Mark V. Stevens

Parkin is a lipid-responsive regulator of fat uptake in mice and mutant human cells

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.

Cysteine 203 of Cyclophilin D Is Critical for Cyclophilin D Activation of the Mitochondrial Permeability Transition Pore

Background: Cyclophilin D, a known mitochondrial permeability transition pore (mPTP) regulator, is associated with cellular protection. Results: Mutation of cysteine 203 of cyclophilin D inhibits mPTP opening and improves cell viability. Conclusion: Cysteine 203 of cyclophilin D is a critical residue for mPTP activation. Significance: This work provides novel mechanistic insights into mPTP regulation. The mitochondrial permeability transition pore (mPTP) opening plays a critical role in mediating cell death during ischemia/reperfusion (I/R) injury. Our previous studies have shown that cysteine 203 of cyclophilin D (CypD), a critical mPTP mediator, undergoes protein S-nitrosylation (SNO). To investigate the role of cysteine 203 in mPTP activation, we mutated cysteine 203 of CypD to a serine residue (C203S) and determined its effect on mPTP opening. Treatment of WT mouse embryonic fibroblasts (MEFs) with H2O2 resulted in an 50% loss of the mitochondrial calcein fluorescence, suggesting substantial activation of the mPTP. Consistent with the reported role of CypD in mPTP activation, CypD null (CypD−/−) MEFs exhibited significantly less mPTP opening. Addition of a nitric oxide donor, GSNO, to WT but not CypD−/− MEFs prior to H2O2 attenuated mPTP opening. To test whether Cys-203 is required for this protection, we infected CypD−/− MEFs with a C203S-CypD vector. Surprisingly, C203S-CypD reconstituted MEFs were resistant to mPTP opening in the presence or absence of GSNO, suggesting a crucial role for Cys-203 in mPTP activation. To determine whether mutation of C203S-CypD would alter mPTP in vivo, we injected a recombinant adenovirus encoding C203S-CypD or WT CypD into CypD−/− mice via tail vein. Mitochondria isolated from livers of CypD−/− mice or mice expressing C203S-CypD were resistant to Ca2+-induced swelling as compared with WT CypD-reconstituted mice. Our results indicate that the Cys-203 residue of CypD is necessary for redox stress-induced activation of mPTP.

Restricted mitochondrial protein acetylation initiates mitochondrial autophagy

Summary Because nutrient-sensing nuclear and cytosolic acetylation mediates cellular autophagy, we investigated whether mitochondrial acetylation modulates mitochondrial autophagy (mitophagy). Knockdown of GCN5L1, a component of the mitochondrial acetyltransferase machinery, diminished mitochondrial protein acetylation and augmented mitochondrial enrichment of autophagy mediators. This program was disrupted by SIRT3 knockdown. Chronic GCN5L1 depletion increased mitochondrial turnover and reduced mitochondrial protein content and/or mass. In parallel, mitochondria showed blunted respiration and enhanced ‘stress-resilience’. Genetic disruption of autophagy mediators Atg5 and p62 (also known as SQSTM1), as well as GCN5L1 reconstitution, abolished deacetylation-induced mitochondrial autophagy. Interestingly, this program is independent of the mitophagy E3-ligase Parkin (also known as PARK2). Taken together, these data suggest that deacetylation of mitochondrial proteins initiates mitochondrial autophagy in a canonical autophagy-mediator-dependent program and shows that modulation of this regulatory program has ameliorative mitochondrial homeostatic effects.

Transient upregulation of PGC-1α diminishes cardiac ischemia tolerance via upregulation of ANT1

