Cotransport System Research Articles

Neutral amino acid transport mediated by ortholog of imino acid transporter SIT1/SLC6A20 in opossum kidney cells

Most neutral l-amino acid acids are transported actively across the luminal brush-border membrane of small intestine and kidney proximal tubule epithelial cells by a Na(+) cotransport system named B(0) that has been recently molecularly identified (B(0)AT1, SLC6A19). We show here that the opossum kidney-derived cell line OK also displays a Na(+)-dependent B(0)-type neutral l-amino acid transport, although with a slightly differing substrate selectivity. We tested the hypothesis that one of the two B(0)AT1-related transporters, SLC6A18 (ortholog of orphan transporter XT2) or SLC6A20 (ortholog of the recently identified mammalian imino acid transporter SIT1), mediates this transport. Anti-sense RNA to OK SIT1 (oSIT1) but not to OK XT2 (oXT2) inhibited Na(+)-dependent neutral amino acid transport induced by OK mRNA injected in Xenopus laevis oocytes. Furthermore, inhibition of oSIT1 gene expression in OK cells by transfection of siRNA and expression of shRNA selectively reduced the Na(+)-dependent uptake of neutral l-amino acids. Finally, expression of OK cell oSIT1 cRNA in X. laevis oocytes induced besides the transport of the l-imino acid l-Pro also that of neutral l-amino acids. Taken together, the data indicate that in OK cells SIT1 (SLC6A20) is not only an apical imino acid transporter but also plays a major role as Na(+)-dependent neutral l-amino acid transporter. A similar double role could be envisaged for SIT1 in mammalian kidney proximal tubule and small intestine.

Nateglinide uptake by a ceftibuten transporter in the rat kidney brush-border membrane

Nateglinide, a novel oral hypoglycemic agent, possesses a carbonyl group and a peptide-type bond in its structure. We previously reported that nateglinide transport occurs via a single system that may be identical to the ceftibuten/H + cotransport system by the rat small intestine. We speculated that the absorption system present on the intestinal epithelium may be similar to that found on the renal tubular epithelium. The aim of this study was to characterize the transporters on the apical side of the kidney that may contribute to the reabsorption of ceftibuten and nateglinide. The uptake of nateglinide by rat renal brush-border membranes is associated with an H +-coupled transport system. Ceftibuten competitively inhibited H +-dependent nateglinide uptake. In contrast, Gly-Sar, cephradine and cephalexin had no effect on nateglinide uptake. Nateglinide competitively inhibited H +-driven transporter-mediated ceftibuten uptake. We conclude that nateglinide transport occurs via a single system that is H +-dependent and may be identical to the ceftibuten/H + cotransport system.

Food−Drug Interaction between Ferulic Acid and Nateglinide Involving the Fluorescein/H+ Cotransport System

In clinical, patients usually take many kinds of drugs at the same time. Thus, drug-drug interactions involving transporters can often directly affect the therapeutic safety and efficacy of many drugs. However, there have been few studies on food-drug interactions involving transporters. Dietary polyphenols have been widely assumed to be beneficial to human health. Polyphenols are commercially prepared and used as functional foods. We report here for the first time that ferulic acid, which is widely used as a functional food, affects the transport of clinical agents. It is important to be aware of the potential of food-drug interactions and to act in order to prevent undesirable and harmful clinical consequences.

Intracellular [H+]: a determinant of cell volume in skeletal muscle

Intracellular [H⁺]: a determinant of cell volume in skeletal muscle

Regulation of the excitatory amino acid transporter EAAT5 by the serum and glucocorticoid dependent kinases SGK1 and SGK3

In the mammalian retina, glutamate re-uptake is mediated by the sodium dependent cotransport systems EAAT1-5 thus terminating neuronal excitation and preventing neuroexcitotoxicity. In retinal amacrine and ganglion cells, EAAT5 is colocalized with the serum and glucocorticoid inducible kinase SGK1, a serine/threonine kinase known to regulate transport. The study explored the possible regulation of EAAT5 by SGK1, its isoform SGK3, and the closely related protein kinase B. EAAT5 was coexpressed in Xenopus laevis oocytes with or without the respective kinases. Transport activity was quantified by electrophysiology and cell surface expression was determined by chemiluminescence. Both EAAT5 mediated currents and EAAT5 protein abundance at the cell surface were increased by a factor of 1.5–2 upon coexpression of SGK1 or SGK3 but not following coexpression of PKB. In conclusion, the kinases SGK1 and SGK3 increase EAAT5 activity by increasing cell surface abundance of the carrier.

