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Query: UMLS:C0020437 (hypercalcemia)
10,293 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Low urinary calcium levels and hypomagnesaemia were observed in three subjects with renal tubular abnormalities. The first, with severe hypomagnesaemia due to congenital renal magnesium wasting, had mildly raised serum ionized calcium levels (1.34-1.36 mmol/l). The other two, a brother and sister, had features of Bartter's syndrome with hypokalaemia, mild hypomagnesaemia and hyperreninaemia with normal serum ionized calcium levels. Hypocalciuria was seen in 24-h urine collections and in 2-hourly timed urine collections. Magnesium loading with intramuscular MgSO4 was used to raise serum Mg to within the normal range. Tubular reabsorption of Mg (TMg) rose while TCa fell, with a rise in fractional excretion of ionized Ca and a small drop in serum ionized Ca. Serum parathyroid hormone levels rose or remained constant. This pattern is consistent with a shared Ca/Mg reabsorptive pathway with a rise in TCa when TMg is low, returning to normal when TMg is raised by Mg loading. In one subject, this imbalance was associated with marginal hypercalcaemia. The site for this pathway is likely to be the thick ascending limb of the loop of Henle.
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PMID:Reversible hypocalciuria with marginal hypercalcaemia in renal magnesium wasting. 846 88

Renal function was observed in freshwater North American eels (Anguilla rostrata LeSueur) 2 weeks after the removal of the corpuscles of Stannius. There was a positive linear correlation between glomerular filtration rates and urine flow rates in both sham-operated and stanniectomized eels but there was no difference in slope or elevation between the two groups nor did urine flow rates ever exceed glomerular filtration rates. Osmolar clearance and free-water clearance were unchanged following stanniectomy. Plasma Ca2+ and K+ concentrations increased and plasma Mg2+, phosphate, Na+ and Cl- concentrations decreased following stanniectomy. Plasma ultrafilterable Ca increased and ultrafilterable Mg decreased after stanniectomy but neither changed relative to its total plasma concentration. Stanniectomy was followed by a decreased renal tubular reabsorption of Mg2+ relative to the amount filtered (CMg/CIn); the same applies to CNa/CIn. Even though the filtered load of Ca increased in conjunction with the predictable hypercalcemia, there was no change in the fraction of filtered Ca reabsorbed. Net tubular secretion of phosphate was observed in both sham-operated and stanniectomized eels together with a slight increase in Cphos/CIn following stanniectomy. Some or all of these changes in plasma electrolytes and/or the modified renal transport of Na+, Mg2+ and possibly phosphate may be caused by the changes in cardiovascular function that were recently shown to follow stanniectomy.
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PMID:Fractional reabsorption of calcium, magnesium and phosphate in the kidneys of freshwater North American eels (Anguilla rostrata LeSueur) following removal of the corpuscles of Stannius. 857 50

We recently cloned extracellular Ca(2+)-sensing receptors (CaRs) from bovine parathyroid and rat kidney that play key roles in Ca2+ homeostasis. Inactivating mutations of the CaR in the inherited human disorder, familial hypocalciuric hypercalcemia, cause reduced responsiveness of the parathyroid to extracellular Ca2+ (Cao2+), as well as abnormally avid renal tubular reabsorption of both Ca2+ and Mg2+ in the distal tubule, suggesting an important role for the CaR in regulating parathyroid hormone (PTH) secretion and renal handling of divalent cations. High Cao2+ also inhibits vasopressinstimulated adenosine 3',5'-cyclic monophosphate accumulation in the medullary thick ascending limb (MTAL) and water reabsorption in the collecting duct (CD) and modulates various other aspects of renal function. The relevance of the CaR to these processes, however, is uncertain. Reduced responsiveness of vasopressin-and PTH-mediated actions on the kidney have been described in the newborn that could potentially reflect effects of the CaR on these aspects of renal function. To define further the role of the CaR in regulating renal function, including the above-mentioned changes during the perinatal period, therefore, we have studied its ontogeny in rat kidney. Northern and Western blot analyses, as well as immunohistochemistry with CaR-specific probes, demonstrate that there is little prenatal expression of the extracellular Ca(2+)-sensing receptor, except in large tubules and branching ureteric buds of developing nephrons. Postnatally, CaR mRNA and protein increase markedly during the 1st wk, related principally to expression of the receptor in the developing TAL and, to a lesser extent, in the CD. The level of expression of the receptor remains nearly constant after postnatal day 14. These results demonstrate that the perinatal increases in expression of CaR mRNA and protein parallel its tissue-specific renal expression. Furthermore, it is possible that some of the previously described changes in renal handling of divalent cations and water in the perinatal and immediate postnatal period are related, in part, to the increasing levels of expression of the CaR and resultant inhibitory effects on the actions of PTH and antidiuretic hormone on the developing nephron.
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PMID:Ontogeny of the extracellular calcium-sensing receptor in rat kidney. 885 37

