayers, indicating ceased cell proliferation due to contact inhibition, remarkable changes were found concerning the absolute cell volume and apical membrane surface. The observed increase in the apical cell surface was exclusively due to the enlarged microvillous surface fraction. This finding is in good agreement with the increased number of Na(+)-dependent hexose transporters as well as with the increased expression of apical membrane marker enzymes observed during the differentiation of LLC-PK1 monolayers.

Cell polarity and development of the first epithelium

In the 4 1/2 to 5 days between fertilization and implantation, the mouse conceptus must gain the abilities to implant and produce an embryo. Each of these is the sole developmental responsibility of one of two cell types forming the blastocyst, trophectoderm and inner cell mass (ICM), respectively. Trophectoderm is a polarized transporting epithelium while the ICM is an aggregate of non-epithelial pluripotent stem cells. These two cell types originate from the division of polar blastomeres when their cleavage furrows parallel their apical surfaces. Blastomeres polarize in response to asymmetric cell--cell contact, and understanding the mechanism of this induction is regarded as the key to understanding the origin of trophectoderm and ICM. Here we propose a model based on transcellular ion current loops for the induction of cell polarity during the development of the first epithelium, trophectoderm.

Different pattern of differentiation in two LLC-PK1 clones

Two clones (LD3 and LC3) were isolated from the established renal cell line LLC-PK1. They differed with respect to the development of the Na+-dependent alpha-methyl-D-glucoside (AMG) uptake. The higher uptake capacity in LD3 as compared to LC3 was owing to the expression of a higher number of carrier molecules as was shown by the specific phlorizin binding. The intracellular cyclic AMP level, the D-glucose concentration in the growth medium and the cell density could be excluded as the causes of the difference between both clones. We found that the faster development of the Na+-dependent hexose carrier in LD3 was parallelled by a faster expression of trehalase in this clone. This suggests that the expression of both apical proteins is correlated. From the growth curves it was concluded that renewal of the undifferentiated population was roughly the same in both clones. The recruitment of cells from the undifferentiated to the growth arrested state seems also very similar as was deduced from the development of tight junctions and from the down-regulation of the alpha-methylaminoisobutyric acid (meAIB) uptake. The start of differentiation was identical as was shown by the similar rate of expression found for gamma-glutamyl transferase. The difference between both clones is most likely situated at the traverse to a fully differentiated cell. This process takes more time in LC3 than in LD3. Also the fully differentiated state seemed to be different in both clones. We conclude that the pattern of differentiated characteristics found in both clones is different and a model incorporating these differences is presented.