Transport de phosphate et lithiase rénale

Our understanding of phosphate homeostasis and of its abnormalities has improved substantially during the last decade thanks to major advances in two areas: on the one hand, molecular identification of sodium-phosphate cotransport systems belonging to three major families and, on the other hand, discovery of regulatory factors, consisting of either intracellular proteins which interact with these cotransporters, or circulating peptides. Phenotypic analysis of genetically modified mice and of human disorders has shed light on the key role of the phosphate balance in kidney stone formation.

Intestinal uptake of nateglinide by an intestinal fluorescein transporter

Nateglinide, a novel oral hypoglycemic agent, rapidly reaches its maximum serum concentration after oral administration, suggesting that it is rapidly absorbed in the intestine. However, nateglinide itself is not transported by MCT1 or PEPT1. The aim of this study was to characterize the transporters on the apical side of the small intestine that are responsible for the rapid absorption of nateglinide. It has been reported that the uptake of fluorescein by Caco-2 cells occurs via an H +-driven transporter and that the intestinal fluorescein transporter is probably not MCT1. We examined the contribution of the fluorescein transporter to the uptake of nateglinide by Caco-2 cells. Fluorescein competitively inhibited H +-dependent nateglinide uptake. All of fluorescein transporter inhibitors examined reduced the uptake of nateglinide. Furthermore, nateglinide inhibited fluorescein uptake. We conclude that the intestinal nateglinide/H + cotransport system is identical to the intestinal fluorescein/H + cotransport system.

A novel alkali‐tolerant Yarrowia lipolytica strain for dissecting Na+‐coupled phosphate transport systems in yeasts

The newly isolated osmo-, salt- and alkali-tolerant Yarrowia lipolytica yeast strain is remarkable by its capacity to grow at alkaline pH values (pH 9.7), which makes it an excellent model system for studying Na(+)-coupled phosphate transport systems in yeast cells grown at alkaline conditions. In cells Y. lipolytica grown at pH 9.7, phosphate uptake was mediated by several kinetically discrete Na(+)-dependent systems that are specifically activated by Na(+) ions. One of these, a low-affinity transporter, operated at high-phosphate concentrations. The other two, derepressible, high-affinity, high-capacity systems, functioned during phosphate starvation. Both H(+)- and Na(+)-coupled high-affinity phosphate transport systems of Y. lipolytica cells were under the dual control of the prevailing extracellular phosphate concentrations and pH values. The contribution of the Na(+)/P(i)-cotransport systems into the total cellular phosphate uptake activity was progressively increased with increasing pH, reaching its maximum at pH > or = 9.

High glucose-induced oxidative stress inhibits Na+/glucose cotransporter activity in renal proximal tubule cells

Oxidative stress plays an important role in the pathogenesis of renal diseases such as diabetic nephropathy. The metabolism of excessive intracellular glucose may involve a number of processes. One consequence of excessive intracellular glucose levels is an increased rate of oxidative phosphorylation under hyperglycemic conditions, whereas another consequence is an increase in the metabolism of glucose to sorbitol by aldose reductase. In addition, hyperglycemia may result in the activation of NADPH oxidase, the production of superoxide anion, and hydrogen peroxide (H2O2). In this report, we investigate the mechanisms responsible for the H2O2 production that occurs as the consequence of hyperglycemia and the effect of H2O2 on the activity of the Na+/glucose cotransport system (SGLT) in primary cultures of renal proximal tubule cells (PTCs). When primary PTCs were cultured in the presence of high glucose, one consequence was that the Na+/glucose cotransport system was inhibited, as indicated by uptake studies utilizing alpha-methyl-D-glucoside (alpha-MG), a nonmetabolizable analog of D-glucose. Pretreatment of the cultures with either 1) aminoguanidine or pyridoxamine [inhibitors of the accumulation of advanced glycation end products (AGEs)], 2) rotenone (an inhibitor of the mitochondrial electron transport chain), or 3) apocynin or diphenylene iodonium (DPI; inhibitors of NADPH oxidase) blocked the observed changes that occurred as a consequence of the incubation of the PTCs with high glucose. Included among these changes were the observed increase in H2O2 levels, as well as an increase in lipid peroxide production, and a decrease both in the activity of catalase and in the level of glutathione (GSH), endogenous antioxidants. The high glucose-induced decrease in the level of the Na+/glucose cotransporter was similarly prevented by either aminoguanidine, rotenone, or apocynin. Thus the inhibitory effect of high glucose on both the level of the Na+/glucose cotransport system and the activity of the Na+/glucose cotransport system can be explained, at least in part, as being due to the effects of the H2O2, the consequent formation of AGEs, the increase in mitochondrial metabolism, and in NADPH oxidase activity in the PTCs. Other related changes observed in the PTCs that could be reversed by treatment with either aminoguanidine, pyridoxamine, rotenone, apocynin, or DPI included an increase in transforming growth factor-beta1 secretion and the activation of the NF-kappaB signal transduction pathway.