The recent cloning of a [Ca2+]o-sensing receptor from several different tissues in several species directly demonstrates that a variety of cells can directly recognize and respond to small changes in their ambient level of [Ca2+]o through a G protein-coupled, cell surface receptor. This finding directly documents that [Ca2+]o can act as an extracellular, first messenger in addition to subserving its better known role as an intracellular second messenger. Several of the tissues expressing the CaR are important elements in the calcium homeostatic system that have long been known to be capable of sensing [Ca2+]o, such as parathyroid and thyroidal C cells. The presence of the receptor in the kidney, however, provides strong evidence that several of the long-recognized but poorly understood direct actions of [Ca2+]o on renal function could be mediated by the CaR. These actions include the up-regulation of urinary calcium and magnesium excretion in the setting of hypercalcemia, which complements the indirect inhibition of renal tubular reabsorption of calcium that results from high [Ca2+]o-mediated inhibition for PTH secretion. The impaired renal concentrating capacity in hypercalcemia is likely a manifestation of a homeostatically important interaction between the regulation of renal calcium and water handling that reduces the risk of pathological deposition of calcium in the kidney when there is a need to dispose of excess, calcium in the urine. In this regard, the availability of human syndromes of [Ca2+]o "resistance" or "overresponsiveness" due to loss-of-function or gain-of-function mutations in the CaR, respectively, have provided useful experiments in nature that have clarified the importance of the receptor in both abnormal and normal physiology. Much remains to be learned, however, about the role of the CaR in locations, such as the brain, where it likely responds to local rather than systemic levels of [Ca2+]o. In such sites, it may represent an important modulator of neuronal function, responding to [Ca2+]o as a neuromodulator or even neurotransmitter. The development of therapeutics that either activate or inhibit the function of the CaR may be useful for treating a variety of conditions in which the receptor is either under- or overactive. Finally, it would not be surprising to discover additional receptors for [Ca2+]o or for other ions (the CaR may, in fact, be an important [Mg2+]o-sensor) that could function abnormally in certain disease states and be amenable to pharmacological manipulation with ion receptor-based therapeutics.
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PMID:The calcium-sensing receptor: a window into the physiology and pathophysiology of mineral ion metabolism. 885 47

