Expression of the sodium iodide symporter in human kidney.
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BACKGROUND: The human sodium iodide symporter (hNIS) is a transmembrane protein that mediates the active transport of iodide in the thyroid gland. Following cloning of NIS, NIS expression has been detected in a broad range of nonthyroidal tissues, suggesting that iodide transport in these tissues is conferred by the expression of functional NIS protein. METHODS: The aim of this study was to examine functional hNIS expression in kidney by reverse transcription-polymerase chain reaction (RT-PCR), ribonuclease protection assay (RPA), immunohistochemistry, and Western blot analysis accompanied by iodide accumulation studies in kidney cells. RESULTS: Using a pair of full-length hNIS-specific oligonucleotide primers, RT-PCR followed by Southern hybridization revealed hNIS mRNA expression in normal human kidney tissue. The PCR products were subjected to automated sequencing and revealed full identity with the published human thyroid-derived NIS cDNA sequence. Furthermore, positive protected bands indicating the presence of hNIS mRNA were apparent in RPA gel lanes corresponding to human kidney cells as well as Chinese hamster ovary (CHO) cells stably transfected with hNIS cDNA and Graves' thyroid tissue. Immunohistochemical analysis of normal human kidney tissue using a mouse monoclonal hNIS-specific antibody showed marked hNIS-specific immunoreactivity confined to tubular cells, while no hNIS-specific immunoreactivity was detected in the glomeruli. NIS protein expression in human kidney cells was further confirmed by Western blot analysis. In addition, accumulation of (125)I was detected in human kidney cells in vitro and was shown to be sodium dependent and sensitive to perchlorate. CONCLUSIONS: Functional hNIS expression was demonstrated in the renal tubular system, suggesting that renal iodide transport may be, at least in part, an active process driven by NIS. (+info)
Iodide and bromide inhibit Ca(2+) uptake by cardiac sarcoplasmic reticulum.
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Recent studies indicate that the Ca(2+) permeability of the sarcoplasmic reticulum (SR) can be affected by its anionic environment. Additionally, anions could directly modulate the SR Ca(2+) pump or the movement of compensatory charge across the SR membrane during Ca(2+) uptake or release. To examine the effect of anion substitution on cardiac SR Ca(2+) uptake, fluorometric Ca(2+) measurements and spectrophotometric ATPase assays were used. Ca(2+) uptake into SR vesicles was inhibited in a concentration-dependent manner when Br(-) or I(-) replaced extravesicular Cl(-) (when Br(-) completely replaced Cl(-), uptake velocity was approximately 70% of control; when I(-) completely replaced Cl(-), uptake velocity was approximately 39% of control). Replacement of Cl(-) with SO(2)(-4) had no effect on SR uptake. Although both I(-) and Br(-) inhibited net Ca(2+) uptake, neither anion directly inhibited the SR Ca(2+) pump nor did they increase the permeability of the SR membrane to Ca(2+). Our results support the hypothesis that an anionic current that occurs during SR Ca(2+) uptake is reduced by the substitution of Br(-) or I(-) for Cl(-). (+info)
Na(+)/I(-) symporter and Pendred syndrome gene and protein expressions in human extra-thyroidal tissues.
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OBJECTIVE: The expression of two recently identified iodide transporters, namely the sodium/iodide symporter (NIS) and pendrin, the product of the gene responsible for the Pendred syndrome (PDS), was studied in a series of various extra-thyroidal human tissues, and especially in those known to concentrate iodide. METHODS: To this end, we used real-time kinetic quantitative PCR to detect NIS and PDS transcripts and immunohistochemistry for the analysis of their protein products. RESULTS: NIS gene and protein expression was detected in most tissues known to concentrate iodine, and particularly in salivary glands and stomach. In contrast, PDS gene expression was restricted to a few tissues, such as kidney and Sertoli cells. Interestingly, in kidney, pendrin immunostaining was detected at the apical pole of epithelial cells of the thick ascending limb of the Henle's loop and of the distal convoluted tubule. CONCLUSION: This study provides new insights on the localization and expression of two genes involved in iodide transport and emphasizes the interest of combining real-time quantitative PCR and immunohistochemistry for the comparison of gene and protein expression in tissues. (+info)
Cobalt stimulation of heme degradation in the liver. Dissociation of microsomal oxidation of heme from cytochrome P-450.
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The administration of cobalt to rats caused a marked increase in the oxidative degradation of heme (hematin, iron protoporphyrin-IX) BY HEPATIC MICROSOMAL ENZYMES. The onset of this enzyme stimulation was very rapid, beginning within 2 hours after injection of the metal and reaching its maximum in 16 to 24 hours. During the rapid phase of stimulation, i.e. the first 2 to 4 hours, when heme oxidation was 450% above control values, there was a significant decrease in microsomal oxidative N-demethylation activity and in microsomal oxidative Ndemethylation activity and in microsomal content of heme with an insignificant decrease in cytochrome P-450 content. Within 24 hours the oxidative activity of the microsomal electron transport chain for drugs was decreased to about 30% of the control. However, during the same period the oxidation of heme approached levels 800% above control. During this period there was a further decrease in the microsomal content of heme with a significant decrease in cytochrome P-450 content and an increase in the activity of delta-aminolevulinate synthetase. The activity of delta-aminolevulinate synthetase reached its maximum within 8 hours after cobalt treatment. Repeated injections (at 24-hour intervals) of cobalt were necessary to maintain these changes in microsomal enzyme activities since, after single injections of the metal, these parameters returned to normal within 72 hours. The inducing effect of cobalt on the oxidation of heme could be inhibited by the administration of actinomycin D and puromycin. Furthermore, this stimulatory effect could not be elicited by in vitro treatment of microsomes with cobalt nor could the effect be attributed to any soluble components of the cytoplasm. Cobalt protoporphyrin-IX was less effective than cobalt chloride in stimulating heme oxidation. 3-Amino-1, 2, 4-triazole did not enhance hepatic heme oxidation activity, while allylisopropylacetamide decreased this activity. The oxidative degradation of heme was found not to be cytochrome P-450 dependent since the highly increased levels of heme oxidation in microsomes from cobalt-treated animals could be retained despite the fact that the cytochrome P-450 content of such microsomes was decreased to spectrally undetectable amounts and drug oxidation was eliminated by treatment of the microsomes with 4 M urea. These findings exclude an obligatory role for cytochrome P-450 in the oxidation of heme compounds, although the possibility that this process is a heme-dependent oxidation is not ruled out. (+info)
Roles of water in heme peroxidase and catalase mechanisms.
