Dynamics of differentiated-renal epithelial cell monolayer after calcium oxalate injury: The role of cyclooxygenase-2.

C. Casali, L. Pescio, Dylan E. Sendyk, Luciana Erjavec, Emanuel Morel Gómez, Leandro Parra, M. Fernández-Tomé
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Abstract

AIMS Calcium oxalate (Oxa), constituent of most common kidney stones, damages renal tubular epithelial cells leading to kidney disease. Most in vitro studies designed to evaluate how Oxa exerts its harmful effects were performed in proliferative or confluent non-differentiated renal epithelial cultures; none of them considered physiological hyperosmolarity of renal medullary interstitium. Cyclooxygenase 2 (COX2) has been associated to Oxa deleterious actions; however, up to now, it is not clear how COX2 acts. In this work, we proposed an in vitro experimental system resembling renal differentiated-epithelial cells that compose medullary tubular structures which were grown and maintained in a physiological hyperosmolar environment and evaluated whether COX2 → PGE2 axis (COX2 considered a cytoprotective protein for renal cells) induces Oxa damage or epithelial restitution. MAIN METHODS MDCK cells were differentiated with NaCl hyperosmolar medium for 72 h where cells acquired the typical apical and basolateral membrane domains and a primary cilium. Then, cultures were treated with 1.5 mM Oxa for 24, 48, and 72 h to evaluate epithelial monolayer restitution dynamics and COX2-PGE2 effect. KEY FINDINGS Oxa completely turned the differentiated phenotype into mesenchymal one (epithelial-mesenchymal transition). Such effect was partially and totally reverted after 48 and 72 h, respectively. Oxa damage was even deeper when COX2 was blocked by NS398. PGE2 addition restituted the differentiated-epithelial phenotype in a time and concentration dependence. SIGNIFICANCE This work presents an experimental system that approaches in vitro to in vivo renal epithelial studies and, more important, warns about NSAIDS use in patients suffering from kidney stones.
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草酸钙损伤后分化肾上皮细胞单层的动态:环氧化酶-2的作用。
草酸钙(Oxa)是大多数常见肾结石的组成成分,它损害肾小管上皮细胞,导致肾脏疾病。大多数旨在评估Oxa如何发挥其有害作用的体外研究都是在增生性或融合性非分化肾上皮培养中进行的;他们都没有考虑肾髓间质生理性高渗。环氧合酶2 (COX2)与Oxa的有害作用有关;然而,到目前为止,COX2的作用机制尚不清楚。在这项工作中,我们提出了一个体外实验系统,类似于肾分化上皮细胞组成的髓管结构,在生理高渗环境中生长和维持,并评估COX2 → PGE2轴(COX2被认为是肾细胞的细胞保护蛋白)是否诱导Oxa损伤或上皮恢复。主要方法smdck细胞在NaCl高渗培养基中分化72 h,细胞获得典型的顶、底外侧膜域和初级纤毛。然后,将培养物用1.5 mM Oxa处理24、48和72 h,以评估上皮单层恢复动力学和cox - pge2效应。soxa将分化表型完全转化为间质表型(上皮-间质转化)。这种效应在48和72 h后分别部分和完全恢复。当COX2被NS398阻断时,Oxa损伤更严重。PGE2的加入恢复了分化上皮的表型,并呈时间和浓度依赖性。这项工作提出了一个实验系统,接近体外和体内肾上皮研究,更重要的是,警告肾结石患者使用非甾体抗炎药。
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