Expression and transport function of the glutamate transporter EAAC1 inXenopus oocytes is regulated by syntaxin 1A

The function of several membrane proteins is regulated by interaction with the SNARE protein syntaxin 1A; this includes regulation of GAT1, the transporter for the dominating inhibitory neurotransmitter gamma-aminobutyric acid (GABA). Here we demonstrate that also EAAC1, the transporter for the dominating excitatory neurotransmitter, is down-regulated by interaction with syntaxin 1A. This is shown by coexpression of EAAC1 and syntaxin 1A in Xenopus oocytes. Total EAAC1 expression is not significantly affected by the coexpression of syntaxin 1A, but more proteins become targeted to the membrane as demonstrated by biotinylation. Colocalization by coimmunoprecipitation suggests direct interaction between the two proteins. In contrast to the number of transporters, the glutamate transport activity becomes reduced, and even stronger inhibition is observed for the EAAC1-mediated conductance uncoupled from glutamate translocation. We conclude that the interaction of syntaxin 1A with EAAC1 particularly disrupts the structure of the conductance pathway of EAAC1.

Effects of chemical chaperones on partially retarded NaCl cotransporter mutants associated with Gitelman's syndrome in a mouse cortical collecting duct cell line

BACKGROUND

Epithelial cells lining the distal convoluted tubule express the thiazide-sensitive Na-Cl cotransporter (NCC) that is responsible for the reabsorption of 5-10% of the filtered load of Na(+) and Cl(-). Mutations in NCC cause the autosomal recessive renal disorder Gitelman's syndrome (GS). GS mutations give rise to mutant transporters that are either fully (class I) or partially (class II) retarded. Recent evidence indicates that class II mutations do not alter the intrinsic transport activity of NCC. These findings suggest that in GS caused by class II NCC mutations, pharmacological chaperones may be useful in treatment.

METHODS

Initial attempts using 4-phenylbutyrate and glycerol to increase Na(+) uptake in Xenopus laevis oocytes expressing the class II mutant L215P were unsuccessful. To study the effect of the chaperones in a more physiological setting, we next expressed hNCC in the polarized epithelial cell line of distal tubular origin, mpkCCD.

RESULTS

mpkCCD cells readily expressed the class II mutant R955Q, but not the class I mutant G741R. Wild-type hNCC was predominantly present in the approximately 120-1403 kD complex glycosylated form. In contrast, the R955Q mutant was predominantly present in a lower molecular weight form of approximately 100 kD. Pretreatment of R955Q expressing cells with 4-phenylbutyrate (5 mM, 16 h), but not thapsigargin (1 microM, 90 min), dimethyl sulfoxide (1%, 16 h) or glycerol (4%, 16 h), increased the expression of the complex glycosylated form and in parallel the number of hNCC positive cells.

CONCLUSIONS

Taken together, the data indicate that 4-phenylbutyrate is a promising candidate for rescuing partially retarded but otherwise functional class II GS mutants.

Different functional roles of arginine residues 39 and 61 and tyrosine residue 98 in transport and channel mode of the glutamate transporter EAAC1

The excitatory amino acid transporter EAAC1 is an electrogenic Na+ - and K+ -gradient-driven transporter. In addition, the transporter mediates in the presence of Na+ and glutamate an anion conductance uncoupled from the transport of the glutamate. The first two N-terminal domains, important for forming the conductance mode, are extracellularly bordered by positively charged arginine residues, R39 and R61, being completely conserved throughout the transporter family. Also the conserved tyrosine residue Y98 could be important for Cl- conductance. We have investigated, by measurements of glutamate uptake and glutamate-induced currents, the effects of mutation of the arginines and the tyrosine to alanine. The mutation R39A hardly affects transport and channel mode. The mutation R61A, on the other hand, reduces the activity of transport but stimulates the channel conductance. In addition, the apparent Km values for glutamate uptake and for the glutamate-activated current are reduced. Glutamate stimulation of current seems to be associated with a voltage-dependent step, and the apparent valence of charge moved during binding is reduced in the R61A mutant. The mutation Y98A leads to reduced function with reduced apparent Km value for glutamate, and with strong reduction of the selectivity ration between NO3- and Cl- of the conductance mode.