The divalent mineral cations Ca2+ and Mg2+ play many and diverse roles both in the function of cells and in extracellular processes. The metabolism of these cations is a complex process involving the coordinated function of several organ systems and endocrine glands. A recently cloned G-protein-coupled receptor responds to extracellular calcium concentration (Ca2+0-sensing receptor, CaSR) and mediates several of the known effects of Ca2+0 on parathyroid and renal function. The CaSR, which is also expressed in a number of other tissues including thyroidal C-cells, brain and gastrointestinal tract, may function as a Ca2+0 sensor in these tissues as well. Thus, Ca2+0 is a first messenger (or hormone) which, via CaSR-mediated activation of second messenger systems (e.g. phospholipases C and A2, cyclic AMP) leads to altered function of these cells. Several mutations in the human CaSR gene have been identified and shown to cause three inherited diseases of calcium homeostasis, clearly implicating the CaSR as an important component of the homeostatic mechanism for divalent mineral ions. Ca2+ and Mg2+ losses from the body are regulated by altering the urinary excretion of these divalent cations. The localization of the CaSR transcripts and protein in the kidney not only provides a basis for a direct Ca2+0 (or Mg2+0)-mediated regulation of Ca2+ (and Mg2+) excretion but also suggests a functional link between divalent mineral and water metabolism. In the kidney, the thick ascending limb of Henle (TAL) plays crucial roles in regulating both divalent mineral reabsorption and urine concentration. Recent studies have suggested models whereby extracellular Ca2+, via the CaSR expressed in the TAL as well as in the collecting duct system, modulates both Ca2+ 0 and Mg2+ 0 as well as water reabsorbtion. When taken together, these studies suggest that the CaSR not only provides the primary mechanism for Ca2+ 0-mediated regulation of parathyroid hormone secretion from parathyroid glands but also for direct modulation of renal divalent mineral excretion and urinary concentrating ability. These latter functions may furnish a mechanism for integrating and balancing water and divalent cation losses that minimizes the risk of urinary tract stone formation. This mechanism can explain hypercalcemia-mediated polyuria (diabetes insipidus).
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PMID:Role of the Ca(2+)-sensing receptor in divalent mineral ion homeostasis. 905 Feb 37

Rana pipiens were divided into four groups: controls; hypocalcemic frogs, depleted of salts by acclimation to deionized water; hypercalcemic frogs, calcium-loaded by the introduction of 40 mumol calcium gluconate; and frogs exposed to the potential competing ions Mg2+, Sr2+, and Ba2+. All groups displayed calcium influx that was proportional to external [Ca2+]; however, the group acclimated to deionized water also displayed hypocalcemia (P < 0.025) and enhanced Ca2+ influx at higher (> 0.3 mM) external [Ca2+]. Ca2+ efflux was depressed in hypocalcemic frogs, and thus net Ca2+ flux shifted from net loss in control frogs to net uptake in hypocalcemic frogs. Hypocalcemia also resulted in increased skin Ca2+ deposits which may be related to a decreased Ca2+ (and other ions) permeability as a consequence of the acclimation to deionized water. Another group of frogs was Ca(2+)-loaded by injecting calcium gluconate: Sodium gluconate controls did not significantly alter Ca2+ fluxes. The frogs that received calcium gluconate treatments became hypercalcemic (P < 0.01) and did not display significant changes in calcium fluxes, nor did they show significant changes in skin calcium deposits. We conclude that hypocalcemia leads to regulatory responses that stimulate active Ca2+ transport in Rana pipiens skin and possibly inhibits cutaneous and renal efflux. We also conclude that hypercalcemia does not alter calcium fluxes across skin. The ions from Group IIA of the Periodic Table of Elements had little effect on Ca2+ fluxes at concentrations ranging from 0.5-4.0 mM; neither Sr2+ or Ba2+ affected Ca2+ influx. The only divalent ion tested that influenced Ca2+ was Mg2+, which significantly inhibited Ca2+ influx but only at 4.0 mM or eight times the external [Ca2+]. We conclude, therefore, that the Ca2+ transport mechanism is fairly specific for Ca2+ within Group IIA.
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PMID:Cutaneous transport of Ca2+ in the frog Rana pipiens: significance and specificity. 912 56

