Physiological regulation of phosphate by vitamin D, parathyroid hormone (PTH) and phosphate (Pi).

Inorganic phosphate (Pi) is an abundant element in the body and is essential for a wide variety of key biological processes. It plays an essential role in cellular energy metabolism and cell signalling, e.g. adenosine and guanosine triphosphates (ATP, GTP), and in the composition of phospholipid membranes and bone, and is an integral part of DNA and RNA. It is an important buffer in blood and urine and contributes to normal acid-base balance. Given its widespread role in almost every molecular and cellular function, changes in serum Pi levels and balance can have important and untoward effects. Pi homoeostasis is maintained by a counterbalance between dietary Pi absorption by the gut, mobilisation from bone and renal excretion. Approximately 85% of total body Pi is present in bone and only 1% is present as free Pi in extracellular fluids. In humans, extracellular concentrations of inorganic Pi vary between 0.8 and 1.2 mM, and in plasma or serum Pi exists in both its monovalent and divalent forms (H2PO4- and HPO42-). In the intestine, approximately 30% of Pi absorption is vitamin D regulated and dependent. To help maintain Pi balance, reabsorption of filtered Pi along the renal proximal tubule (PT) is via the NaPi-IIa and NaPi-IIc Na+-coupled Pi cotransporters, with a smaller contribution from the PiT-2 transporters. Endocrine factors, including, vitamin D and parathyroid hormone (PTH), as well as newer factors such as fibroblast growth factor (FGF)-23 and its coreceptor α-klotho, are intimately involved in the control of Pi homeostasis. A tight regulation of Pi is critical, since hyperphosphataemia is associated with increased cardiovascular morbidity in chronic kidney disease (CKD) and hypophosphataemia with rickets and growth retardation. This short review considers the control of Pi balance by vitamin D, PTH and Pi itself, with an emphasis on the insights gained from human genetic disorders and genetically modified mouse models.

The renal and blood pressure response to low sodium diet in P2X4 receptor knockout mice.

In the kidney, purinergic (P2) receptor-mediated ATP signaling has been shown to be an important local regulator of epithelial sodium transport. Appropriate sodium regulation is crucial for blood pressure (BP) control and disturbances in sodium balance can lead to hypo- or hypertension. Links have already been established between P2 receptor signaling and the development of hypertension, attributed mainly to vascular and/or inflammatory effects. A transgenic mouse model with deletion of the P2X4 receptor (P2X4-/- ) is known to have hypertension, which is thought to reflect endothelial dysfunction and impaired nitric oxide (NO) release. However, renal function in this model has not been characterized; moreover, studies in vitro have shown that the P2X4 receptor can regulate renal epithelial Na+ channel (ENaC) activity. Therefore, in the present study we investigated renal function and sodium handling in P2X4-/- mice, focusing on ENaC-mediated Na+ reabsorption. We confirmed an elevated BP in P2X4-/- mice compared with wild-type mice, but found that ENaC-mediated Na+ reabsorption is no different from wild-type and does not contribute to the raised BP observed in the knockout. However, when P2X4-/- mice were placed on a low sodium diet, BP normalized. Plasma aldosterone concentration tended to increase according to sodium restriction status in both genotypes; in contrast to wild-types, P2X4-/- mice did not show an increase in functional ENaC activity. Thus, although the increased BP in P2X4-/- mice has been attributed to endothelial dysfunction and impaired NO release, there is also a sodium-sensitive component.

Acute saccharin infusion has no effect on renal glucose handling in normal rats in vivo.

Artificial sweeteners are extensively used by the food industry to replace sugar in food and beverages and are widely considered to be a healthy alternative. However, recent data suggest that artificial sweeteners may impact intestinal glucose absorption and that they might lead to glucose intolerance. Moreover, chronic consumption of artificial sweeteners has also been linked to detrimental changes in renal function. Using an in vivo approach, our study aimed to determine if short-term infusion of the artificial sweetener saccharin can alter renal function and renal glucose absorption. We show that saccharin infusion does not induce any major change in GFR or urine flow rate at either the whole kidney or single nephron level, suggesting that any reported change in renal function with artificial sweeteners must depend on chronic consumption. As expected for a nondiabetic animal, glucose excretion was low; however, saccharin infusion caused a small, but significant, decrease in fractional glucose excretion. In contrast to the whole kidney data, our micropuncture results did not show any significant difference in fractional glucose reabsorption in either the proximal or distal tubules, indicating that saccharin does not influence renal glucose handling in vivo under euglycemic conditions. In keeping with this finding, protein levels of the renal glucose transporters SGLT1 and SGLT2 were also unchanged. In addition, saccharin infusion in rats undergoing a glucose tolerance test failed to induce a robust change in renal glucose excretion or renal glucose transporter expression. In conclusion, our results demonstrate that saccharin does not induce acute physiologically relevant changes in renal function or renal glucose handling.