Malfunction of respiratory-related neuronal activity in Na+, K+-ATPase alpha2 subunit-deficient mice is attributable to abnormal Cl- homeostasis in brainstem neurons

Na+, K+-ATPase 2 subunit gene (Atp1a2) knock-out homozygous mice (Atp1a2-/-) died immediately after birth resulting from lack of breathing. The respiratory-related neuron activity in Atp1a2-/- was investigated using a brainstem-spinal cord en bloc preparation. The respiratory motoneuron activity recorded from the fourth cervical ventral root (C4) was defective in Atp1a2-/- fetuses of embryonic day 18.5. The C4 response to electrical stimulation of the ventrolateral medulla (VLM) recovered more slowly in Atp1a2-/- than in wild type during superfusion with Krebs' solution, consistent with the high extracellular GABA in brain of Atp1a2-/-. Lack of inhibitory neural activities in VLM of Atp1a2-/- was observed by optical recordings. High intracellular Cl- concentrations in neurons of the VLM of Atp1a2-/- were detected in gramicidin-perforated patch-clamp recordings. The alpha2 subunit and a neuron-specific K-Cl cotransporter KCC2 were coimmunoprecipitated in a purified synaptic membrane fraction of wild-type fetuses. Based on these results, we propose a model for functional coupling between the Na+, K+-ATPase alpha2 subunit and KCC2, which excludes Cl- from the cytosol in respiratory center neurons.

Expression of K+-Cl- cotransporters in the alpha-cells of rat endocrine pancreas

The expression of K+-Cl- cotransporters (KCC) was examined in pancreatic islet cells. mRNA for KCC1, KCC3a, KCC3b and KCC4 were identified by RT-PCR in islets isolated from rat pancreas. In immunocytochemical studies, an antibody specific for KCC1 and KCC4 revealed the expression of KCC protein in alpha-cells, but not pancreatic beta-cells nor delta-cells. A second antibody which does not discriminate among KCC isoforms identified KCC expression in both alpha-cell and beta-cells. Exposure of isolated alpha-cells to hypotonic solutions caused cell swelling was followed by a regulatory volume decrease (RVD). The RVD was blocked by 10 microM [dihydroindenyl-oxy] alkanoic acid (DIOA; a KCC inhibitor). DIOA was without effect on the RVD in beta-cells. NEM (0.2 mM), a KCC activator, caused a significant decrease of alpha-cell volume, which was completely inhibited by DIOA. By contrast, NEM had no effects on beta-cell volume. In conclusion, KCCs are expressed in pancreatic alpha-cells and beta-cells. However, they make a significant contribution to volume homeostasis only in alpha-cells.

Behavioural abnormalities of the hyposulphataemic Nas1 knock-out mouse

We recently generated a sodium sulphate cotransporter knock-out mouse (Nas1-/-) which has increased urinary sulphate excretion and hyposulphataemia. To examine the consequences of disturbed sulphate homeostasis in the modulation of mouse behavioural characteristics, Nas1-/- mice were compared with Nas1+/- and Nas1+/+ littermates in a series of behavioural tests. The Nas1-/- mice displayed significantly (P < 0.001) decreased marble burying behaviour (4.33 +/- 0.82 buried) when compared to Nas1+/+ (7.86 +/- 0.44) and Nas1+/- (8.40 +/- 0.37) animals, suggesting that Nas1-/- mice may have decreased object-induced anxiety. The Nas1-/- mice also displayed decreased locomotor activity by moving less distance (1.53 +/- 0.27 m, P < 0.05) in an open-field test when compared to Nas1+/+ (2.31 +/- 0.24 m) and Nas1+/- (2.15 +/- 0.19 m) mice. The three genotypes displayed similar spatiotemporal and ethological behaviours in the elevated-plus maze and open-field test, with the exception of a decreased defecation frequency by the Nas1-/- mice (40% reduction, P < 0.01). There were no significant differences between Nas1-/- and Nas1+/+ mice in a rotarod performance test of motor coordination and in the forced swim test assessing (anti-)depressant-like behaviours. This is the first study to demonstrate behavioural abnormalities in the hyposulphataemic Nas1-/- mice.

