Na(+)-coupled alternative to H(+)-coupled primary transport systems in bacteria.

Protons are the most common coupling ions in bacterial energy conversions. However, while many organisms, such as the alkaliphilic Bacilli, employ H(+)-bioenergetics for electron transport phosphorylation, they use Na+ as the coupling ion for transport and flagellar movement. The Na+ gradient required for these bioenergetic functions is established by the secondary Na+/H+ antiporter. In contrast, Vibrio alginolyticus and methanogenic bacteria have primary pumps for both H+ and Na+. They use the proton gradient for ATP synthesis while other, less energy-consuming membrane reactions are powered by the Na+ gradient. In a third mode, some anaerobic bacteria possess decarboxylases acting as primary Na+ pumps. For instance, in Klebsiella pneumoniae, the Na+ gradient established by oxaloacetate decarboxylase is used for the uptake of the growth substrate citrate, and Propionigenium modestum consumes the energy of the Na+ gradient formed by methylmalonyl-CoA decarboxylase directly for ATP synthesis.     

Differential regulation of Na(+),K(+)-ATPase and the Na(+)-coupled glucose transporter in hypertensive rat kidney

Several Na(+) transporters are functionally abnormal in the hypertensive rat. Here, we examined the effects of a high-salt load on renal Na(+),K(+)-ATPase and the sodium-coupled glucose transporter (SGLT1) in Dahl salt-resistant (DR) and salt-sensitive (DS) rats. The protein levels of Na(+),K(+)-ATPase and SGLT1 in the DS rat were the same as those in the DR rat, and were not affected by the high-salt load. In the DS rat, a high-salt load decreased Na(+),K(+)-ATPase activity, and this decrease coincided with a decrease in the apparent Mechaelis constant (K(m)) for ATP, but not with a change of maximum velocity (V(max)). On the contrary, a high-salt load increased SGLT1 activity in the DS rat, which coincided with an increase in the V(max) for alpha-methyl glucopyranoside. The protein level of phosphorylated tyrosine residues in Na(+),K(+)-ATPase was decreased by the high-salt load in the DS rat. The amount of phosphorylated serine was not affected by the high-salt load in DR rats, and could not be detected in DS rats. On the other hand, the amount of phosphorylated serine residues in SGLT1 was increased by the high-salt load. However, the phosphorylated tyrosine was the same for all samples. Therefore, we concluded that the high-salt load changes the protein kinase levels in DS rats, and that the regulation of Na(+),K(+)-ATPase and SGLT1 activity occurs via protein phosphorylation.     

Regulation of Na(+)-coupled glucose carrier SGLT1 by human papillomavirus 18 E6 protein

Tumor cells utilize preferably glucose for energy production. They accomplish cellular glucose uptake in part through Na⁺-coupled glucose transport mediated by SGLT1 (SLC5A1). This study explored the possibility that the human papillomavirus 18 E6 protein HPV18 E6 (E6) participates in the stimulation of SGLT1 activity. E6 is one of the two major oncoproteins of high-risk human papillomaviruses, which are the causative agent for cervical carcinoma. According to Western blotting, SGLT1 is expressed in the HPV18-positive cervical carcinoma cell line HeLa. To explore whether E6 affects SGLT1 activity, SGLT1 was expressed in Xenopus oocytes with and without E6 and electrogenic glucose transport determined by dual electrode voltage clamp. In SGLT1-expressing oocytes, but not in oocytes injected with water or expressing E6 alone, glucose triggered a current (I_g). I_g was significantly increased by coexpression of E6 but not by coexpression of E2. According to chemiluminescence and confocal microscopy, coexpression of E6 significantly increased the SGLT1 protein abundance in the cell membrane. The decay of I_g following inhibition of carrier insertion by Brefeldine A (5 μM) was not significantly affected E6 coexpression. Accrodingly, E6 was not effective by increasing carrier protein stability in the membrane. In conclusion, HPV18 E6 oncoprotein participates in the upregulation of SGLT1.     