Protease stimulation of renal sodium reabsorption in vivo by activation of the collecting duct epithelial sodium channel (ENaC).

BACKGROUND: Proteases can increase the activity of the epithelial sodium channel (ENaC) by cleaving its α- or γ-subunit. However, evidence so far comes only from studies in vitro in either heterologous expression systems or isolated nephron segments. The present study has tested whether exposure to a luminal protease can alter sodium reabsorption along the rat collecting duct in vivo. METHODS: Rats on normal laboratory chow were prepared for renal micropuncture. Late distal tubules of superficial nephrons were microinjected and perfused twice (3 nL min(-1) for 3-6 min) with a solution similar to native tubular fluid, but containing (14)[C]inulin and (22)Na. The first perfusion was either a control solution or solution containing amiloride 1 mM or hydrochlorothiazide (HCTZ ) 1 mM; the second perfusion was either a control solution (time control) or a solution containing chymotrypsin 2 µg mL(-1) ± aprotinin 100 µg mL(-1) or amiloride 1 mM or HCTZ 1 mM. Urinary recoveries of (14)[C]inulin and (22)Na were recorded. RESULTS: In time controls, the Na/In ratio did not change significantly (32.2 ± 3.4% versus 34.5 ± 3.1%). In contrast, chymotrypsin reduced the ratio from 33.3 ± 3.8% to 25.5 ± 2.5% (P < 0.05), indicating an increase in sodium reabsorption. When co-injected with chymotrypsin, the protease inhibitor aprotinin abolished the stimulatory effect of chymotrypsin on sodium reabsorption (31.7 ± 3.4% versus 32.1 ± 2.1%), while aprotinin alone had no effect. When chymotrypsin was co-injected with HCTZ, the Na/In ratio decreased from 36.8 ± 2.3% to 28.0 ± 3.4% (P < 0.05), whereas when given with amiloride, there was no change in the ratio (45.8 ± 3.4% versus 45.5 ± 2.3%), indicating that stimulation of sodium reabsorption by chymotrypsin was ENaC-dependent. CONCLUSIONS: These findings demonstrate proteolytic activation of ENaC in vivo, and suggest that changes in protease activity of the glomerular filtrate and tubular fluid in health or disease could affect net renal sodium excretion.

Cadmium-induced autophagy in rat kidney: an early biomarker of subtoxic exposure.

Environmental exposures to cadmium (Cd) are a major cause of human toxicity. The kidney is the most sensitive organ; however, the natures of injuries and of adaptive responses have not been adequately investigated, particularly in response to environmental relevant Cd concentrations. In this study, rats received a daily ip injection of low CdCl2 dose (0.3 mg Cd/kg body mass) and killed at 1, 3, and 5 days of intoxication. Functional, ultrastructural, and biochemical observations were used to evaluate Cd effects. We show that Cd at such subtoxic doses does not affect the tubular functions nor does it induce apoptosis. Meanwhile, Cd accumulates within lysosomes of proximal convoluted tubule (PCT) cells where it triggers cell proliferation and autophagy. By developing an immunohistochemical assay, a punctate staining of light chain 3-II is prominent in Cd-intoxicated kidneys, as compared with control. We provide the evidence of a direct upregulation of autophagy by Cd using a PCT cell line. Compared with the other heavy metals, Cd is the most powerful inducer of endoplasmic reticulum stress and autophagy in PCT cells, in relation to the hypersensitivity of PCT cells. Altogether, these findings suggest that kidney cortex adapts to subtoxic Cd dose by activating autophagy, a housekeeping process that ensures the degradation of damaged proteins. Given that Cd is persistent within cytosol, it might damage proteins continuously and impair at long-term autophagy efficiency. We therefore propose the autophagy pathway as a new sensitive biomarker for renal injury even after exposure to subtoxic Cd doses.

Heavy metal poisoning: the effects of cadmium on the kidney.