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.

Vitamin C is an important cofactor for both adrenal cortex and adrenal medulla

The adrenal gland is among the organs with the highest concentration of vitamin C in the body. Interestingly, both the adrenal cortex and the medulla accumulate such high levels of ascorbate. Ascorbic acid is a cofactor required both in catecholamine biosynthesis and in adrenal steroidogenesis. Here we provide an overview on the role of vitamin C in the adrenal cortex and medulla derived from in vitro and in vivo studies. In addition, recent insights gained from an animal model with a deletion in the gene for the ascorbic acid transporter will be summarized. Mutant mice lacking the plasma membrane ascorbic acid transporter (SVCT2) have severely reduced tissue levels of ascorbic acid and die soon after birth. There is a significant decrease of tissue catecholamine levels in the adrenals. On the ultrastructural level, adrenal chromaffin cells in SVCT2 null mice show depletion of catecholamine storage vesicles, signs of apoptosis, and increased glycogen storage. Decreased plasma levels of corticosterone and altered morphology of mitochondrial membranes indicate additional effects of the deficiency on adrenal cortical function. The data derived from these animal models and various cell culture studies confirm a crucial role for vitamin C for both the adrenal cortex as well as the adrenal medulla further underlining the interdependence of the two endocrine systems united in one gland.

Expression and regulation of the renal Na/phosphate cotransporter NaPi-IIa in a mouse model deficient for the PDZ protein PDZK1

Inorganic phosphate (P(i)) is reabsorbed in the renal proximal tubule mainly via the type-IIa sodium-phosphate cotransporter (NaPi-IIa). This protein is regulated tightly by different factors, among them dietary P(i) intake and parathyroid hormone (PTH). A number of PDZ-domain-containing proteins have been shown to interact with NaPi-IIa in vitro, such as Na(+)/H(+) exchanger-3 regulatory factor-1 (NHERF1) and PDZK1. PDZK1 is highly abundant in kidney and co-localizes with NaPi-IIa in the brush border membrane of proximal tubules. Recently, a knock-out mouse model for PDZK1 (Pdzk1(-/-)) has been generated, allowing the role of PDZK1 in the expression and regulation of the NaPi-IIa cotransporter to be examined in in vivo and in ex vivo preparations. The localization of NaPi-IIa and other proteins interacting with PDZK1 in vitro [Na(+)/H(+) exchanger (NHE3), chloride-formate exchanger (CFEX)/putative anion transporter-1 (PAT1), NHERF1] was not altered in Pdzk1(-/-) mice. The abundance of NaPi-IIa adapted to acute and chronic changes in dietary P(i) intake, but steady-state levels of NaPi-IIa were reduced in Pdzk1(-/-) under a P(i) rich diet. This was paralleled by a higher urinary fractional P(i) excretion. The abundance of the anion exchanger CFEX/PAT1 (SLC26A6) was also reduced. In contrast, NHERF1 abundance increased in the brush border membrane of Pdzk1(-/-) mice fed a high-P(i) diet. Acute regulation of NaPi-IIa by PTH in vivo and by PTH and activators of protein kinases A, C and G (PKA, PKC and PKG) in vitro (kidney slice preparation) was not altered in Pdzk1(-/-) mice. In conclusion, loss of PDZK1 did not result in major changes in proximal tubule function or NaPi-IIa regulation. However, under a P(i)-rich diet, loss of PDZK1 reduced NaPi-IIa abundance indicating that PDZK1 may play a role in the trafficking or stability of NaPi-IIa under these conditions.

[ATHK1 gene regulates signal transduction of osmotic stress in Arabidopsis thaliana]

