Uric acid formation is driven by crosstalk between skeletal muscle and other cell types
Spencer G. Miller, Catalina Matias, Paul S. Hafen, Andrew S. Law, Carol A. Witczak, Jeffrey J. Brault
Spencer G. Miller, Catalina Matias, Paul S. Hafen, Andrew S. Law, Carol A. Witczak, Jeffrey J. Brault
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Research Article Metabolism Muscle biology

Uric acid formation is driven by crosstalk between skeletal muscle and other cell types

Abstract

Hyperuricemia is implicated in numerous pathologies, but the mechanisms underlying uric acid production are poorly understood. Using a combination of mouse studies, cell culture studies, and human serum samples, we sought to determine the cellular source of uric acid. In mice, fasting and glucocorticoid treatment increased serum uric acid and uric acid release from ex vivo–incubated skeletal muscle. In vitro, glucocorticoids and the transcription factor FoxO3 increased purine nucleotide degradation and purine release from differentiated muscle cells, which coincided with the transcriptional upregulation of AMP deaminase 3, a rate-limiting enzyme in adenine nucleotide degradation. Heavy isotope tracing during coculture experiments revealed that oxidation of muscle purines to uric acid required their transfer from muscle cells to a cell type that expresses xanthine oxidoreductase, such as endothelial cells. Last, in healthy women, matched for age and body composition, serum uric acid was greater in individuals scoring below average on standard physical function assessments. Together, these studies reveal skeletal muscle purine degradation is an underlying driver of uric acid production, with the final step of uric acid production occurring primarily in a nonmuscle cell type. This suggests that skeletal muscle fiber purine degradation may represent a therapeutic target to reduce serum uric acid and treat numerous pathologies.

Authors

Spencer G. Miller, Catalina Matias, Paul S. Hafen, Andrew S. Law, Carol A. Witczak, Jeffrey J. Brault

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Figure 4

Increased FoxO3 activity is sufficient to induce myotube purine nucleotide degradation and is required for DEX upregulation of AMPD3 promoter activity.

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Increased FoxO3 activity is sufficient to induce myotube purine nucleoti...
C2C12 myotubes were allowed to differentiate for 4 days, then infected with adenovirus encoding a constitutively active FoxO3 isoform (caFoxO3) or GFP for 48 hours. (A) Representative immunofluorescence images after staining for MyHC and nuclei (DAPI). Scale bar, 1,000 μm. (B) Quantification of MyHC area and nuclei count per well. n = 4 wells/group and 6 random images/well. **=P < 0.01. (C) Media concentrations of the purine nucleotide breakdown products hypoxanthine, xanthine, and uric acid. **=P < 0.01 vs. GFP. ND, not detected. (D) Western blots for AMPD3 at 24 hours after GFP and caFoxO3 infection or DEX and S.S. treatments. (E and F) Prior to differentiation, C2C12 myoblasts were transfected with luciferase reporter plasmids containing 1 Kb of the AMPD3 proximal promoter region, with or without substitution mutations in the consensus FoxO binding site (ΔFoxO Mutant). (E) AMPD3 promoter activity measured 24 hours after GFP or caFoxO3 infection. One-way ANOVA, Tukey’s multiple comparisons. ***=P < 0.0001. (F) AMPD3 promoter activity after 24 hours’ treatment with 100 μM DEX and/or S.S. *=P < 0.05 vs. Veh, =P < 0.05 S.S.+DEX vs. DEX. Two-way ANOVA, Tukey’s multiple comparisons.