Microvasculopathy and soft tissue calcification in mice are governed by fetuin-A, magnesium and pyrophosphate.

Calcifications can disrupt organ function in the cardiovascular system and the kidney, and are particularly common in patients with chronic kidney disease (CKD). Fetuin-A deficient mice maintained against the genetic background DBA/2 exhibit particularly severe soft tissue calcifications, while fetuin-A deficient C57BL/6 mice remain healthy. We employed molecular genetic analysis to identify risk factors of calcification in fetuin-A deficient mice. We sought to identify pharmaceutical therapeutic targets that could be influenced by dietary of parenteral supplementation. We studied the progeny of an intercross of fetuin-A deficient DBA/2 and C57BL/6 mice to identify candidate risk genes involved in calcification. We determined that a hypomorphic mutation of the Abcc6 gene, a liver ATP transporter supplying systemic pyrophosphate, and failure to regulate the Trpm6 magnesium transporter in kidney were associated with severity of calcification. Calcification prone fetuin-A deficient mice were alternatively treated with parenteral administration of fetuin-A dietary magnesium supplementation, phosphate restriction, or by or parenteral pyrophosphate. All treatments markedly reduced soft tissue calcification, demonstrated by computed tomography, histology and tissue calcium measurement. We show that pathological ectopic calcification in fetuin-A deficient DBA/2 mice is caused by a compound deficiency of three major extracellular and systemic inhibitors of calcification, namely fetuin-A, magnesium, and pyrophosphate. All three of these are individually known to contribute to stabilize protein-mineral complexes and thus inhibit mineral precipitation from extracellular fluid. We show for the first time a compound triple deficiency that can be treated by simple dietary or parenteral supplementation. This is of special importance in patients with advanced CKD, who commonly exhibit reduced serum fetuin-A, magnesium and pyrophosphate levels.

[Cardiovascular calcification inhibitors]. / Inhibiteurs des calcifications cardiovasculaires.

Vascular calcification is a marker of cardiovascular risk increase. Age and specific disease such as diabetes or chronic kidney disease are important factors for calcification genesis. Vascular calcification process is a complex phenomenon, involving several activators and inhibitors factors. Indeed, recent works related to in vitro and in vivo experimental studies have led to a better understanding of calcification process and identification of molecules able to modulate this system. This revue will summarize some of these molecules with a particular interest of those with therapeutic relevance. We will present: i) calcium sensing receptor and its modulation by cinacalcet; ii) pyrophosphate supplementation; iii) fetuin A and overall propensity serum test for calcification and finally; iv) matrix-Gla-protein and the use of vitamin K to prevent vascular calcification progression.

Fetuin A promotes lipotoxicity in ß cells through the TLR4 signaling pathway and the role of pioglitazone in anti-lipotoxicity.

OBJECTIVE: Fetuin A (FetA), a secreted glycoprotein, is known to affect inflammation and insulin resistance (IR) in obese humans and animals. Lipotoxicity from chronic hyperlipidemia damages pancreatic ß cells, hastening the onset of diabetes. We sought to determine whether FetA promotes lipotoxicity through modulation of the toll-like receptor 4 (TLR4) inflammatory signaling pathway as well as the protective effect of pioglitazone(PIO) on lipotoxicity. METHODS: ßTC6, a glucose-sensitive mouse pancreatic ß cell line, and Sprague-Dawley rats with diet-induced obesity, were used to investigate FetA-mediated lipotoxicity. Protein expression/activation were measured by Western blotting. Small interfering (si)RNAs for TLR4 were used. Cell apoptosis was quantified by TUNEL analysis or flow cytometry, respectively. Insulin release was assessed with an insulin ELISA. RESULTS: FetA dose-dependently aggravated palmitic acid (PA)-induced ßTC6 cell apoptosis, insulin secretion impairment, and inhibition of the expression of G-protein-coupled receptor 40 (GPR40) and pancreatic duodenal homeobox-1(PDX-1). Combined FetA + PA induced TLR4 expression, and subsequent inhibition of TLR4 signaling or expression was shown to prevent the strengthening effect of FetA on PA-induced lipotoxicity in ßTC6 cells. FetA + PA induced p-JNK and nuclear factor-κB (NF-κB) subunit P65 expression, and inhibition of this activity reduced PA+ FetA lipotoxicity in ßTC6 cells. PIO could ameliorate PA+ FetA-induced damage to ßTC6 cells. Similarly, PIO improved insulin secretion disorder, reduced apoptosis, decreased FetA, TLR4, p-JNK, NF-κB subunit P65 and cleaved caspase 3 expression, and increased GPR40 and PDX-1 expression in islet ß cells of diet-induced obese rats. The correlative bivariate analysis showed that increases in Fetuin A were directly proportional to the development of ß cell injury. CONCLUSIONS: FetA can promote lipotoxicity in ß cells through the TLR4-JNK-NF-κB signaling pathway. The protective effects of PIO on lipotoxicity in ß cells may involve the inhibition of the activation of the FetA and TLR4 signaling pathway.