Differences in physiology and gene expression between ATHK1 knock-out mutant caused by T-DNA insertion and wild type (WT) of WS accession of Arabidopsis thaliana were analysed. Water loss ratio of detached leaf of ATHK1-mutant was obviously higher than that of WT. After being treated with 30% PEG-6000, ion leakage ratio of cell membrane in wild type leaves was 50% higher than that before PEG treatment, while in mutant leaves it increased 80%. The wilted phenotype of ATHK1-mutant after PEG treatment for 48 h was higher than that of WT. All these results showed that ATHK1-mutant was more sensitive to osmotic stress compared to WT and ATHK1 involved in osmotic stress adaptation. Differential-Display Reverse Transcription-PCR (DDRT-PCR) analysis was carried out to investigate the difference of gene expression between ATHK1-mutant and WT. Nine differential cDNA fragments involved in stress adaptation were identified, including the MAPKKK18 and serine/threonine protein kinase genes. These fragments were up-regulated by PEG treatment in WT, but not in ATHK1-mutant. These results indicate that ATHK1 plays an important role up-stream from MAPK in the osmotic stress signal transduction pathway. ATHK1 may be working as a plant osmosensor.

Partial characterization of cytoprotective mechanisms of lecithin against bile salt-induced bile duct damage

BACKGROUND

We recently demonstrated that cyclosporine A causes a disproportionate reduction of biliary lipid secretion, and this is inhibited by hydrophilic bile salts through the enhancing of biliary lecithin secretion. In the present study, the underlying mechanism of such a cytoprotective action of hydrophilic bile salts was determined with attention to the possible role of lecithin.

METHODS

Immortalized mouse cholangiocytes were cultured for 4 h with taurine conjugates of a hydrophobic bile salt (cholate [TC]), and hydrophilic bile salts (ursodeoxycholate [TUDC], betamuricholate [TbetaMC], and alphamuricholate [TalphaMC]), at 200 microM, in the presence or absence of lecithin (5, 10, 25, 50, 100, or 200 microM), followed by flow cytometric detection of apoptosis, using Annexin V-fluorescein isothiocyanate (FITC)/propidium iodide (PI) staining. Cholangiocyte bile salt transporter mRNAs (apical sodium-dependent bile-salt transporter [Asbt] and multidrug resistance protein 3 [Mrp3]) were determined by reverse transcription-polymerase chain reaction (RT-PCR).

RESULTS

Apoptosis was induced by all of the bile salts (TC > TUDC, TbetaMC, and TalphaMC). Interestingly, bile salt-induced apoptosis was inhibited by lecithin in a concentration-dependent manner. Further, RT-PCR showed that the expressions of Asbt and Mrp3 mRNAs were enhanced by all the bile salts, whereas lecithin reduced Asbt expression, but enhanced Mrp3 expression.

CONCLUSIONS

These findings indicate that bile salts cause bile-duct cell damage through Asbt-mediated uptake, but that biliary lecithin physiologically inhibits such damage by reducing the expression of this transporter. In addition, the induction of Mrp3 expression by lecithin may play a role in inhibiting the accumulation of bile. Thus, the modulation of lecithin secretion into bile may be another important target for the treatment of biliary disorders.

Altered renal distal tubule structure and renal Na(+) and Ca(2+) handling in a mouse model for Gitelman's syndrome

Gitelman's syndrome, an autosomal recessive renal tubulopathy caused by loss-of-function mutations in the thiazide-sensitive NaCl co-transporter (NCC) of the distal convoluted tubule (DCT), is characterized by mild renal Na(+) wasting, hypocalciuria, hypomagnesemia, and hypokalemic alkalosis. For gaining further insights into the pathophysiology of Gitelman's syndrome, the impact of NCC ablation on the morphology of the distal tubule, on the distribution and abundance of ion transport proteins along its length, and on renal tubular Na(+) and Ca(2+) handling in a gene-targeted mouse model was studied. NCC-deficient mice had significantly elevated plasma aldosterone levels and exhibited hypocalciuria, hypomagnesemia, and compensated alkalosis. Immunofluorescent detection of distal tubule marker proteins and ultrastructural analysis revealed that the early DCT, which physiologically lacks epithelial Na(+) (ENaC) and Ca(2+) (TRPV5) channels, was virtually absent in NCC-deficient mice. In contrast, the late DCT seemed intact and retained expression of the apical ENaC and TRPV5 as well as basolateral Na(+)-Ca(2+) exchanger. The connecting tubule exhibited a marked epithelial hypertrophy accompanied by an increased apical abundance of ENaC. Ca(2+) reabsorption seemed unaltered in the distal convolution (i.e., the DCT and connecting tubule) as indicated by real-time reverse transcription-PCR, Western blotting, and immunohistochemistry for TRPV5 and Na(+)-Ca(2+) exchanger and micropuncture experiments. The last experiments further indicated that reduced glomerular filtration and enhanced fractional reabsorption of Na(+) and Ca(2+) upstream and of Na(+) downstream of the DCT provide some compensation for the Na(+) transport defect in the DCT and contribute to the hypocalciuria. Thus, loss of NCC leads to major structural remodeling of the renal distal tubule that goes along with marked changes in glomerular and tubular function, which may explain some of the clinical features of Gitelman's syndrome.