The ability of parathyroid cells to recognize and respond to (i.e., "sense") small changes in the extracellular Ca2+ concentration (Ca2+o) plays a crucial role in mineral ion homeostasis. Expression cloning in Xenopus laevis oocytes enabled isolation of a cDNA coding for the bovine parathyroid CaR. CaRs were later isolated from human parathyroid and kidney, rat kidney, brain and C-cell, rabbit kidney, and chicken parathyroid. All are tissue and species homologs of the same ancestral gene. The predicted CaR protein has a large extracellular amino-terminus, which binds polycationic CaR agonists; a central core with seven membrane-spanning helices, documenting that it is a G protein-coupled receptor; and an approximately 200 amino acid carboxyl-terminal tail. The CaR is highly expressed in parathyroid and C-cells, along almost the entire nephron and gastrointestinal (GI) tract and within numerous regions of the brain, particularly hippocampus, cerebellum, and hypothalamus. The CaR's physiological importance has been documented by the identification of hyper- and hypocalcemic syndromes due to inactivating or activating CaR mutations, respectively. Familial hypocalciuric hypercalcemia (FHH) and neonatal severe hyperparathyroidism (NSHPT) are caused by loss-of-function CaR mutations producing Ca2+o "resistance," while autosomal dominant hypocalcemia is the result of activating mutations rendering CaRs overly sensitive to Ca2+o. In addition to showing altered parathyroid responsiveness to Ca2+o, patients with FHH reabsorb too much urinary Ca2+ and Mg2+ at a given Ca2+o, while those with autosomal dominant hypocalcemia excrete too much, illustrating the CaR's key role in renal handling of divalent cations. Recent in vitro data suggest that the CaR directly regulates renal water handling in the collecting duct. Indeed, patients with FHH concentrate their urine normally, despite their hypercalcemia, while those with autosomal dominant hypocalcemia can exhibit impaired urinary concentration at normal or even low Ca2+o, suggesting that the CaR enables coordination of renal calcium and water handling. In addition to serving these "homeostatic" roles, the CaR likely also enables Ca2+o to serve additional roles as an extracellular messenger. The receptor regulates key Ca2+ and K(+)-permeable ion channels in hippocampal and other brain cells and likely senses local changes in Ca2+o within the brain microenvironment accompanying neuronal activation. It is also present in and regulates ion channels in lens epithelial cells, potentially playing some role in cataract development in hypoparathyroid patients. In keratinocytes and epithelial cells of the gastrointestinal tract, in contrast, the CaR may regulate cellular proliferation and differentiation, processes known to be modulated by Ca2+o in these cell types. Thus, in addition to sensing and regulating systemic Ca2+o, the CaR likely enables Ca2+o to act as a local signal for cells within specific microenvironments, such as the brain or eye.
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PMID:The calcium-sensing receptor (CaR) permits Ca2+ to function as a versatile extracellular first messenger. 976 11

1. The aim of this study was to investigate some of the cellular mechanisms involved in the effects caused by changes in extracellular Ca2+ concentration ([Ca2+](o)). 2. Current- and voltage-clamp experiments were carried out on acutely isolated thalamic neurons of rats. 3. Increasing [Ca2+](o) alone induced a transition of the discharge from single spike to burst mode in isolated current-clamped neurons. 4. Increasing [Ca(2+)](o) caused the voltage-dependent characteristics of the low voltage-activated (LVA) transient Ca2+ currents to shift towards positive values on the voltage axis. Changing [Ca2+](o) from 0.5 to 5 mM caused the inactivation curve to shift by 21 mV. 5. Extracellular Ca2+ blocked a steady cationic current. This current reversed at -35 mV, was scarcely affected by Mg2+ and was completely blocked by the non-selective cation channel inhibitor gadolinium (10 microM). The effect of [Ca2+](o) was mimicked by 500 microM spermine, a polyamine which acts as an agonist for the Ca(2+)-sensing receptor, and was modulated by intracellular GTP-gamma-S. 6. At the resting potential, both the voltage shift and the block of the inward current removed the inactivation of LVA calcium channels and, together with the increase in the Ca2+ driving force, favoured a rise in the low threshold Ca2+ spikes, causing the thalamic firing to change to the oscillatory mode. 7. Our data indicate that [Ca2+](o) is involved in multiple mechanisms of control of the thalamic relay and pacemaker activity. These findings shed light on the correlation between hypercalcaemia, low frequency EEG activity and symptoms such as sleepiness and lethargy described in many clinical papers.
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PMID:Changes in extracellular Ca2+ can affect the pattern of discharge in rat thalamic neurons. 1150 56

