#4000 ROLE OF ENDOTHELIAL CELLS IN VASCULAR CALCIFICATION

Abstract

Abstract Background and Aims Vascular calcification (VC) represents a common pathological feature of cardiovascular disease and VC caused by hyperphosphatemia is one of the hallmarks of chronic kidney disease (CKD). Therefore, elucidating the pathogenesis of VC may have significant clinical benefits for CKD patients. Vascular smooth muscle cells challenged with high-phosphate (Pi) actively participate to VC by trans-differentiating into simil-osteoblastic cells that acquire the capability to deposit hydroxyapatite crystals in the extracellular matrix of tunica media in arteries. The role of endothelial cells (ECs) in high-Pi calcification has been poorly investigated until now. Nonetheless, following particular stimuli ECs can lose their endothelial characteristics and acquire several different phenotypes transdifferentiating with a process known as endothelial-to-mesenchymal transition (EndMT). Given the central role of VC for CKD patients wellbeing we decided to investigate whether ECs may have a role in VC process. Method We set up an in vitro calcification model with human aortic ECs (HAECs) challenged with 2, 2.5, 3, 3.5 mM high-Pi for 7 days. Calcium deposition, cell viability and cell trans-differentiation were evaluated. Results In our model we observed deposition of calcium phosphate crystals induced by high-Pi that resulted significant from 3 up to 3.5 mM Pi (Ctr 0.43 ± 0.01; 3 mM Pi 6.72 ± 1.15; 3.5 mM Pi 17.31 ± 1.88; micromol Ca++/mg protein; P < .01; Fig 1A-B). We found that calcification is mediated by Pi-influx, as demonstrated by the inhibition of calcium deposition by Phosphonoformic acid (PFA), an inhibitor of Na/Pi cotransporter Pit-1 (3.5 mM Pi 15.52 ± 1.97; 1 mM PFA 0.6 ± 0.05; micromol Ca++/mg protein; P < .0001; Fig 1A, C). In addition, in our model high-Pi did not show any significant toxic effect at every concentration tested compared to control cells. In Pi-treated ECs we observed a clear change in cell-morphology from cobblestone to spindle shaped, a recognized sign of EndMT. Moreover, we observed a change in extracellular matrix composition more similar to osteoblastic matrix. In facts, ECs treated with Pi were Alcian Blue positive, a staining that binds glycosaminoglycans contained in bone matrix, with blue granules of calcium-phosphate in the cytoplasm of treated cells. Starting from day 5 up to day 7 the transition was confirmed by an up-regulation of SNAIL and N-cadherin mRNA expressions, one of the master genes and one the markers of EndMT process, respectively. A modification of endothelial phenotype was also supported by a progressive decrease in protein expression of Von Willebrand factor and VE-Cadherin observed at day 9 of calcification (−53.7% and −32.6% respectively). Moreover, from day 5 till day 7 we found some osteoblastic differentiation signs such as a progressive increase of RUNX2 and BMP2 mRNA expression and an increase of protective MGP mRNA levels. Conclusion Our data demonstrate that HAECs are able to calcify. High-Pi induces trans-differentiation in simil-osteoblastic cells and a progressive loss of endothelial characteristics through the EndMT process. More studies are needed to better elucidate the role for ECs in CKD VC process.