Kidney Of Winter Flounder Research Articles

Regulation of sodium-dicarboxylate cotransporter-3 from winter flounder kidney by protein kinase C.

The sodium dicarboxylate cotransporter located at the basolateral side supplies renal proximal tubule cells with Krebs cycle intermediates and maintains the driving force for the exchange of organic anions like PAH against alpha-ketoglutarate through the organic anion transporter-1. Recently, we cloned sodium dicarboxylate cotransporter-3 from winter flounder kidney (fNaDC-3). To understand the regulation of fNaDC-3, we preincubated fNaDC-3-expressing oocytes with PMA, a PKC activator. PMA dose and time dependently inhibited fNaDC-3-mediated succinate uptake. Simultaneous preincubation of fNaDC-3-expressing oocytes with 50 nM PMA and either staurosporine or RO 31-8220 for 30 min attenuated PKC-mediated inhibition of succinate uptake. Site-directed mutagenesis of the five putative PKC sites (S7, T167, S174, T188, and S396) resulted in no change in PKC-mediated inhibition of the transporter. In electrophysiological studies performed at -60 mV, the K0.5 for succinate was not significantly affected (56 +/- 13 vs. 42 +/- 19 microM), but DeltaImax was reduced from -139 +/- 49 to -20 +/- 8 nA by PMA (50 nM, 30 min). Immunofluorescence analysis of fNaDC-3-expressing oocytes revealed that PMA leads to an endocytosis of fNaDC-3 protein. In conclusion, fNaDC-3 expressed in oocytes is downregulated by PMA through endocytosis. PKC consensus sites appear not to be important for this process.

The renal Na(+)-dependent dicarboxylate transporter, NaDC-3, translocates dimethyl- and disulfhydryl-compounds and contributes to renal heavy metal detoxification.

The active transport of Krebs cycle intermediates, such as succinate, alpha-ketoglutarate, and citrate, is mediated by sodium-coupled transporters found in the luminal (NaDC-1) and basolateral plasma membranes (NaDC-3) of proximal tubule cells. This study used the two-electrode voltage clamp technique to examine steady-state currents associated with the influx of three sodium ions and one divalent dicarboxylate into oocytes expressing the sodium-dicarboxylate transporter from winter flounder kidney, fNaDC-3. The substrate concentration, where half-maximal current was observed (K(0.5)), was 30 micro M for succinate. Besides 2,2-dimethylsuccinate, fNaDC-3 also accepted 2,3-dimethylsuccinate and the oral lead-chelating agent, meso-2,3-dimercaptosuccinate (DMSA or Succimer). Whereas the K(0.5) for succinate and 2,2-dimethylsuccinate was independent of membrane voltage within -90 and -10 mV, K(0.5) for 2,3-dimethylsuccinate and 2,3-dimercaptosuccinate increased with decreasing voltage, indicating a critical role of the position of the methyl- or sulfhydryl-group in voltage-sensitive affinity. In addition to meso-2,3-dimercaptosuccinate, fNaDC-3 translocated dimercaptopropane-1-sulfonate (DMPS or Dimaval), an oral chelator for the treatment of mercury intoxication. The chelates formed by HgCl(2) and DMSA or DMPS and by Pb(NO(3))(2) and DMSA, however, were not translocated by fNaDC-3. The data suggest that NaDC-3 is an essential component in the delivery of uncomplexed antidotes for renal heavy metal detoxification.

Potential-dependent steady-state kinetics of a dicarboxylate transporter cloned from winter flounder kidney.

The two-electrode voltage-clamp technique in combination with tracer uptake experiments was used to investigate the dependence of dicarboxylate transport kinetics on membrane potential in Xenopus laevis oocytes expressing the flounder renal high-affinity-type sodium dicarboxylate cotransporter (fNaDC-3). Steady-state succinate-dependent currents in the presence of Na+ were saturable with an apparent affinity constant for succinate, K0.5,succ, of 60 microM. K0.5,succ was independent of membrane potential, suggesting succinate binding at the surface of the fNaDC-3 protein. The maximal succinate-dependent current, deltaImax, increased with hyperpolarization, suggesting that the empty carrier may translocate net charge. Succinate-induced currents showed sigmoidal dependence on Na+ concentration, and K0.5,Na+ decreased with hyperpolarization, suggesting Na+ binding in an ion well. Lowering the external Na+ concentration to 20 mM increased K0.5,succ approximately threefold. Succinate-induced currents were inhibited by Li+ with an Ki,Li+ of approximately 0.5 mM, and a Hill coefficient of below unity indicating the interaction of one Li+ ion with an inhibitory site at fNaDC-3.

