Parkin is a lipid-responsive regulator of fat uptake in mice and mutant human cells
Kye-Young Kim, … , Alan T. Remaley, Michael N. Sack
Kye-Young Kim, … , Alan T. Remaley, Michael N. Sack
Published August 25, 2011
Citation Information: J Clin Invest. 2011;121(9):3701-3712. https://doi.org/10.1172/JCI44736.
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Parkin is a lipid-responsive regulator of fat uptake in mice and mutant human cells

Abstract

It has long been hypothesized that abnormalities in lipid biology contribute to degenerative brain diseases. Consistent with this, emerging epidemiologic evidence links lipid alterations with Parkinson disease (PD), and disruption of lipid metabolism has been found to predispose to α-synuclein toxicity. We therefore investigated whether Parkin, an E3 ubiquitin ligase found to be defective in patients with early onset PD, regulates systemic lipid metabolism. We perturbed lipid levels by exposing Parkin+/+ and Parkin–/– mice to a high-fat and -cholesterol diet (HFD). Parkin–/– mice resisted weight gain, steatohepatitis, and insulin resistance. In wild-type mice, the HFD markedly increased hepatic Parkin levels in parallel with lipid transport proteins, including CD36, Sr-B1, and FABP. These lipid transport proteins were not induced in Parkin–/– mice. The role of Parkin in fat uptake was confirmed by increased oleate accumulation in hepatocytes overexpressing Parkin and decreased uptake in Parkin–/– mouse embryonic fibroblasts and patient cells harboring complex heterozygous mutations in the Parkin-encoding gene PARK2. Parkin conferred this effect, in part, via ubiquitin-mediated stabilization of the lipid transporter CD36. Reconstitution of Parkin restored hepatic fat uptake and CD36 levels in Parkin–/– mice, and Parkin augmented fat accumulation during adipocyte differentiation. These results demonstrate that Parkin is regulated in a lipid-dependent manner and modulates systemic fat uptake via ubiquitin ligase–dependent effects. Whether this metabolic regulation contributes to premature Parkinsonism warrants investigation.

Authors

Kye-Young Kim, Mark V. Stevens, M. Hasina Akter, Sarah E. Rusk, Robert J. Huang, Alexandra Cohen, Audrey Noguchi, Danielle Springer, Alexander V. Bocharov, Tomas L. Eggerman, Der-Fen Suen, Richard J. Youle, Marcelo Amar, Alan T. Remaley, Michael N. Sack

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Figure 5

Parkin regulates posttranslational modification of CD36.

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Parkin regulates posttranslational modification of CD36. (A) Expression ...
(A) Expression levels of Parkin and lipid uptake (CD36 and Sr-B1) and transport (L-FABP) proteins in response to the ND and HFD in liver tissue by immunoblot analysis. (B) Protein expression of Parkin and lipid uptake and transport proteins in response to the ND and HFD in whole brain tissue by immunoblot analysis. (C) Degradation of CD36 protein following CHX administration in the presence or absence of Parkin overexpression in HeLa cells engineered to overexpress CD36. (D) CD36 protein expression in response to oleic acid administration following overexpression of Parkin or control vector. (E) Interaction between Parkin and CD36. CD36-overexpressing HeLa cells were transfected with p3×Flag vector or p3×Flag-Parkin, respectively. After 48 hours transfection, protein extracts were IP with anti-Flag M2 agarose (IP:α-Flag). (F) Ubiquitination of CD36 following IP of an HA antibody and immunoblot analysis for CD36. CD36-overexpressing HeLa cells were transfected with HA-Ubiquitin and/or Parkin. (G) Ubiquitination of CD36 following IP with a CD36 antibody and immunoblot analysis for HA following the transfection of HA-Ubiquitin and/or Parkin in the CD36-overexpressing HeLa cells. All studies were performed in duplicate, and at least 3 independent experiments were performed.