Calcium-sensing receptor and calcium kidney stones

In the kidney, the CaSR performs different tasks depending on the various tubular segments in which it is located (figure 1) [25]. It is expressed on the luminal membrane of the proximal tubular cells where it senses the increase in calcium luminal concentrations and inhibits cAMP production induced by PTH [23, 26]. In proximal tubules, PTH causes phosphate excretion by internalization and degradation of phosphate reabsorption carriers (NPT2c and NPT2a) in subapical vesicles derived from brush border. In-vitro microperfusion studies of single mouse proximal tubules showed that CaSR limits PTH activity and decreases urinary loss and luminal concentrations of phosphates [27].

CaSR is expressed on the basolateral membrane of the thick ascending limb of Henle loop [26]. In this tubular segment, a sodium-potassium-chloride carrier (NKCC2) couples the inward transport of these three ions through the apical membrane. The activity of NKCC2 is sustained by the sodium-potassium-pump in the basolateral membrane and by the low-conductance potassium channels (ROMK) in the apical membrane [21]. ROMK allows potassium ions recycling from cytoplasm into the tubular lumen, thus sustaining the positive luminal charge of the electric gradient between interstitium and tubular lumen. This electric gradient becomes the driving force for paracellular reabsorption of sodium and calcium [21]. In in-vitro studies on microdissected or isolated microperfused tubules from laboratory animals, CaSR activation by serum-interstitial calcium enhanced the intracellular production of arachidonic acid and HETE that can inactivate the potassium ROMK channel and the Na-K-2Cl cotransporter [20]. The inactivation of these carriers inhibited the passive reabsorption of sodium, potassium and chloride and blocked the potassium recycling to the lumen through the specific ROMK channel [20, 21]. This mechanism dissipates the positive luminal electrical potential generated by potassium recycling and decreases the passive calcium reabsorption (figure 2). In thick ascending limbs isolated from dogs, CaSR also inhibited the phosphorilation of claudin-16 through a mechanism mediated by the decrease in the protein kinase A activity. The unphosphorilated form of claudin-16 was not expressed in tight junctions and its absence reduced the tight junction permeability to calcium and magnesium, thus amplifying the calciuric effect of CaSR [28]. In cortical segment of the thick ascending limb, explored in mice by single tubule microperfusion experiments, CaSR decreased the PTH-dependent passive calcium reabsorption through the apical membrane by antagonizing the PTH-stimulated cAMP production (figure 2) [29].

In the distal convoluted tubule, CaSR is located on the basolateral membrane of tubular cells and in cultured dog cells from this tubular segment CaSR was found to reduce the active calcium reabsorption by interfering with the calcium pump function through a phospholipase C dependent mechanism. The signaling pathway for this effect requires activation of G_q proteins [30].

In the collecting duct, CaSR is expressed on the apical membrane of the principal and intercalated cells [23, 31]. In cultured mouse principal cells, CaSR altered the trafficking of aquaporin 2 (AQP2) and reduced the urine concentrating ability by antagonizing vasopressin activity and the cAMP-dependent activation of protein kinase A [32]. In intercalated cells, the stimulation of CaSR with an agonist promoted urinary acidification in mice, through the activation of the proton pump enhancing proton secretion in urine [33].

The analysis of the described CaSR functions in the kidney suggests that in the ascending limb and distal convolute tubule CaSR is sensitive to serum calcium because of its location on basolateral membrane of tubular cells. Here, the CaSR modulates calcium reabsorption according to the serum levels of calcium so that its increase may be compensated by the CaSR-mediated inactivation of both passive and active distal calcium reabsorption. Nevertheless, a high calcium excretion is potentially dangerous for the kidney as it increases the probability of calcium-phosphate precipitation inside the kidney. This probability especially increases in the papilla, where the fluid concentration is unusually high. To prevent possible dangerous consequences caused by high calcium excretion, CaSR might induce the modifications counterbalancing the tubular function. In proximal tubules, the antiphosphaturic effect reduces the phosphate load to the distal tubular segments, where CaSR decreases calcium reabsorption. In the collecting duct, CaSR promotes urinary salt dilution and acidification, both necessary to favor the solubility of calcium-phosphate salts [34]. These effects appear to be an integrated system able to prevent calcium-phosphate precipitation in kidney tubules and complications like nephrocalcinosis and the formation of calcium-phosphate stones. This hypothetical system is supported by experiments in tubular cells or tubules from laboratory animals, but their relevance has not yet confirmed in humans [35]. This system, if confirmed, seems to be specifically dedicated to the control of calcium-phosphate precipitation within kidney tubules, which are the principal bivalent ions in human body. However, it could also prevent interstitial precipitation of calcium-phosphate salt in kidney medulla to form Randall's plaque that is an apatite deposit in papillary interstitium on which calcium-oxalate stones may develop after ulceration of urothelium covering it [36, 37].

Three missense polymorphisms of the CaSR gene have a significant frequency in general population. They are located on exon 7 and are A986S (rs1801725, G > T), R990G (rs1042636, A > G) and Q1011E (rs1801726, C > G). Few studies considering CaSR as a candidate-gene tested the frequency of their alleles in nephrolithiasis. A study was performed in 223 Canadian idiopatic calcium stone formers genotyped for A986S and R990G. It observed significant Hardy-Weinberg disequilibrium at the R990G locus in cases, but not in controls, and attributed this disequilibrium to the association of the polymorphism with stones. Carriers of the 990G allele had an eightfold increase of stone risk [40]. Another study was carried out in a group of 99 Iranian recurrent stone formers and observed a significantly higher frequency of the 986S, 990G and Q1011 alleles in stone formers [41]. Two other studies found a significant association between the 990G allele and stones in Italian patients with primary hyperparathyroidism [42, 43]. R990G was also associated with primary hypercalciuria, a disorder predisposing to calcium kidney stones, and the association was observed both in stone formers and in stone free subjects [44, 45]. This allele was recognized to cause a gain of CaSR function in transfected embrionic kidney cells HEK-293 [45].

These findings confirm that CaSR gene polymorphisms may be involved in calcium nephrolithiasis, but propose an intriguing scenario in which stone formation appears to be favored by an activating polymorphism (R990G) and by polymorphisms decreasing expression of the CaSR gene. Despite their apparently opposite effect, both polymorphisms could predispose to calcium nephrolithiasis. Today, we have no sufficient knowledge to explain this puzzle, that, to be resolved, needs experiments evaluating the CaSR activity in kidney tubules and the functional effect of the variant alleles at these polymorphisms. An initial contribution was given by a study in knockout mice for the calcium channel TRPV5 [33]. TRPV5-/- mice were hypercalciuric, but did not form calcium stones or precipitate; they developed calcium-phosphate precipitate in collecting ducts only after inhibition of H-pump activity that hampers urine acidification. The use of allosteric agonist of CaSR in these mice showed that CaSR stimulated H-pump activity in collecting ducts and allowed to maintain urine stability. TRPV5-/- mice were also polyuric because the stimulation of CaSR by luminal calcium antagonized vasopressin activity in collecting ducts [33].