H(+)-coupled heavy metal transport in plants

It has been recently well documented that metal transport systems play a crucial role in the uptake, distribution and detoxification of heavy metals throughout the plant. A range of gene families that are likely to be involved in essential and non-essential metal transport has been now identified and their plasma membrane and/or tonoplast localization in plant cells has been recently confirmed. These include the primary metal transporters, using ATP as the source of energy and H(+)-coupling transporters, utilizing the electrochemical gradient previously generated by plasma membrane and tonoplast proton pumps. As the presence of nucleotide binding domains in the protein sequence may indicate its ATP-hydrolytic activity, it is more difficult to determine the H(+)-coupling activity of protein on the base of its structure. Thus, the H(+)-coupling activity of protein may be only proved by functional analysis of the protein. In this work, we briefly review the structure, regulation and function of the metal transporters operating as H(+)/metal cotransporters.     

Na(+)-dependent AIB transport by neuroblastoma cells.

Na(+)-dependent amino isobutyric acid transport by two neuroblastoma cell lines with and without amplification of the oncogene N-myc is studied. Surprisingly, the contribution of system A is greater in the cell line showing no N-myc amplification. Preliminary data support a role for essential tyrosine and cysteine residues in the active center of the carriers, mainly in system A.     

Evidence for the involvement of Ala 166 in coupling Na(+) to sugar transport through the human Na(+)/glucose cotransporter

We mutated residue 166, located in the putative Na(+) transport pathway between transmembrane segments 4 and 5 of human Na(+)/glucose cotransporter (hSGLT1), from alanine to cysteine (A166C). A166C was expressed in Xenopus laevis oocytes, and electrophysiological methods were used to assay function. The affinity for Na(+) was unchanged compared to that of hSGLT1, whereas the sugar affinity was reduced and sugar specificity was altered. There was a reduction in the turnover rate of the transporter, and in contrast to that of hSGLT1, the turnover rate depended on the sugar molecule. Exposure of A166C to MTSEA and MTSET, but not MTSES, abolished sugar transport. Accessibility of A166C to alkylating reagents was independent of protein conformation, indicating that the residue is always accessible from the extracellular surface. Sugar and phlorizin did not protect the residue from being alkylated, suggesting that residue 166 is not located in the sugar pathway. MTSEA, MTSET, and MTSES all changed the pre-steady-state kinetics of A166C, independent of pH, and sugars altered these kinetics. The inability of MTSEA-labeled A166C to transport sugar was reversed (with no major change in Na(+) and sugar affinity) if the positive charge on MTSEA was neutralized by increasing the external pH to 9.0. These studies suggest that the residue at position 166 is involved in the interaction between the Na(+) and sugar transport pathways.     

Electrogenicity of Na(+)-coupled bile acid transporters.

The Na(+)-bile acid cotransporters NTCP and ASBT are largely responsible for the Na(+)-dependent bile acid uptake in hepatocytes and intestinal epithelial cells, respectively. This review discusses the experimental methods available for demonstrating electrogenicity and examines the accumulating evidence that coupled transport by each of these bile acid transporters is electrogenic. The evidence includes measurements of transport-associated currents by patch clamp electrophysiological techniques, as well as direct measurement of fluorescent bile acid transport rates in whole cell patch clamped, voltage clamped cells. The results support a Na+:bile acid coupling stoichiometry of 2:1.     

Implication of distinct proteins in cadmium uptake and transport by intestinal cells HT-29