Phosphate (Pi) retention is a common problem in patients with chronic kidney disease, particularly in those who have reached end-stage renal disease (ESRD). In addition to causing secondary hyperparathyroidism and renal osteodystrophy, recent evidence suggests that, in ESRD patients, high serum phosphorus concentration and increased calcium and phosphorous (Ca x P) product are associated with vascular and cardiac calcifications and increased mortality. Dietary phosphorus restriction and Pi removal by dialysis are not sufficient to restore Pi homeostasis. Reduction of intestinal Pi absorption with the use of Pi binders is currently the primary treatment for Pi retention in patients with ESRD. The use of large doses of calcium-containing Pi binders along with calcitriol administration may contribute to over-suppression of parathyroid hormone secretion and adynamic bone disease as well as to a high incidence of vascular calcifications. When used in patients with impaired renal function, aluminium salts were found to accumulate in bone and other tissues, resulting in osteomalacia and encephalopathy.Sevelamer, an aluminium- and calcium-free Pi binder can reduce serum phosphorus concentration and is associated with a significantly lower incidence of hypercalcaemia, while maintaining the ability to suppress parathyroid hormone production. An additional benefit of sevelamer is its ability to lower low density lipoprotein-cholesterol and total cholesterol levels. Sevelamer attenuates the progression of vascular calcifications in haemodialysis patients, which may lead to lower mortality. The use of sevelamer in non-dialysed patients might aggravate metabolic acidosis, common in these patients. Several other calcium-free Pi binders are in development. Lanthanum carbonate has shown significant promise in clinical trials in ESRD patients. Magnesium salts do not offer a significant advantage over currently available Pi binders. Their use is restricted to patients receiving dialysis since excess magnesium must be removed by dialysis. Iron-based compounds have shown variable efficacy in short-term clinical trials in small numbers of haemodialysis patients. Mixed metal hydroxyl carbonate compounds have shown efficacy in animals but have not been studied in humans. Major safety issues include absorption of the metal component with possible tissue accumulation and toxicity.
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PMID:Safety of new phosphate binders for chronic renal failure. 1464 Jul 73

Magnesium-deficient rats develop significant hypercalcemia, hypophosphatemia, and hyperphosphaturia. These changes suggest a state of hyperparathyroidism. This study examines the regulation of parathyroid gland activity in magnesium-deficient rats. Magnesium deficiency was induced in intact and chronically parathyroidectomized animals by feeding them a diet free of this cation. Control animals were pair fed and treated identically except for the inclusion of magnesium in their gavage solution.Magnesium-deficient rats with intact parathyroid glands developed significant hypercalcemia and hypophosphatemia. In addition, the concentration of ionic calcium in plasma was significantly elevated. In contrast, magnesium-deficient parathyroidectomized animals did not have a higher level of calcium in plasma than their nondeficient controls; they developed a decreased concentration of ionic calcium in the absence of a difference in the concentration of phosphate in plasma when compared with appropriate controls. The increased urinary excretion of phosphate was independent of the parathyriod status of the animals.It can be concluded that the hypercalcemia and hypophosphatemia of magnesium deficiency demands parathyroid gland activity and that the regulation of this activity is modified in the magnesium-deficient state to permit the maintenance of an elevated concentration of ionic calcium in plasma. Additional explanations must be found for the hyperphosphaturia.
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PMID:The influence of the parathyroid glands on the hypercalcemia of experimental magnesium depletion in the rat. 1669 34


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