Role of PEPT2 in the Choroid Plexus Uptake of Glycylsarcosine and 5-Aminolevulinic Acid: Studies in Wild-Type and Null Mice

PURPOSE

To determine the importance of PEPT2 in the uptake of glycylsarcosine (GlySar) and 5-aminolevulinic acid (5-ALA) in mouse choroid plexus whole tissue.

METHODS

Uptake studies were performed in bicarbonate artificial cerebrospinal fluid buffer using choroid plexuses isolated from PEPT2+/+ and PEPT2-/- mice. [14C]GlySar and [14C]5-ALA were studied as a function of temperature, concentration, potential inhibitors, and low sodium conditions.

RESULTS

PEPT2-/- mice exhibited a 90% reduction in GlySar uptake (p < 0.001) and a 92% reduction in 5-ALA uptake (p < 0.001) as compared to wild type animals. At 4 degrees C (vs. 37 degrees C), GlySar uptake was reduced by 95% in PEPT2+/+ mice; no difference was observed in null animals. Unlabeled GlySar inhibited the uptake of [14C]GlySar in PEPT2+/+ mice (p < 0.01); self-inhibition did not occur in PEPT2-/- mice. GlySar demonstrated saturable uptake in PEPT2+/+ mice (Vmax = 16.4 pmol mg(-1) min(-1), Km = 70 microM, Kd = 0.014 microl mg(-1) min(-1)), however, uptake was linear in PEPT2-/- mice (Kd = 0.023 microl mg(-1) min(-1)). Low sodium buffer (1 mM) resulted in 75% and 59% reductions, respectively, in GlySar (p < 0.001) and 5-ALA (p < 0.01) uptake in PEPT2+/+ mice; no differences were observed in PEPT2-/- mice. Overall, about 90-95% of the choroid plexus uptake of GlySar and 5-ALA was mediated by PEPT2, with about 5-10% of the residual uptake occurring by nonspecific mechanisms.

CONCLUSIONS

The results demonstrate that PEPT2 is the only transporter responsible for the choroid plexus uptake of GlySar and 5-ALA. They also suggest a role for PEPT2 in the clearance of dipeptides and endogenous peptidomimetics from cerebrospinal fluid.

Intestinal Na-Pi cotransporter adaptation to dietary Pi content in vitamin D receptor null mice

Recent studies suggest that vitamin D may play a role in intestinal Na+-dependent phosphate transport adaptation to variable levels of dietary Pi. Therefore, the goal of the current study was to assess Na+-dependent Pi cotransport activity in transgenic mice to determine whether vitamin D is an essential mediator of this process. Intestinal brush-border membrane (BBM), Na+-dependent Pi cotransport activity was significantly decreased in vitamin D receptor (VDR) null [VDR (−/−)] mice compared with wild-type (VDR+/+) mice. While intestinal Na-Pi cotransporter (type IIb) mRNA levels were similar in VDR (−/−) and VDR (+/+) mice, type IIb Na-Pi cotransporter protein expression was markedly suppressed in VDR (−/−) mice compared with VDR (+/+) mice. Furthermore, Na-Pi cotransport activity in renal BBM was similar in VDR (−/−) and VDR (+/+) mice, but type IIa Na-Pi cotransporter protein expression was decreased in VDR (−/−) mice. After administration of a low-Pi diet, type IIb protein expression was significantly increased in VDR (+/+) and VDR (−/−) mice, and type IIb protein expression was present in the intestinal BBM of VDR (−/−) mice. These data demonstrate that intestinal Na-Pi cotransport adaptation to a low-Pi diet occurs independently of vitamin D.