A new alkalitolerant Yarrowia lipolytica yeast strain is a promising model for dissecting properties and regulation of Na+-dependent phosphate transport systems

A newly isolated osmo-, salt-, and alkalitolerant Yarrowia lipolytica yeast strain is distinguished from other yeast species by its capacity to grow vigorously at alkaline pH values (9.7), which makes it a promising model organism for studying Na+-dependent phosphate transport systems in yeasts. Phosphate uptake by Y. lipolytica cells grown at pH 9.7 was mediated by several kinetically discrete Na+-dependent systems specifically activated by Na+. One of these, a low-affinity transporter, operated at high concentrations of extracellular phosphate. The other two, high-affinity systems, maximally active in phosphate-starved cells, were repressed or derepressed depending on the prevailing extracellular phosphate concentration and pH value. The contribution of Na+/P(i)-cotransport systems to the total cellular phosphate uptake progressively increased with increasing pH, reaching its maximum at pH >/= 9.

H+-dependent transport mechanism of nateglinide in the brush-border membrane of the rat intestine.

(-)-N-(trans-4-Isopropylcyclohexanecarbonyl)-D-phenylalanine (nateglinide) is a novel oral hypoglycemic agent possessing a carboxyl group and a peptide-type bond in its structure. Although nateglinide quickly reaches the maximal serum concentration after oral administration, nateglinide itself is not transported by PepT1 or MCT1. The aim of this study was to characterize the transporters on the apical side of the small intestine that are responsible for the rapid absorption of nateglinide. The uptake of nateglinide by rat intestinal brush-border membrane vesicles is associated with a proton-coupled transport system. Ceftibuten competitively inhibited H(+)-dependent nateglinide uptake. Glycylsarcosine (Gly-Sar), cephradine, and cephalexin did not significantly inhibit the uptake of nateglinide. The combination of Gly-Sar and nateglinide greatly reduced the uptake of ceftibuten. The effect of the combined treatment was significantly greater than that of Gly-Sar alone. Furthermore, nateglinide competitively inhibited H(+)-driven ceftibuten transporter-mediated ceftibuten uptake. Ceftibuten transport occurs via at least two H(+)-dependent transport systems: one is PepT1, and the other is the ceftibuten/H(+) cotransport system. On the other hand, we demonstrated that nateglinide transport occurs via a single system that is H(+) dependent but is distinct from PepT1 and may be identical to the ceftibuten/H(+) cotransport system.

Regulation of high-affinity sulphate transporters in plants: towards systematic analysis of sulphur signalling and regulation.

Plants require the function of plasma membrane-bound sulphate transporters for the initial uptake of inorganic sulphate. Part of this fundamental process is the energy-dependent proton/sulphate co-transport systems that are located in the surface cell layers of roots. During sulphur limitation, plants are able to activate the expression of sulphate transporters that facilitate the uptake of sulphate in roots. SULTR1;1 and SULTR1;2 are suggested to be the essential components of the sulphate uptake system in Arabidopsis roots. The physiological importance of SULTR1;1 and SULTR1;2 is supported by characteristics that can cope with sulphur deficiency: they were (i) functional high-affinity sulphate transporters; (ii) induced by sulphur limitation at the mRNA levels; and (iii) predominantly localized in the root hairs, epidermis, and cortex. The expression of high-affinity sulphate transporters was primarily regulated by sulphur in a promoter-dependent manner. Aside from the sulphur-specific regulation, the induction of SULTR1;1 and SULTR1;2 high-affinity sulphate transporters by sulphur limitation was dependent on the supply of carbon and nitrogen. In this review, the application of SULTR promoter-GFP systems for the analysis of regulatory pathways of sulphate acquisition in plants is described.