The heavy metal cadmium (Cd) is known to be a widespread environmental contaminant and a potential toxin that may adversely affect human health. Exposure is largely via the respiratory or gastrointestinal tracts; important non-industrial sources of exposure are cigarette smoke and food (from contaminated soil and water). The kidney is the main organ affected by chronic Cd exposure and toxicity. Cd accumulates in the kidney as a result of its preferential uptake by receptor-mediated endocytosis of freely filtered and metallothionein bound Cd (Cd-MT) in the renal proximal tubule. Internalised Cd-MT is degraded in endosomes and lysosomes, releasing free Cd(2+) into the cytosol, where it can generate reactive oxygen species (ROS) and activate cell death pathways. An early and sensitive manifestation of chronic Cd renal toxicity, which can be useful in individual and population screening, is impaired reabsorption of low molecular weight proteins (LMWP) (also a receptor-mediated process in the proximal tubule) such as retinol binding protein (RBP). This so-called 'tubular proteinuria' is a good index of proximal tubular damage, but it is not usually detected by routine clinical dipstick testing for proteinuria. Continued and heavy Cd exposure can progress to the clinical renal Fanconi syndrome, and ultimately to renal failure. Environmental Cd exposure may be a significant contributory factor to the development of chronic kidney disease, especially in the presence of other co-morbidities such as diabetes or hypertension; therefore, the sources and environmental impact of Cd, and efforts to limit Cd exposure, justify more attention.

Effect of heavy metals on, and handling by, the kidney.

Heavy metals such as cadmium (Cd), mercury (Hg), lead (Pb), chromium (Cr) and platinum (Pt) are a major environmental and occupational hazard. Unfortunately, these non-essential elements are toxic at very low doses and non-biodegradable with a very long biological half-life. Thus, exposure to heavy metals is potentially harmful. Because of its ability to reabsorb and accumulate divalent metals, the kidney is the first target organ of heavy metal toxicity. The extent of renal damage by heavy metals depends on the nature, the dose, route and duration of exposure. Both acute and chronic intoxication have been demonstrated to cause nephropathies, with various levels of severity ranging from tubular dysfunctions like acquired Fanconi syndrome to severe renal failure leading occasionally to death. Very varied pathways are involved in uptake of heavy metals by the epithelium, depending on the form (free or bound) of the metal and the segment of the nephron where reabsorption occurs (proximal tubule, loop of Henle, distal tubule and terminal segments). In this review, we address the putative uptake pathways involved along the nephron, the mechanisms of intracellular sequestration and detoxification and the nephropathies caused by heavy metals. We also tackle the question of the possible therapeutic means of decreasing the toxic effect of heavy metals by increasing their urinary excretion without affecting the renal uptake of essential trace elements. We have chosen to focus mainly on Cd, Hg and Pb and on in vivo studies.

Zinc and cadmium interactions in a renal cell line derived from rabbit proximal tubule.

BACKGROUND: The aim of this work was to characterize the relationship between zinc (Zn(2+)) and cadmium (Cd(2+)) and the toxic effects of Cd(2+) in immortalized renal proximal tubule cells RP1. METHODS: An RP1 cell line was developed from primary cultures of microdissected S1 and S2. Uptakes of (65)Zn and (109)Cd and competitive experiments with Cd(2+) and Zn(2+) were performed and kinetic parameters were determined. Oxygen consumption, metallothionein synthesis, and necrotic and apoptotic phenomena were studied. RESULTS: Kinetic parameters indicate that (65)Zn (Km = 71.8 +/- 10.6 microM) and (109)Cd (Km = 23.3 +/- 2.0 microM) were both transported by a saturable carrier-mediated process. Competition between Cd(2+) and Zn(2+) uptake was reciprocal. Cd(2+) induced an increase in necrosis and apoptosis, and a decrease in oxygen consumption, depending on Cd(2+) concentrations. Concomitant addition of Zn(2+) (10 microM) reduced the number of necrotic and apoptotic cells and maintained oxygen consumption at control levels. Cd(2+) alone, or in the presence of Zn(2+), increased metallothionein levels, whereas Zn(2+) alone did not. CONCLUSION: Zn(2+) and Cd(2+) probably share the same transporter in the proximal tubule. Cd(2+) caused necrotic and apoptotic cell death. Cd(2+) toxicity may occur through an effect on the mitochondrial electron transport chain and not on metallothionein synthesis. Zn(2+) protects against the renal cell toxicity of Cd(2+).