Pharmacological characterization of human excitatory amino acid transporters EAAT1, EAAT2 and EAAT3 in a fluorescence-based membrane potential assay

We have expressed the human excitatory amino acid transporters EAAT1, EAAT2 and EAAT3 stably in HEK293 cells and characterized the transporters pharmacologically in a conventional [(3) H]-d-aspartate uptake assay and in a fluorescence-based membrane potential assay, the FLIPR Membrane Potential (FMP) assay. The K(m) and K(i) values obtained for 12 standard EAAT ligands at EAAT1, EAAT2 and EAAT3 in the FMP assay correlated well with the K(i) values obtained in the [(3) H]-d-aspartate assay (r(2) values of 0.92, 0.92, and 0.95, respectively). Furthermore, the pharmacological characteristics of the cell lines in the FMP assay were in good agreement with previous findings in electrophysiology studies of the transporters. The FMP assay was capable of distinguishing between substrates and non-substrate inhibitors and to discriminate between "full" and "partial" substrates at the transporters. Taking advantage of the prolific nature of the FMP assay, interactions of the EAATs with substrates and inhibitors were studied in some detail. This is the first report of a high throughput screening assay for EAATs. We propose that the assay will be of great use in future studies of the transporters. Although conventional electrophysiology set-ups might be superior in terms of studying sophisticated kinetic aspects of the uptake process, the FMP assay enables the collection of considerable amounts of highly reproducible data with relatively little labor. Furthermore, considering that the number of EAAT ligands presently available is limited, and that almost all of these are characterized by low potency and a low degree of subtype selectivity, future screening of compound libraries at the EAAT-cell lines in the FMP assay could help identify structurally and pharmacologically novel ligands for the transporters.

Association of excitatory amino acid transporters, especially EAAT2, with cholesterol-rich lipid raft microdomains: importance for excitatory amino acid transporter localization and function

In the present study, we investigated the role of membrane cholesterol in the function of glutamate transporters. Depletion of membrane cholesterol by methyl-beta-cyclodextrin resulted in reduced Na(+)-dependent glutamate uptake in primary cortical cultures. Glial glutamate transporter EAAT2-mediated uptake was more sensitive to this effect. Cell surface biotinylation and immunostaining experiments revealed that the loss of cholesterol significantly altered the trafficking of EAAT2 to the plasma membrane as well as their membrane distribution. These effects were also observed in neuronal glutamate transporter EAAT3 but to a lesser extent. Furthermore, the treatment of mouse brain plasma membrane vesicles with methyl-beta-cyclodextrin resulted in a significant reduction in glutamate uptake, suggesting that cholesterol depletion has a direct effect on the function of the glutamate transporters. Plasma membrane cholesterol is localized within discreet microdomains known as lipid rafts. Analyses of purified lipid raft microdomains revealed that a large portion of total EAAT2 and a minor portion of total EAAT1, EAAT3, and EAAT4 were associated with lipid rafts. Artificial aggregation of lipid rafts in vivo resulted in the formation of larger EAAT2-immunoreactive clusters on the cell surface. The purified lipid raft-associated fractions were capable of Na(+)-dependent glutamate uptake. Our data suggest that the glutamate transporters, especially EAAT2, are associated with cholesterol-rich lipid raft microdomains of the plasma membrane and that the association with these cholesterol-rich microdomains is important for excitatory amino acid transporter localization and function.

[New insights on plasma phosphate and calcium control]

The physiological regulation of renal Pi reabsorption is mediated by renal type II Na/Pi cotransporters. The type II a transporter is a key player of renal Pi reabsorption and regulated, among other factors, by parathyroid hormone (PTH). The PTH-induced inhibition of Pi reabsorption is mediated by endocytosis of the type II a transporter from the brush-border membrane and subsequent lysosomal degradation. In addition, during weaning, the type II c Na/Pi cotransporter (growth related Na/Pi cotransporter) is induced in the apical membrane of proximal tubular cells. The type II c transporter is also regulated by PTH, FGF-23 and PHEX. Studying the mechanisms of the regulation of type II c transporters by PHEX and FGF-23 has increased understanding of the control of proximal tubular Pi handling and bone mineralization.

