Vitamin D and Calcium Supplementation Accelerates Randall's Plaque Formation in a Murine Model.

Most kidney stones are made of calcium oxalate crystals. Randall's plaque, an apatite deposit at the tip of the renal papilla, is considered to at the origin of these stones. Hypercalciuria may promote Randall's plaque formation and growth. We analyzed whether long-term exposure of Abcc6-/- mice (a murine model of Randall's plaque) to vitamin D supplementation, with or without a calcium-rich diet, would accelerate the formation of Randall's plaque. Eight groups of mice (including Abcc6-/- and wild type) received vitamin D alone (100,000 UI/kg every 2 weeks), a calcium-enriched diet alone (calcium gluconate 2 g/L in drinking water), both vitamin D supplementation and a calcium-rich diet, or a standard diet (controls) for 6 months. Kidney calcifications were assessed by 3-dimensional microcomputed tomography, µ-Fourier transform infrared spectroscopy, field emission-scanning electron microscopy, transmission electron microscopy, and Yasue staining. At 6 months, Abcc6-/- mice exposed to vitamin D and calcium supplementation developed massive Randall's plaque when compared with control Abcc6-/- mice (P < 0.01). Wild-type animals did not develop significant calcifications when exposed to vitamin D. Combined administration of vitamin D and calcium significantly accelerates Randall's plaque formation in a murine model. This original model raises concerns about the cumulative risk of vitamin D supplementation and calcium intakes in Randall's plaque formation.

Urothelium proliferation is a trigger for renal crystal deposits in a murine lithogenesis model.

Most mouse kidney stone models induce nephrocalcinosis rather than urolithiasis. The aim of our study was to find an accelerated experimental model in order to study the early events of stone formation, that is, at the time of crystal binding to intrarenal urothelium. C57B6 mice exposed to vitamin D supplements and water containing hydroxyl-L-proline, ammonium chloride and calcium chloride were studied for 42 days. A group receiving urothelial cell mitogen Fibroblast Growth Factor 7 (FGF7) was compared to control group receiving saline. Calcium oxalate monohydrate (COM) crystals were detected in urines by day 2 and within urinary spaces in specialized fornix areas in both groups as soon as day 14 with enhanced deposits in FGF7 group compared to controls at day 21. Urothelial cells proliferation, uroplakin III downregulation and de novo expression of osteopontin receptor CD44 detected in FGF7 group, were delayed in the control group (day 42). Crystal aggregates within specialized fornix areas by day 42 were located in urinary spaces but also within and under a multilayered metaplastic urothelium, simultaneous to macrophages influx. Point of note, administration of a normal diet by day 21 was responsible for a spontaneous crystal clearance. Our data show that under supersaturation conditions, urothelial cell proliferation and calcium oxalate crystal retention occur within specialized fornix areas. Enhanced crystal deposits following FGF7 administration suggest that urothelium proliferation would be a relevant trigger for renal stone formation.

Calcium and vitamin D have a synergistic role in a rat model of kidney stone disease.

Vitamin D supplementation in humans should be accompanied by calcium administration to avoid bone demineralization through vitamin D receptor signaling. Here we analyzed whether long-term exposure of rats to vitamin D supplementation, with or without a calcium-rich diet, would promote kidney stone formation. Four groups of rats received vitamin D alone (100,000 UI/kg/3 weeks), a calcium-enriched diet alone, both vitamin D supplementation and calcium-enriched diet, or a standard diet (controls) for 6 months. Serum and urine parameters and crystalluria were monitored. Kidney stones were assessed by 3-dimensional micro-computed tomography, infrared spectroscopy, von Kossa/Yasue staining, and field emission scanning electron microscopy. Although serum calcium levels were similar in the 4 groups, rats receiving vitamin D had a progressive increase in urinary calcium excretion over time, especially those receiving both calcium and vitamin D. However, oral calcium supplementation alone did not increase urinary calcium excretion. At 6 months, rats exposed to both calcium and vitamin D, but not rats exposed to calcium or vitamin D alone, developed significant apatite kidney calcifications (mean volume, 0.121 mm(3)). Thus, coadministration of vitamin D and increased calcium intake had a synergistic role in tubular calcifications or kidney stone formation in this rat model. Hence, one should be cautious about the cumulative risk of kidney stone formation in humans when exposed to both vitamin D supplementation and high calcium intake.

Calpains Released by T Lymphocytes Cleave TLR2 To Control IL-17 Expression.

Calpains are intracellular proteases that play a key role in inflammation/immunity. Rare studies show that they are partially externalized. However, the mechanism of this secretion and the functions of exteriorized calpains remain poorly understood. In this study, we found that mouse and human lymphocytes secreted calpains through an ABCA1-driven process. In turn, extracellular calpains inhibited IL-17A expression. We were able to attribute this function to a cleavage of the TLR2 extracellular domain, which prevented TLR2-induced transcription of molecules essential for IL-17A induction. Calpain exteriorization and TLR2 cleavage were critical for the control of IL-17A expression by low doses of IL-2. By using newly developed transgenic mice in which extracellular calpains are specifically inactivated, we provide evidence for the relevance of calpain externalization in vivo in regulating IL-17A expression and function in experimental sterile peritonitis and autoimmune arthritis, respectively. Thus, this study identifies calpain exteriorization as a potential target for immune modulation.