Expression Cloning and Characterization of a Novel Sodium-Dicarboxylate Cotransporter from Winter Flounder Kidney

A cDNA coding for a Na+-dicarboxylate cotransporter, fNaDC-3, from winter flounder (Pseudopleuronectes americanus) kidney was isolated by functional expression in Xenopus laevis oocytes. The fNaDC-3 cDNA is 2384 nucleotides long and encodes a protein of 601 amino acids with a calculated molecular mass of 66.4 kDa. Secondary structure analysis predicts at least eight membrane-spanning domains. Transport of succinate by fNaDC-3 was sodium-dependent, could be inhibited by lithium, and evoked an inward current. The apparent affinity constant (Km) of fNaDC-3 for succinate of 30 microM resembles that of Na+-dicarboxylate transport in the basolateral membrane of mammalian renal proximal tubules. The substrates specific for the basolateral transporter, 2,3-dimethylsuccinate and cis-aconitate, not only inhibited succinate uptake but also evoked inward currents, proving that they are transported by fNaDC-3. Succinate transport via fNaDC-3 decreased by lowering pH, as did citrate transport, although much more moderately. These characteristics suggest that fNaDC-3 is a new type of Na+-dicarboxylate transporter that most likely corresponds to the Na+-dicarboxylate cotransporter in the basolateral membrane of mammalian renal proximal tubules.

Na-P(i) cotransport sites in proximal tubule and collecting tubule of winter flounder (Pleuronectes americanus).

Localization of a recently described and cloned Na-Pi cotransport system from flounder was investigated by reverse transcription-polymerase chain reaction (RT-PCR) of microdissected tubules and by immunocytochemistry of kidney of winter flounder. Histological examination showed a small glomerulus, an extremely short proximal tubule PI with a selective affinity to Lens culinaris agglutinin from lentils, and an extensive second proximal tubule segment PII (> 90% of proximal tubules), consisting of cells with numerous apical clear vesicles and extensive amplification of basolateral cell membranes. PII merged with the collecting tubule/ collecting duct (CT/CD) system without a distal segment. By RT-PCR, PII cells revealed high levels of NaPi-II related RNA; low levels were also observed in CTs. Previously characterized antisera against different epitopes of flounder NaPi-II specifically labeled the basolateral regions of PII and the apical cell portion of CT/CD cells and of some PII cells. These results suggest that tubular secretion of P(i) occurs in PII of teleost fish with modulation of urinary P(i) content in the subsequent CT/CD system.

Electrophysiological characterization of the flounder type II Na+/Pi cotransporter (NaPi-5) expressed in Xenopus laevis oocytes.

The two electrode voltage clamp technique was used to investigate the steady-state and presteady-state kinetic properties of the type II Na+/Pi cotransporter NaPi-5, cloned from the kidney of winter flounder (Pseudopleuronectes americanus) and expressed in Xenopus laevis oocytes. Steady-state Pi-induced currents had a voltage-independent apparent K(m) for Pi of 0.03 mM and a Hill coefficient of 1.0 at neutral pH, when superfusing with 96 mM Na+. The apparent K(m) for Na+ at 1 mM Pi was strongly voltage dependent (increasing from 32 mM at -70 mV to 77 mM at -30 mV) and the Hill coefficient was between 1 and 2, indicating cooperative binding of more than one Na+ ion. The maximum steady-state current was pH dependent, diminishing by 50% or more for a change from pH 7.8 to pH 6.3. Voltage jumps elicited presteady-state relaxations in the presence of 96 mM Na+ which were suppressed at saturating Pi (1 mM). Relaxations were absent in non-injected oocytes. Charge was balanced for equal positive and negative steps, saturated at extremes of potential and reversed at the holding potential. Fitting the charge transfer to a Boltzmann relationship typically gave a midpoint voltage (V0.5) close to zero and an apparent valency of approximately 0.6. The maximum steady-state transport rate correlated linearly with the maximum Pi-suppressed charge movement, indicating that the relaxations were NaPi-5-specific. The apparent transporter turnover was estimated as 35 sec-1. The voltage dependence of the relaxations was Pi-independent, whereas changes in Na+ shifted V0.5 to -60 mV at 25 mM Na+. Protons suppressed relaxations but contributed to no detectable charge movement in zero external Na+. The voltage dependent presteady-state behavior of NaPi-5 could be described by a 3 state model in which the partial reactions involving reorientation of the unloaded carrier and binding of Na+ contribute to transmembrane charge movement.