A hypothesis on the role of the electrical charge of haemoglobin in regulating the erythrocyte shape

A previously proposed mechanism of erythrocyte shape has been proposed in which the ratio of the two conformations of Band 3, the anion exchange protein, controls the erythrocyte shape by modifying the degree of contraction or relaxation of the membrane skeleton. This mechanism was previously shown to explain several observations related and unrelated to the erythrocyte shape. We show that it can also explain the occurrence of target cells in blood smears of individuals expressing Hb A variants with significantly lower and higher isoelectric points. This would provide further support of its validity and would have the following implications. The electrical charge of of Hb A influences the erythrocyte shape and deformability, thus explaining the low level of expression of Hb A2 with an isoelectric point significantly higher than Hb A. It would suggest that Hb A2 has a physiological function related to the control of the erythrocyte shape. This could be of regulating the activity of the K–Cl cotransport system or of tuning finely the cell pH. A role of haemoglobin in the control of the erythrocyte shape would ensure a more efficient oxygenation of tissues and removal of carbon dioxide generated by tissues. It would also provide a basis for the absence of spreading in populations of some haemoglobin variants differing only by the electrical charge.

Physiological adaptations of the gut in the Lake Magadi tilapia, Alcolapia grahami, an alkaline- and saline-adapted teleost fish

We describe the gut physiology of the Lake Magadi tilapia ( Alcolapia grahami), specifically those aspects associated with feeding and drinking while living in water of unusually high carbonate alkalinity (titratable base=245 mequiv l −1) and pH (9.85). Drinking of this highly alkaline lake water occurs at rates comparable to or higher than those seen in marine teleosts. Eating and drinking take place throughout the day, although drinking predominates during hours of darkness. The intestine directly intersects the esophagus at the anterior end of the stomach forming a ‘T’, and the pyloric sphincter, which comprises both smooth and striated muscle, is open when the stomach is empty and closed when the stomach is full. This unique configuration (a functional trifurcation) allows imbibed alkaline water to bypass the empty stomach, thereby avoiding a reactive mixing with acidic gastric fluids, and minimizes interference with a full stomach. No titratable base was present in the stomach, where the mean pH was 3.55, but the intestine was progressively more alkaline (foregut 6.96, midgut 7.74, hindgut 8.12, rectum 8.42); base levels in the intestinal fluid were comparable to those in lake water. The gut was highly efficient at absorbing water (76.6%), which accompanied the absorption of Na + (78.5%), titratable base (80.8%), and Cl − (71.8%). The majority of Na +, base and water absorption occurred in the foregut by an apparent Na + plus base co-transport system. Overall, more than 70% of the intestinal flux occurred via Na + plus base co-transport, and less than 30% by Na + plus Cl − co-transport, a very different situation from the processes in the intestine of a typical marine teleost.

Differential expression of Na+/D-glucose cotransport in isolated cells of Marsupenaeus japonicus hepatopancreas.

D-Glucose absorptive processes at the gastrointestinal tract of decapod crustaceans are largely under-investigated. We have studied Na(+)-dependent D-glucose transport (Na(+)/D-glucose cotransport) in the hepatopancreas of the Kuruma prawn, Marsupenaeus japonicus, using both brush-border membrane vesicles and purified R and B hepatopancreatic cell suspensions. As assessed by brush-border membrane vesicle studies, Na(+)/D-glucose cotransport was inhibited by phloridzin and responsive to the (inside negative) membrane potential. Furthermore, it was strongly activated by protons (although only in the presence of an inside-negative membrane potential), which correlates with the fact that the lumen of crustacean hepatopancreatic tubules is acidic. When assayed in purified R and B cell suspensions, Na(+)/D-glucose cotransport activity was restricted to B cells only. Mab 13, a monoclonal antibody recognizing an 80- to 85-KDa protein at the brush-border membrane location, inhibited Na(+)/D-glucose cotransport in brush-border membrane vesicles as well as in enriched B cell suspensions. Primers designed after comparison of highly homologous regions of various mammalian sodium-glucose transporter) nucleotide sequences failed to produce RT-PCR amplification products from Kuruma prawn hepatopancreatic RNA. The molecular nature of this Na(+)/D-glucose cotransport system is still to be established.