[Mechanism of vascular calcification]

Vascular calcification in dialysis patients is associated with morbidity and mortality risks. Recent evidence suggests that vascular calcification is an active process resembling osteogenesis and chondrogenesis process. In this process, hyperphosphatemia is one of the important regulators. Inorganic phosphates directly regulate vascular calcification in vitro through a sodium-dependent phosphate cotransporter and promote expression of the osteoblastic differentiation markers.

Perinatal cocaine exposure reduces myocardial norepinephrine transporter function in the neonatal rat

Norepinephrine transporter (NET) mediates the active removal of norepinephrine (NE) released from sympathetic nerve terminals via reuptake, and NET function and expression can be regulated by cocaine. NET expression and its regulation by cocaine in the developing sympathetic nervous system during early postnatal period, however, have not been examined. We quantified immunodetectable NET protein expression in the neonatal rat heart to examine the developmental pattern of myocardial NET during the first 2 weeks after birth. To assess sympathetic innervations, we simultaneously quantified the expression of myocardial tyrosine hydroxylase (TH). Timed pregnant rats received daily intragastric treatment with saline (CTL) or cocaine at 60 mg/kg (Coc) from Gestational Day 2 until parturition. After birth, nursing mothers continued to receive the same treatment. The expression of myocardial TH and NET in neonatal rats were then studied at 1 day (Postnatal Day 1, PD1), 7 days (PD7) or 14 days (PD14) of age. We observed a similar age-dependent increase in the expression for myocardial NET and TH during the first 2 weeks of postnatal life, in both CTL and Coc animals. While myocardial TH was significantly up-regulated following perinatal cocaine exposure, no significant change in immunodetectable myocardial NET protein was evident. To further examine whether NET function might be affected by perinatal cocaine exposure, we performed NE uptake in myocardial membranes from PD14 CTL and Coc rats. We found that NE uptake was reduced at PD14 in the cocaine-treated group. Our results indicate that myocardial NET and TH are both developmentally regulated. Furthermore, our results indicate that perinatal exposure to cocaine did not change NET protein expression but impaired myocardial NET function in the neonatal rat.

Peptide transporters: structure, function, regulation and application for drug delivery

Proton-coupled peptide transporters, localized at brush-border membranes of intestinal and renal epithelial cells, play important roles in protein absorption and the conservation of peptide-bound amino nitrogen. These transporters also have significant pharmacological and pharmacokinetic relevance to the transport of various peptide-like drugs such as beta-lactam antibiotics. The identification and molecular characterization of H(+)/peptide cotransporters (PEPT1 and PEPT2) have facilitated the clarification of many aspects of these transporters such as the structure/function relationship and regulation. Recent findings that intestinal PEPT1 can transport l-valine ester prodrugs such as valacyclovir provided a major step forward toward the development of novel drug delivery systems. It has been demonstrated that peptide transporters, which have a similar substrate specificity to PEPT1 and PEPT2, but possess other distinct functional properties, are localized at basolateral membranes of intestinal and renal epithelial cells. This review highlights the recent advances in our knowledge of the cellular and molecular nature of PEPT1, PEPT2 and the basolateral peptide transporters.

Stimulation of differentiation in sodium-dependent vitamin C transporter 2 overexpressing MC3T3-E1 osteoblasts

Sodium-dependent vitamin C transporter (SVCT) 2 facilitates reduced ascorbic acid (AA) transport in MC3T3-E1 osteoblasts. Our previous studies suggested that Zn-induced osteoblast differentiation and Ca2+-, PO4(3-)-stimulated osteopontin (OPN) expression might result from their up-regulation effect on SVCT2 expression and AA uptake. Here, we investigated the role of SVCT2 on osteoblast differentiation by using SVCT2-overexpressing cells. Two clones of SVCT2-introduced cells overexpressed SVCT2 mRNA by 2.8- and 3.1-fold those of control cells, which resulted in obvious increase of AA uptake by 2.1- and 2.4-fold in Vmax with no change in Km. Alkaline phosphatase activity, hydroxyproline content significantly increased in SVCT2-overexpressing cells, and the induction of OPN mRNA was through up-regulation of OPN promoter activity by SVCT2 overexpression. Moreover, SVCT2-overexpressing cells exhibited more ability to promote mineralization and increase calcium deposition under the stimulation of 5 mM beta-glycerophosphate. These findings indicate that SVCT2 stimulates osteoblast differentiation and mineralization.

