Hepatic HIF2 is a key determinant of manganese excess and polycythemia in SLC30A10 deficiency
Milankumar Prajapati, … , Mariam Aghajan, Thomas B. Bartnikas
Milankumar Prajapati, … , Mariam Aghajan, Thomas B. Bartnikas
Published April 23, 2024
Citation Information: JCI Insight. 2024;9(10):e169738. https://doi.org/10.1172/jci.insight.169738.
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Research Article Genetics Hepatology

Hepatic HIF2 is a key determinant of manganese excess and polycythemia in SLC30A10 deficiency

Abstract

Manganese is an essential yet potentially toxic metal. Initially reported in 2012, mutations in SLC30A10 are the first known inherited cause of manganese excess. SLC30A10 is an apical membrane protein that exports manganese from hepatocytes into bile and from enterocytes into the lumen of the gastrointestinal tract. SLC30A10 deficiency results in impaired gastrointestinal manganese excretion, leading to manganese excess, neurologic deficits, liver cirrhosis, polycythemia, and erythropoietin excess. Neurologic and liver disease are attributed to manganese toxicity. Polycythemia is attributed to erythropoietin excess. The goal of this study was to determine the basis of erythropoietin excess in SLC30A10 deficiency. Here, we demonstrate that transcription factors hypoxia-inducible factor 1a (Hif1a) and 2a (Hif2a), key mediators of the cellular response to hypoxia, are both upregulated in livers of Slc30a10-deficient mice. Hepatic Hif2a deficiency corrected erythropoietin expression and polycythemia and attenuated aberrant hepatic gene expression in Slc30a10-deficient mice, while hepatic Hif1a deficiency had no discernible impact. Hepatic Hif2a deficiency also attenuated manganese excess, though the underlying cause of this is not clear at this time. Overall, our results indicate that hepatic HIF2 is a key determinant of pathophysiology in SLC30A10 deficiency and expand our understanding of the contribution of HIFs to human disease.

Authors

Milankumar Prajapati, Jared Z. Zhang, Lauren Chiu, Grace S. Chong, Courtney J. Mercadante, Heather L. Kowalski, Bradley Delaney, Jessica A. Anderson, Shuling Guo, Mariam Aghajan, Thomas B. Bartnikas

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Figure 1

Slc30a10–/– mice develop Mn-dependent Epo excess and polycythemia.

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Slc30a10–/– mice develop Mn-dependent Epo excess and polycythemia. (A a...
(A and B) Two-month-old Slc30a10+/+ and Slc30a10–/– mice were analyzed for serum Epo levels by ELISA (A) and kidney and liver Epo RNA levels by quantitative PCR (qPCR) (B). (CE) Livers from 2-month-old Slc30a10+/+ and Slc30a10–/– mice were analyzed by PCR array for hypoxia-regulated genes up- (blue) or down- (red) regulated at least 2-fold (C and D), followed by qPCR validation of the top 3 differentially regulated genes besides Epo (E). (F) Two-month-old Slc30a10+/+ and Slc30a10–/– mice were analyzed for liver cobalt levels by graphite furnace atomic absorption spectroscopy (GFAAS). (GI) Slc30a10+/+ and Slc30a10–/– mice were weaned onto Mn-sufficient (100 ppm) or -deficient (1 ppm) diets, then analyzed at 6 weeks for liver Mn levels by inductively coupled plasma optical emission spectroscopy (ICP-OES) (G), for liver Epo RNA levels by qPCR (H), and for RBC counts by complete blood counts (I). Data are represented as means ± standard deviation, with at least 4 animals per group, except for C and D where 3 mice were used. Data were tested for normal distribution by Shapiro-Wilk test; if not normally distributed, data were log-transformed. Within each sex, groups were compared using unpaired, 2-tailed t tests (A, B, E, and F) or 2-way ANOVA with Tukey’s multiple comparisons test (GI). (* P < 0.05, ** P < 0.01, *** P < 0.001, **** P < 0.0001.)