The mechanisms of intestinal absorption have not been clearly elucidated for cadmium, a toxic metal. In this work, we show the implication of distinct proteins in cadmium transport, and the transport step where these proteins are involved. We first validated the HT-29 model by evaluating nontoxic doses of cadmium (ranging from 1 to 20 μmol/L), and by quantifying metal uptake and transepithelial transport. The time-course of 1 μmol/L cadmium uptake at pH 7.5 showed three steps: a rapid one during the first 4 min, probably due to cadmium binding to the membrane; a slower one, characterized by K _m of 1.65±0.54 μmol/L and V _max of 3.9±0.3 pmol/min per mg protein; and a third, corresponding to slow accumulation that was not equilibrated even after 48 h of cadmium exposure. Intracellular metallothionein content following 1 or 5 μmol/L cadmium exposure showed a significant increase after 6 h of exposure, and was not equilibrated even after 72 h, allowing cadmium accumulation. After 24 h of exposure, metallothionein content was 5-fold, 14-fold, 26-fold, and 50-fold, respectively, for cells grown in the presence of 1, 5, 10, and 20 μmol/L cadmium, compared to control cells. The second step of uptake, characterized by carrier-mediated transport, was markedly increased at pH 5.5, compared to pH 7.5, and strongly inhibited by the metabolic inhibitor dinitrophenol. Moreover Nramp2 transporter cDNA was present in HT-29 cells. These data suggest the involvement of a proton-coupled transporter, which may be the divalent cation transporter Nramp2 (natural resistance-associated macrophage protein 2). Cadmium uptake was also inhibited by copper, zinc, and para-chloromercuribenzenesulfonate (pCMBS), but not by verapamil or ouabain. Taken together, our results indicate that cadmium could enter HT-29 cell by Nramp2 proton-coupled active transport and by diffusion, and accumulates in the cell as long as it binds to metallothionein. Cadmium toxicity could depend partly on the activity of Nramp2, and partly on metallothionein content. This revised version was published online in July 2006 with corrections to the Cover Date.     

Expression of O-glycans during enterocytic differentiation of HT-29 cells

The expression of O- and N-glycan chains during the enterocytic differentiation of HT-29 cells was followed using L-[63H]-fucose and D-[6-3H]-glucosamine radiolabeling. Whatever the cell population, i.e., differentiated or undifferentiated, the incorporation of radiolabeled sugars into glycoproteins was similar. However, differences among these two cell populations were noted when the ratio [3H]-glucosamine/[3H]-galactosamine and the sensitivity of glycopeptides to mild alkaline treatment were followed. From these data, we could conclude that there is a shift in the high molecular weight glycopeptides during the differentiation of HT-29 cells meaning an increase of O-linked glycopeptides correlated with a decrease of N-linked forms.     

Thermodynamic stoichiometry of Na+-coupled glutathione transport

Ambiguity exists with respect to mechanisms of glutathione (GSH) transport and the molecular identity of GSH transporters. Empirical and theoretical limitations have hindered functional and molecular characterizations. Published literature referring to the isolation and molecular identification of Na+-coupled GSH transporters that mediate the cellular uptake of GSH is highly debated. Whereas a number of functional and kinetic reports of this putative symport mechanism exist, the hypothetical transmembrane Na+-coupled GSH transporter protein or the genetic message encoding it has not been isolated. Theoretical thermodynamic calculations to support the concept of secondary active GSH transport and to rationalize accounts of physical-kinetic measurements describing Na+-coupled cellular GSH uptake were performed. The adequacy of requisite energy and stoichiometric conservation of the separate electrical and chemical components of a Na+ gradient in maintaining a high cellular accumulation gradient for GSH was examined through a purely phenomenological perspective. Dependent on the biological context, the energetic coupling between Na+ and GSH cotransport may occur at ratios from 1:1 to 3:1. Molecular identification of specific transporters responsible for cellular Na+-coupled GSH uptake will facilitate determination of their relative contribution to the overall plasma membrane resting potential. In tissues with a high GSH concentration relative to their extracellular milieu, particularly in pathologies of cystic fibrosis and dry eye syndromes, large energy coupling ratios in cotransport of Na+ and GSH may be expected. Na+-coupled GSH transport may play an important role in disease onset and (or) progression, or treatment modalities thereof.     