Osmoregulation in the parasitic protozoan Tritrichomonas foetus.

Tritrichomonas foetus was shown to undergo a regulatory volume increase (RVI) when it was subjected to hyperosmotic challenge, but there was no regulatory volume decrease after hypoosmotic challenge, as determined by using both light-scattering methods and measurement of intracellular water space to monitor cell volume. An investigation of T. foetus intracellular amino acids revealed a pool size (65 mM) that was similar to that of Trichomonas vaginalis but was considerably smaller than those of Giardia intestinalis and Crithidia luciliae. Changes in amino acid concentrations in response to hyperosmotic challenge were found to account for only 18% of the T. foetus RVI. The T. foetus intracellular sodium and potassium concentrations were determined to be 35 and 119 mM, respectively. The intracellular K(+) concentration was found to increase considerably during exposure to hyperosmotic stress, and, assuming that there was a monovalent accompanying anion, this increase was estimated to account for 87% of the RVI. By using light scattering it was determined that the T. foetus RVI was enhanced by elevated external K(+) concentrations and was inhibited when K(+) and/or Cl(-) was absent from the medium. The results suggested that the well-documented Na(+)-K(+)-2Cl(-) cotransport system was responsible for the K(+) influx activated during the RVI. However, inhibitors of Na(+)-K(+)-2Cl(-) cotransport in other systems, such as quinine, ouabain, furosemide, and bumetanide, had no effect on the RVI or K(+) influx in T. foetus.

Sodium and the heart: a hidden key factor in cardiac regulation

Myocyte Na+ homeostasis is crucially involved in a number of vital cell functions, such as excitability, excitation–contraction coupling, energy metabolism, pH regulation, as well as cardiac development and growth. However, consideration of Na+ regulation is often relegated to a secondary position in the discussion of cardiac (patho-)physiology, where the focus is typically on contractile proteins, Ca2+ regulation and pH regulation which appear more directly related to contractile function. However, myocyte Na+ homeostasis is as complex as Ca2+ or pH homeostasis and [Na+]i very directly influences intracellular [Ca2+] and pH via powerful cardiac Na/Ca exchange, Na/H exchange and Na-bicarbonate cotransport systems. Na+ flux my even be central in mediating effects of mechanical loading of the heart on excitation–contraction coupling. Moreover, [Na+]i homeostasis is regulated by a delicate balance of Na+ channels and transporters in the surface and mitochondrial membrane that maintain a large [Na+] gradient across the sarcolemmal membrane. Given this fundamental but often overlooked contribution of Na … * Corresponding author. Tel.: +49-551-3989-25; fax: +49-551-3919-127.

Membrane ion transport in erythrocytes of salt hypertensive Dahl rats and their F2 hybrids: the importance of cholesterol.

The possible association of salt hypertension and altered lipid metabolism with abnormalities of particular systems transporting sodium and potassium has been studied in erythrocytes of Dahl rats and their F2 hybrids fed a high-salt diet since weaning. Our attention was paid to the Na(+)-K+ pump, Na(+)-K+ cotransport and especially to passive membrane permeability for Na+ and Rb+ (Na+ and Rb+ leak), because the Na+ leak was found to be dependent on the genotype, age and salt intake of Dahl rats, whereas the Rb+ leak was suggested to be a potential marker of salt sensitivity in Dahl and Sabra rats. Young male Dahl salt-sensitive (SS/Jr) and salt-resistant (SR/Jr) rats kept on a low-salt (0.3% NaCl) or high-salt diet (8% NaCl) were used for the progenitor study. The subsequent genetic study was based on 135 young male SS/Jr x SR/Jr F2 hybrids fed a high-salt diet since weaning. Ouabain (5 mmol/l) and bumetanide (10 micromol/l) were used to distinguish the contribution of the Na(+)-K+ pump, Na(+)-K+ cotransport and passive membrane permeability to measured net Na+ fluxes and unidirectional Rb+ (K+) movements. Compared to normotensive SR/Jr animals, salt-loaded SS/Jr rats had higher blood pressure (BP), elevated erythrocyte Na+ content, and increased Na+ and Rb+ leaks together with enhanced Na+ and Rb+ transport mediated by the Na(+)-K+ pump and Na(+)-K+ cotransport system. Salt hypertensive Dahl rats were also characterized by elevated plasma levels of total cholesterol and triglycerides, which were positively associated with BP of F2 hybrids (r=0.27 and 0.24, p< 0.01). In F2 hybrids, mean arterial pressure correlated significantly with erythrocyte Na+ content (r=0.24, p<0.01) and ouabain-sensitive Na+ extrusion, but not with the passive membrane permeability for Na+ or Rb+ (r=-0.02 and 0.06, not significant). Both of the above-mentioned significant associations could partially be ascribed to the dependence of erythrocyte Na+ content and ouabain-sensitive Na+ extrusion on plasma cholesterol (r=0.18 and 0.21, p<0.05). Our results support the idea that abnormal lipid metabolism and/or altered Na+,K(+)-ATPase function play an important role in the pathogenesis of salt hypertension in salt-sensitive Dahl rats.

