Urolithiasis and hepatotoxicity are linked to the anion transporter Sat1 in mice
Paul A. Dawson, … , Lorne A. Clarke, Daniel Markovich
Paul A. Dawson, … , Lorne A. Clarke, Daniel Markovich
Published February 15, 2010
Citation Information: J Clin Invest. 2010;120(3):706-712. https://doi.org/10.1172/JCI31474.
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Research Article Nephrology

Urolithiasis and hepatotoxicity are linked to the anion transporter Sat1 in mice

Abstract

Urolithiasis, a condition in which stones are present in the urinary system, including the kidneys and bladder, is a poorly understood yet common disorder worldwide that leads to significant health care costs, morbidity, and work loss. Acetaminophen-induced liver damage is a major cause of death in patients with acute liver failure. Kidney and urinary stones and liver toxicity are disturbances linked to alterations in oxalate and sulfate homeostasis, respectively. The sulfate anion transporter–1 (Sat1; also known as Slc26a1) mediates epithelial transport of oxalate and sulfate, and its localization in the kidney, liver, and intestine suggests that it may play a role in oxalate and sulfate homeostasis. To determine the physiological roles of Sat1, we created Sat1–/– mice by gene disruption. These mice exhibited hyperoxaluria with hyperoxalemia, nephrocalcinosis, and calcium oxalate stones in their renal tubules and bladder. Sat1–/– mice also displayed hypersulfaturia, hyposulfatemia, and enhanced acetaminophen-induced liver toxicity. These data suggest that Sat1 regulates both oxalate and sulfate homeostasis and may be critical to the development of calcium oxalate urolithiasis and hepatotoxicity.

Authors

Paul A. Dawson, Christopher S. Russell, Soohyun Lee, Sarah C. McLeay, Jacobus M. van Dongen, David M. Cowley, Lorne A. Clarke, Daniel Markovich

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Figure 1

Targeted disruption of Sat1.

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Targeted disruption of Sat1. (A) Sat1 targeting strategy. Exons (box...
(A) Sat1 targeting strategy. Exons (boxes 1–4), restriction sites, probes, and primers P1–P5 are shown. NeoR, neomycin resistance sequence; TK, thymidine kinase sequence. (B) Southern analysis of Hind III– and Not I–digested DNA from Sat1+/+, Sat1+/–, and Sat1–/– mice. Probe A detected 9.9-kb wild-type and 5.2-kb targeted allele fragments. (C) Southern analysis of Bcl I–digested DNA from Sat1+/+, Sat1+/–, and Sat1–/– mice. The neoR probe detected a single 4.7-kb fragment in Sat1+/– and Sat1–/– mice. (D) Forward (P4) and reverse (P5) primers amplified an 8.9-kb product in DNA samples from Sat1+/– and Sat1–/– mice. M, molecular mass ladder; Neg, negative control. (E) Primers P1 and P2 amplified a 0.5-kb wild-type fragment; P1 and P3 amplified a 0.4-kb targeted allele fragment. (F) Selective disruption of the Sat1 gene located on the opposite strand within the Idua gene. Sat1 exons (white boxes 1–4), Idua exons (black boxes 1–14), primers P6 and P7, and neomycin resistance sequence are shown.