Cloning and expression of a renal Na-Pi cotransport system from flounder.

Starting with the recently published sequence of the rat renal Na-Pi cotransport system, we have cloned a corresponding cDNA from the kidney of winter flounder (Pseudopleuronectes americanus), designated flounder NaPi-II. Expression of the cognate in vitro transcribed RNA in Xenopus laevis oocytes stimulated Na-dependent Pi transport specifically and in a time- and dose-dependent manner. Apparent affinities of Na and Pi, as well as the pH dependency, were very similar to those found for the mammalian systems. The flounder NaPi-II cDNA is 2,424 base pairs long and encodes a protein of 637 amino acids. The hydropathy plot predicts eight transmembrane spanning domains. In these regions the flounder NaPi-II-deduced protein shows high homology (approximately 80%, identity, approximately 92% similarity) with the amino acid sequences reported for mammalian NaPi-II proteins. However, in the hydrophilic parts of flounder NaPi-II protein, only minimal similarity could be found between fish and mammalian systems (30% homology, 45% similarity). Northern blot analysis with flounder NaPi-II cDNA as a probe confirmed this finding: even under nonstringent washing conditions, no cross-hybridization with mRNA from rat renal cortex was observed. Interestingly, flounder intestine was found to contain high levels of mRNA corresponding to NaPi-II. Supplementary bands of 1.9 and 4.2 kb were observed on Northern blots of renal and intestinal tissue. The close functional relationship of the flounder NaPi-II protein with the previously described Na-Pi cotransport systems and the pronounced differences on the level of their primary structures provide the tools for detailed structure-function analysis of Na-Pi cotransport.

Molecular cloning of metallothionein cDNA and analysis of metallothionein gene expression in winter flounder tissues

Investigations into the precise role played by metallothionein (MT) in heavy-metal metabolism have been hampered by difficulties in positively identifying and quantifying MT in fish tissues. This study describes the development of an antisense MT RNA (cRNA) probe that will enable MT mRNA levels to be measured with a high degree of specificity and precision. Cadmium chloride administration induces the producton of MT mRNA in the liver and kidney of winter flounder (Pseudopleuronectes americanus). Poly(A)+ RNA purified from liver samples of winter flounder after cadmium chloride injections was used to construct a cDNA library. Several recombinant clones made complementary to MT mRNA were selected from this cDNA library by an oligonucleotide derived from the N-terminal amino acid sequence of winter flounder metallothionein. Sequence analysis of two of the cDNA inserts gave the structure of the entire 3′ untranslated region, a coding region corresponding to winter flounder MT and 49 nucleotides of the 5′ untranslated region. One of the flounder MT cDNAs, pWFMTC4, was subcloned into a RNA probe plasmid and transcribed to produce antisense MT RNA (cRNA). The MT cRNA was then used to detect the induction of MT mRNA production in the liver of winter flounder, following the administration of Cu2+, Zn2+, Cd2+, Pb2+, and Hg2+. The time required for the induction of hepatic MT mRNA by a single injection of Cd2+ was approximately 96 h. Dexamethasone did not induce an increase of MT mRNA in any of the winter flounder tissues examined (liver, kidney, heart, brain, intestinal scrape, and gill filament), whereas Cd2+ induced MT mRNA in all of the tissues except brain, where the constitutive level of expression was high.