Ontogenetic development of rat intestinal bile acid transport requires thyroxine but not corticosterone

Absorption of bile acids by the distal ileum is an essential component of the enterohepatic circulation. In neonatal rats, the appearance of the apical sodium-dependent bile acid transporter (ASBT) at 17 d of age coincides with increases in serum corticosterone and thyroxine. We tested the hypothesis that these hormones modulate ASBT expression during ileal development. Taurocholate uptake into the isolated ileum of normal 20-d-old pups exhibited saturable (K(m) = 0.52 mM, J(max) = 0.34 pmol mg/min) and nonsaturable (K(diff) = 0.015 min(-1)) components and was two to five times greater than uptake in the proximal intestine. Hypothyroid or euthyroid pups received daily thyroxine injections starting at 6 d of age. At 12 d of age, serum concentrations of thyroxine, ileal abundance of ASBT mRNA, and ileal rates of taurocholate uptake were low in hypothyroid pups that received an injection of vehicle (HT-) or thyroxine (HT+) and in euthyroid pups that received an injection of vehicle (ET-) or thyroxine (ET+). At 20 and 26 d, ileal ASBT mRNA abundance and taurocholate uptake rate remained low in HT- pups but increased dramatically in ET- and ET+ pups, paralleling the increase in serum thyroxine. Restoration of normal plasma thyroxine in HT- pups by thyroxine injections (HT+) restored normal ASBT development. Sodium-glucose co-transporter activity and mRNA expression were independent of serum thyroxine levels. Corticosterone levels were significantly lower in pups that were adrenalectomized at 10 d of age. ASBT mRNA abundance and taurocholate uptake rate increased markedly with age but were the same in adrenalectomized, sham-operated, and nonoperated pups. Hence, endogenous thyroxine but not corticosterone regulates the developmentally timed appearance of ASBT.

Electrophysiological Characterization of the Human Na+/Nucleoside Cotransporter 1 (hCNT1) and Role of Adenosine on hCNT1 Function

We previously reported that the human Na(+)/nucleoside transporter pyrimidine-preferring 1 (hCNT1) is electrogenic and transports gemcitabine and 5'-deoxy-5-fluorouridine, a precursor of the active drug 5-fluorouracil. Nevertheless, a complete electrophysiological characterization of the basic properties of hCNT1-mediated translocation has not been performed yet, and the exact role of adenosine in hCNT1 function has not been addressed either. In the present work we have used the two-electrode voltage clamp technique to investigate hCNT1 transport mechanism and study the kinetic properties of adenosine as an inhibitor of hCNT1. We show that hCNT1 exhibits presteady-state currents that disappear upon the addition of adenosine or uridine. Adenosine, a purine nucleoside described as a substrate of the pyrimidine-preferring transporters, is not a substrate of hCNT1 but a high affinity blocker able to inhibit uridine-induced inward currents, the Na(+)-leak currents, and the presteady-state currents, with a K(i) of 6.5 microM. The kinetic parameters for uridine, gemcitabine, and 5'-deoxy-5-fluorouridine were studied as a function of membrane potential; at -50 mV, K(0.5) was 37, 18, and 245 microM, respectively, and remained voltage-independent. I(max) for gemcitabine was voltage-independent and accounts for approximately 40% that for uridine at -50 mV. Maximal current for 5'-DFUR was voltage-dependent and was approximately 150% that for uridine at all membrane potentials. K(0.5)(Na(+)) for Na(+) was voltage-independent at hyperpolarized membrane potentials (1.2 mM at -50 mV), whereas I(max)(Na(+)) was voltage-dependent, increasing 2-fold from -50 to -150 mV. Direct measurements of (3)H-nucleoside or (22)Na fluxes with the charge-associated revealed a ratio of two positive inward charges per nucleoside and one Na(+) per positive inward charge, suggesting a stoichiometry of two Na(+)/nucleoside.