Abstract
AbstractBackgroundtheKCNJ16gene has been associated with a novel kidney tubulopathy phenotype,viz.disturbed acid-base homeostasis, hypokalemia and altered renal salt transport.KCNJ16encodes for Kir5.1, which together with Kir4.1 constitutes a potassium channel located at kidney tubular cell basolateral membranes. Preclinical studies provided mechanistical links between Kir5.1 and a disease phenotype, however, the disease pathology remains poorly understood. Here, we aimed at generating and characterizing a novel advancedin vitrohuman kidney model that recapitulates the disease phenotype to investigate further the pathophysiological mechanisms underlying the disease and potential therapeutic interventions.Methodswe used CRISPR/Cas9 to generateKCNJ16mutant (KCNJ16+/-andKCNJ16-/-) cell lines from healthy human induced pluripotent stem cells (iPSC)KCNJ16control (KCNJ16WT). The iPSCs were differentiated following an optimized protocol into kidney organoids in an air-liquid interface.ResultsKCNJ16-depleted kidney organoids showed transcriptomic and potential functional impairment of key voltage-dependent electrolyte and water-balance transporters. We observed cysts formation, lipid droplet accumulation and fibrosis upon Kir5.1 function loss. Furthermore, a large scale, glutamine tracer flux metabolomics analysis demonstrated thatKCNJ16-/-organoids display TCA cycle and lipid metabolism impairments. Drug screening revealed that treatment with statins, particularly the combination of simvastatin and C75, prevented lipid droplet accumulation and collagen-I deposition inKCNJ16-/-kidney organoids.Conclusionsmature kidney organoids represent a relevantin vitromodel for investigating the function of Kir5.1. We discovered novel molecular targets for this genetic tubulopathy and identified statins as a potential therapeutic strategy forKCNJ16defects in the kidney.Significance StatementIn this study, the use of CRISPR/Cas9 technology resulted in the establishment of aKCNJ16-depleted kidney organoid model, instrumental in elucidating the pathophysiology of the recently reportedKCNJ16-associated kidney tubulopathy. Our study substantiates the role of Kir5.1 (KCNJ16) in kidney disease, confirming already described phenotypes, as well as aiding to gain insight in the causal role of Kir5.1 loss in the disease phenotype. Our approach increases the knowledge onKCNJ16-related kidney phenotype, and it states the importance of combining CRISPR/Cas9 technology and advancedin vitromodels for complex disease modeling and therapy testing. Furthermore, we encourage the application of our approach to thein vitromodeling of rare and/or underrepresented genetic kidney diseases, for which the availability of patient material is limited.
Publisher
Cold Spring Harbor Laboratory