Prolonged cardiac overexpression of the mitochondrial biogenesis regulatory transcriptional coactivator PGC-1alpha disrupts cardiac contractile function and its genetic ablation limits cardiac capacity to enhance workload. In contrast, transient induction of PGC-1alpha alleviates neuronal cell oxidative stress and enhances skeletal myotube anti-oxidant defenses. We explored whether transient upregulation of PGC-1alpha in the heart protects against ischemia-reperfusion injury. The transient induction of PGC-1alpha in the cardiac-restricted inducible PGC-1alpha transgenic mouse, increased PGC-1alpha protein levels 5-fold. Following 25 min of ischemia and 2h of reperfusion on a Langendorff perfusion apparatus, contractile recovery and the rate pressure product was significantly blunted in mice overexpressing PGC-1alpha vs. controls. Affymetrix gene array analysis showed a 3-fold PGC-1alpha-mediated upregulation of adenine nucleotide translocase 1 (ANT1). As ANT1 upregulation induces cardiomyocyte cell death we investigated whether the induction of ANT1 by PGC-1alpha contributes to this enhanced ischemia-stress susceptibility. Infection with adenovirus harboring PGC-1alpha into cardiac-derived H9c2 cells significantly upregulates ANT1 without changing basal cell viability. In response to anoxia-reoxygenation injury cell death is significantly increased following PGC-1alpha overexpression. This detrimental effect is abolished following siRNA knockdown of ANT1. Similarly, the attenuation of ANT-1 in the presence of PGC-1alpha overexpression preserves the mitochondrial membrane potential in response to hydrogen-peroxide stress. Interestingly, the isolated knockdown of ANT1 also protects H9c2 cells from anoxia-reoxygenation injury. Taken together these data suggest that transient induction of PGC-1alpha in the murine heart decreases ischemia-reperfusion contractile recovery and diminishes anoxia-reoxygenation tolerance in H9c2 cells. These adverse phenotypes appear to be mediated, in part, by PGC-1alpha induced upregulation of ANT1.

Parkin regulation of CHOP modulates susceptibility to cardiac endoplasmic reticulum stress

The regulatory control of cardiac endoplasmic reticulum (ER) stress is incompletely characterized. As ER stress signaling upregulates the E3-ubiquitin ligase Parkin, we investigated the role of Parkin in cardiac ER stress. Parkin knockout mice exposed to aortic constriction-induced cardiac pressure-overload or in response to systemic tunicamycin (TM) developed adverse ventricular remodeling with excessive levels of the ER regulatory C/EBP homologous protein CHOP. CHOP was identified as a Parkin substrate and its turnover was Parkin-dose and proteasome-dependent. Parkin depletion in cardiac HL-1 cells increased CHOP levels and enhanced susceptibility to TM-induced cell death. Parkin reconstitution rescued this phenotype and the contribution of excess CHOP to this ER stress injury was confirmed by reduction in TM-induced cell death when CHOP was depleted in Parkin knockdown cardiomyocytes. Isogenic Parkin mutant iPSC-derived cardiomyocytes showed exaggerated ER stress induced CHOP and apoptotic signatures and myocardium from subjects with dilated cardiomyopathy showed excessive Parkin and CHOP induction. This study identifies that Parkin functions to blunt excessive CHOP to prevent maladaptive ER stress-induced cell death and adverse cardiac ventricular remodeling. Additionally, Parkin is identified as a novel post-translational regulatory moderator of CHOP stability and uncovers an additional stress-modifying function of this E3-ubiquitin ligase.

Cysteine 203 of cyclophilin D is critical for cyclophilin D activation of the mitochondrial permeability transition pore (Journal of Biological Chemistry (2011) 286 (40184-40192))

Tiffany T. Nguyen, Mark V. Stevens, Mark Kohr, Charles Steenbergen, Michael N. Sack, and Elizabeth Murphy The CypD cDNA plasmid used in our original manuscript from OriGene included a 62-base pair intronic fragment (Fig. 1). Unfortunately, we did not recognize the problem with this commercial plasmid until after publication of the paper.We evaluatedwhether this residual intron was cleaved during processing following transfection; however, this sequence was retained in the RNA isolated from the transfected mouse embryonic fibroblast (MEF) cells as assessed by RT-PCR with primers targeting the region spanning the 62-base pair insert. This finding is validated where we find that two protein products are generated whetherwe expressed theWTCypDormutated plasmids inMEFs from mice lacking CypD (Fig 2). As shown in Fig. 2, there are no bands in MEFs from the CypD-KO mice (lane 2) and a single band for the WT MEFs (lane 1), but two bands were observed when we expressed either the mutant CypD (lanes 3 and 6) or WT CypD (lane 5). The two bands are at the correct molecular weight for the protein with and without the extra 62 bases, and we usually see a ratio of 7:3 of the lower molecular weight (without the residual intronic sequence) to the higher molecular weight product. To validate the results of our published work, we obtained a new plasmid for the WT CypD, where we confirmed the absence of the intronic region. As done in our article, we then mutated cysteine 203 to a serine residue (C203S). We then sequenced both plasmids to confirm their fidelity (Fig. 1).With the new plasmids, we repeated the key experiments of our paper to validate the results. We expressed theWTCypD and C203S-CypD inMEFs from the CypD / mice. As shown in Fig. 3, typically similar levels ofWTCypD andC203S-CypDwere expressed in CypD / MEFs. The corrected “Results” and figures are shown below.