Clonal Analysis of Immortalized Renal Proximal Tubule Cells: Na +/Glucose Cotransport System Levels Are Maintained Despite a Decline in Transport Function

Primary rabbit kidney proximal tubule (RPT) cells (S.D. Chung et al., 1982, J. Cell Biol. 95, 118–126) were transfected with the vector pRSV-T, which contains SV40 early region genes. After the third passage (when normal cells had stopped dividing), individual colonies formed in cultures transfected with pRSV-T. Clonal isolates (RPT-I cells) could be obtained in a simple and reproducible manner. Southern analysis of clone RPT-I8 indicated the presence of SV40 early region genes. Nuclear SV40 T was detected. After 23 passages, and subcloning, RPT-I8 (and subclones) was found to express renal proximal tubule markers to a similar extent, indicating that the phenotype was stable. Nevertheless, the activities of the Na +/glucose cotransport system, γ-glutamyl transpeptidase and alkaline phosphatase, were reduced as compared with primary cultures. Western analysis indicated that the level of Na +/glucose cotransporters was maintained in RPT-I8 cells, when compared with intact proximal tubules and primary cultures. Thus, the reduction in α-MG uptake in RPT-I8 cells may be attributed to other types of cellular alterations, including changes in energy metabolism. Indeed, growth in glucose-free medium was not observed in RPT-I8 cell cultures, suggesting that unlike primary RPT cells (J. C. Chung et al., 1992, J. Cell. Physiol. 150, 243–250), the gluconeogenic pathway was not intact.

A novel regulatory mechanism for amino acid absorption in lepidopteran larval midgut

A number of methyl and ethyl esters of naturally occurring amino acids exert a potent stimulatory effect on the cotransport system responsible for the absorption of most essential amino acids along the midgut of the silkworm Bombyx mori. l-Leucine methyl ester (Leu–OMe), one of the most effective activators, induces a large increase of the initial rate of leucine uptake in midgut brush border membrane vesicles (BBMV) from the anterior–middle (AM) region, and a small effect in BBMV from the posterior (P) region. Nonetheless, the methyl ester causes in both regions a relevant K +-, Δ ψ- and pH-independent increase of the intravesicular accumulation of the amino acid. The activation by Leu–OMe proves that amino acid absorption can be modulated all along the B. mori larval midgut and that the AM region, where the ability to transport and concentrate the substrate is very low, is more susceptible than the P region. Leucine uptake in AM-BMMV can be activated by amino acid methyl esters with definite structural requisites, with the following order of potency: l-leucine> l-phenylglycine> l-methionine> l-phenylalanine> l-norleucine≫ l-isoleucine. The activation is stereospecific and occurs also with some ethyl esters (e.g. leucine and phenylalanine). No activation was observed with esters of amino acids with short hydrophobic or polar side-chains. The activation mechanism here described plays a fundamental role in larval growth since silkworms reared on artificial diets supplemented with leucine or methionine methyl esters reach maximum body weight 12–18 h before control larvae and spin cocoons with a larger shell weight. This novel regulatory mechanism of an amino acid transport protein appears to be widespread among lepidopteran larvae.