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A water molecule is coproduced with the Compound I intermediate in the reactions of native heme peroxidases and catalases with hydrogen peroxide. As a result of water release/rebinding from/to the coproduct formation site the Compound I intermediate may exist in two forms: a "wet" form, Compound I(H(2)O), in which a water molecule is present at or near the site of coproduct water formation, and Compound I, in which the coproduct water formation site is "dry." It is postulated that the absence or presence of a water molecule at this site provides the structural basis for a redox pathway switching mechanism, such that the transition states for 2-electron equivalent reduction of Compound I intermediates are accessible in the dry form, but that in the wet form only 1-electron equivalent processes are possible, unless release of water can be stimulated. This concept provides the basis of a general mechanism in which the classical functional distinction between catalases and peroxidases, as well as the more complex behavior observed in halide oxidation and halogenation reactions, appear as particular cases in which variations in the degree of retention of water at the coproduct formation site influence Compound I reactivity. (+info)
Post-transcriptional regulation of the sodium/iodide symporter by thyrotropin.
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The Na(+)/I(-) symporter (NIS) is a key plasma membrane glycoprotein that mediates active I(-) transport in the thyroid gland (Dai, G., Levy, O., and Carrasco, N. (1996) Nature 379, 458-460), the first step in thyroid hormone biogenesis. Whereas relatively little is known about the mechanisms by which thyrotropin (TSH), the main hormonal regulator of thyroid function, regulates NIS activity, post-transcriptional events have been suggested to play a role (Kaminsky, S. M., Levy, O., Salvador, C., Dai, G., and Carrasco, N. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 3789-3793). Here we show that TSH induces de novo NIS biosynthesis and modulates the long NIS half-life ( approximately 5 days). In addition, we demonstrate that TSH is required for NIS targeting to or retention in the plasma membrane. We further show that NIS is a phosphoprotein and that TSH modulates its phosphorylation pattern. These results provide strong evidence of the major role played by post-transcriptional events in the regulation of NIS by TSH. Beyond their inherent interest, it is also of medical significance that these TSH-dependent regulatory mechanisms may be altered in the large proportion of thyroid cancers in which NIS is predominantly expressed in intracellular compartments, instead of being properly targeted to the plasma membrane. (+info)
P2Y(11), a purinergic receptor acting via cAMP, mediates secretion by pancreatic duct epithelial cells.
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Pancreatic duct epithelial cells (PDEC) mediate the exocrine secretion of fluid and electrolytes. We previously reported that ATP and UTP interact with P2Y(2) receptors on nontransformed canine PDEC to increase intracellular free Ca2+ concentration ([Ca2+](i)) and stimulate Ca2+-activated Cl- and K+ channels. We now report that ATP interacts with additional purinergic receptors to increase cAMP and activate Cl- channels. ATP, 2-methylthio-ATP, and ATP-gamma-S stimulated a 4- to 10-fold cAMP increase with EC(50) of 10-100 microM. Neither UTP nor adenosine stimulated a cAMP increase, excluding a role for P2Y(2) or P1 receptors. Although UTP stimulated an (125)I(-) efflux that was fully inhibited by 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid tetra(acetoxymethyl) ester (BAPTA-AM), ATP stimulated a partially resistant efflux, suggesting activation of additional Cl- conductances through P2Y(2)-independent and Ca2+-independent pathways. In Ussing chambers, increased cAMP stimulated a much larger short-circuit current (I(sc)) increase from basolaterally permeabilized PDEC monolayers than increased [Ca2+](i). Luminal ATP and UTP and serosal UTP stimulated a small Ca2+-type I(sc) increase, whereas serosal ATP stimulated a large cAMP-type I(sc) response. Serosal ATP effect was inhibited by P2 receptor blockers and unaffected by BAPTA-AM, supporting ATP activation of Cl- conductances through P2 receptors and a Ca2+-independent pathway. RT-PCR confirmed the presence of P2Y(11) receptor mRNA, the only P2Y receptor acting via cAMP. (+info)
New technologies to prevent intravascular catheter-related bloodstream infections.
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Most intravascular catheter-related infections are associated with central venous catheters. Technologic advances shown to reduce the risk for these infections include a catheter hub containing an iodinated alcohol solution, short-term chlorhexidine-silver sulfadiazine- impregnated catheters, minocycline-rifampin-impregnated catheters, and chlorhexidine- impregnated sponge dressings. Nontechnologic strategies for reducing risk include maximal barrier precautions during catheter insertion, specialized nursing teams, continuing quality improvement programs, and tunneling of short-term internal jugular catheters. (+info)