Novel Dent disease 1 cellular models reveal biological processes underlying ClC-5 loss-of-function.

Mónica Durán, Carla Burballa, Gerard Cantero-Recasens, Cristian M Butnaru, Vivek Malhotra, Gema Ariceta, Eduard Sarró, Anna Meseguer

Human molecular genetics 2021 Jul 09

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Dent disease 1 (DD1) is a rare X-linked renal proximal tubulopathy characterized by low molecular weight proteinuria and variable degree of hypercalciuria, nephrocalcinosis and/or nephrolithiasis, progressing to chronic kidney disease. Although mutations in the electrogenic Cl-/H+ antiporter ClC-5, which impair endocytic uptake in proximal tubule cells, cause the disease, there is poor genotype-phenotype correlation and their contribution to proximal tubule dysfunction remains unclear. To further discover the mechanisms linking ClC-5 loss-of-function to proximal tubule dysfunction, we have generated novel DD1 cellular models depleted of ClC-5 and carrying ClC-5 mutants p.(Val523del), p.(Glu527Asp) and p.(Ile524Lys) using the human proximal tubule-derived RPTEC/TERT1 cell line. Our DD1 cellular models exhibit impaired albumin endocytosis, increased substrate adhesion and decreased collective migration, correlating with a less differentiated epithelial phenotype. Despite sharing functional features, these DD1 cell models exhibit different gene expression profiles, being p.(Val523del) ClC-5 the mutation showing the largest differences. Gene set enrichment analysis pointed to kidney development, anion homeostasis, organic acid transport, extracellular matrix organization and cell-migration biological processes as the most likely involved in DD1 pathophysiology. In conclusion, our results revealed the pathways linking ClC-5 mutations with tubular dysfunction and, importantly, provide new cellular models to further study DD1 pathophysiology. © The Author(s) 2021. Published by Oxford University Press.

Citation

Mónica Durán, Carla Burballa, Gerard Cantero-Recasens, Cristian M Butnaru, Vivek Malhotra, Gema Ariceta, Eduard Sarró, Anna Meseguer. Novel Dent disease 1 cellular models reveal biological processes underlying ClC-5 loss-of-function. Human molecular genetics. 2021 Jul 09;30(15):1413-1428