Small-molecule inhibitor of intestinal anion exchanger SLC26A3 for treatment of hyperoxaluria and nephrolithiasis
Onur Cil, … , Peter M. Haggie, Alan S. Verkman
Onur Cil, … , Peter M. Haggie, Alan S. Verkman
Published May 24, 2022
Citation Information: JCI Insight. 2022;7(13):e153359. https://doi.org/10.1172/jci.insight.153359.
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Research Article Nephrology Therapeutics

Small-molecule inhibitor of intestinal anion exchanger SLC26A3 for treatment of hyperoxaluria and nephrolithiasis

Abstract

Nephrolithiasis is a common and recurrent disease affecting 9% of the US population. Hyperoxaluria is major risk factor for calcium oxalate kidney stones, which constitute two-thirds of all kidney stones. SLC26A3 (DRA, downregulated in adenoma) is an anion exchanger of chloride, bicarbonate, and oxalate thought to facilitate intestinal oxalate absorption, as evidenced by approximately 70% reduced urine oxalate excretion in knockout mice. We previously identified a small-molecule SLC26A3 inhibitor (DRAinh-A270) that selectively inhibited SLC26A3-mediated chloride/bicarbonate exchange (IC50 ~ 35 nM) and, as found here, oxalate/chloride exchange (IC50 ~ 60 nM). In colonic closed loops in mice, luminal DRAinh-A270 inhibited oxalate absorption by 70%. Following oral sodium oxalate loading in mice, DRAinh-A270 largely prevented the 2.5-fold increase in urine oxalate/creatinine ratio. In a mouse model of oxalate nephropathy produced by a high-oxalate low-calcium diet, vehicle-treated mice developed marked hyperoxaluria with elevated serum creatinine, renal calcium oxalate crystal deposition, and renal injury, which were largely prevented by DRAinh-A270 (10 mg/kg twice daily). DRAinh-A270 administered over 7 days to healthy mice did not show significant toxicity. Our findings support a major role of SLC26A3 in intestinal oxalate absorption and suggest the therapeutic utility of SLC26A3 inhibition for treatment of hyperoxaluria and prevention of calcium oxalate nephrolithiasis.

Authors

Onur Cil, Tifany Chu, Sujin Lee, Peter M. Haggie, Alan S. Verkman

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Figure 1

DRAinh-A270 inhibits SLC26A3-mediated oxalate transport.

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DRAinh-A270 inhibits SLC26A3-mediated oxalate transport. (A) Chemical st...
(A) Chemical structure of DRAinh-A270. (B) Oxalate/chloride exchange assay (left). Extracellularly added oxalate drives oxalate/chloride exchange and the consequent increase in YFP fluorescence (reduced quenching of cytoplasmic YFP by chloride). Representative curves of YFP fluorescence over time in FRT cells expressing SLC26A3 treated with indicated concentrations of DRAinh-A270, with FRT-null cells shown as control (right). Dashed lines denote deduced initial slopes. (C) Concentration-dependent inhibition of SLC26A3-mediated Cl/oxalate exchange by DRAinh-A270. Mean ± SEM, n = 4–8 wells per concentration. (D) The inset shows a schematic of oxalate transport assay in FRT cells grown on permeable filters, with basolateral-to-apical oxalate gradient (500 μM oxalate in the basolateral solution and 0 oxalate in the apical solution). Oxalate transport rate is plotted for studies done in FRT cells expressing SLC26A3 (FRT-A3) pretreated with indicated concentrations of DRAinh-A270 (or DMSO control) for 15 minutes before application of the oxalate gradient. FRT cells not expressing SLC26A3 (FRT-null cells) are shown as controls. Mean ± SEM, n = 6–12 wells per condition. One-way ANOVA with post hoc Newman-Keuls multiple comparisons test; **P < 0.01.