Na(+)-coupled transport of L-carnitine via high-affinity carnitine transporter OCTN2 and its subcellular localization in kidney

The mechanism of Na(+)-dependent transport of L-carnitine via the carnitine/organic cation transporter OCTN2 and the subcellular localization of OCTN2 in kidney were studied. Using plasma membrane vesicles prepared from HEK293 cells that were stably transfected with human OCTN2, transport of L-carnitine via human OCTN2 was characterized. Uptake of L-[(3)H]carnitine by the OCTN2-expressing membrane vesicles was significantly increased in the presence of an inwardly directed Na(+) gradient, with an overshoot, while such transient uphill transport was not observed in membrane vesicles from cells that were mock transfected with expression vector pcDNA3 alone. The uptake of L-[(3)H]carnitine was specifically dependent on Na(+) and the osmolarity effect showed that Na(+) significantly influenced the transport rather than the binding. Changes of inorganic anions in the extravesicular medium and of membrane potential by valinomycin altered the initial uptake activity of L-carnitine by OCTN2. In addition, the fluxes of L-carnitine and Na(+) were coupled with 1:1 stoichiometry. Accordingly, it was clarified that Na(+) is coupled with flux of L-carnitine and the flux is an electrogenic process. Furthermore, OCTN2 was localized on the apical membrane of renal tubular epithelial cells. These results clarified that OCTN2 is important for the concentrative reabsorption of L-carnitine after glomerular filtration in the kidney.     

Regulation of Na+-coupled glucose carrier SGLT1 by AMP-activated protein kinase

Abstract

AMP-activated protein kinase (AMPK), a serine/threonine kinase activated upon energy depletion, stimulates energy production and limits energy utilization. It has previously been shown to enhance cellular glucose uptake through the GLUT family of facilitative glucose transporters. The present study explored the possibility that AMPK may regulate Na⁺-coupled glucose transport through SGLT1 (SLC5A1). To this end, SGLT1 was expressed in Xenopus oocytes with and without AMPK and electrogenic glucose transport determined by dual electrode voltage clamping experiments. In SGLT1-expressing oocytes but not in oocytes injected with water or expressing constitutively active ^γR70QAMPK (α1β1γ1(R70Q)) alone, the addition of glucose to the extracellular bath generated a current (I_g), which was half maximal (K_M) at ≈ 650 μM glucose concentration. Coexpression of ^γR70QAMPK did not affect K_M but significantly enhanced the maximal current (≈ 1.7 fold). Coexpression of wild type AMPK or the kinase dead ^αK45RAMPK mutant (α1(K45R)β1γ1) did not appreciably affect I_g. According to confocal microscopy and Western Blotting, AICAR (1 mM), phenformin (1 mM) and A-769662 (10 μM) enhanced the SGLT1 protein abundance in the cell membrane of Caco2 cells suggesting that AMPK activity may increase membrane translocation of SGLT1. These observations support a role for AMPK in the regulation of Na⁺-coupled glucose transport.     

Residue 457 controls sugar binding and transport in the Na(+)/glucose cotransporter

The Na(+)/glucose cotransporter (SGLT1) is highly selective for its natural substrates, d-glucose and d-galactose. We have investigated the structural basis of this sugar selectivity on the human isoform of SGLT1, single site mutants of hSGLT1, and the pig SGLT3 isoform, expressed in Xenopus oocytes using electrophysiological methods and the effects of cysteine-specific reagents. Kinetics of transport of glucose analogues, each modified at one position of the pyranose ring, were determined for each transporter. Correlation of kinetics with amino acid sequences indicates that residue Gln-457 sequentially interacts with O1 of the pyranose in the binding site, and with O5 in the translocation pathway. Furthermore, correlation of the selectivity characteristics of the SGLT isoforms (SGLT1 transports both glucose and galactose, but SGLT2 and SGLT3 transport only glucose) with amino acid sequence differences, suggests that residue 460 (threonine in SGLT1, and serine in SGLT2 and SGLT3) are involved in hydrogen bonding to O4 of the pyranose. In addition, the results show that substrate specificity of binding is not correlated to substrate specificity of transport, suggesting there are at least two steps in the sugar translocation process.