Project description:Parkin expression is persistently increased in TIGAR-deficient (TKO) mouse hearts, even after restoration of TIGAR expression in adulthood, suggesting a developmental epigenetic mechanism. To investigate whether DNA methylation contributes to this regulation, we performed whole-genome bisulfite sequencing (WGBS) on cardiac tissues from wild-type and TKO mice. RNA sequencing confirmed increased Parkin transcript levels across all exons in TKO hearts. WGBS analysis identified multiple differentially methylated regions (DMRs) across the Parkin gene body, with consistently lower methylation levels in TKO hearts. A prominent hypomethylated region was detected within intron 10, while no significant methylation changes were observed in the Parkin promoter CpG island. These data suggest that TIGAR deficiency is associated with stable, gene body–specific DNA methylation changes that correlate with increased Parkin expression.

Project description:High-fat diet (HFD) is known to promote metabolic stress and cardiac dysfunction. To examine genotype-dependent cardiac transcriptional responses, we performed RNA sequencing of hearts from wild-type (WT) and TKO mice fed either normal chow (NC) or a high-fat diet. RNA-seq analysis revealed significantly increased Parkin (Prkn) mRNA expression in TKO hearts compared with WT hearts under HFD conditions.

Project description:DNA methylation analysis of the Parkin gene in wild-type and TIGAR-deficient mouse tissues [EM-seq]

Project description:DNA methylation analysis of the Parkin gene in wild-type and TIGAR-deficient mouse tissues [Bisulfite-seq]

Project description:Dysfunctional Parkin-mediated mitophagic culling of senescent or damaged mitochondria is a major pathological process underlying Parkinson disease and a potential genetic mechanism of cardiomyopathy. Despite epidemiological associations between Parkinson disease and heart failure, the role of Parkin and mitophagic quality control in maintaining normal cardiac homeostasis is poorly understood.We used germline mutants and cardiac-specific RNA interference to interrogate Parkin regulation of cardiomyocyte mitochondria and examine functional crosstalk between mitophagy and mitochondrial dynamics in Drosophila heart tubes. 5 wild-type mouse hearts; 4 germline Parkin knockout mouse hearts Please note that the mouse cardiac examples were an adjunct to the Drosophila studies that comprised most of the associated publication. However, mRNA-sequencing was only performed on the mouse samples, not the Drosophila heart tubes.

Project description:Adult mice bearing homozygous floxed Parkin alleles (PMIDs 15249681, 21376232; T M Dawson), with or without the Myh6-driven MERCreMER transgene, were administered tamoxifen at 6-10 wks of age. Tissues were obtained from euthanized mice 9-10 weeks after tamoxifen induction. 6 floxed, non-Cre (noninduced) mouse hearts; 6 floxed, MERCreMer, adult-induced, Parkin knockout mouse hearts

Project description:Exclusion of Parkin from mitochondria of perinatal cardiomyocytes interrupts structural and molecular transformations essential to normal perinatal-adult mitochondrial replacement. mRNA-sequencing from cardiac total RNA was performed at P1, P21 and 5-week stages of nontransgenic (ntg) and human-Mfn2-overexpressing (Mfn2wt) hearts, and also of tet-off control (tetoff) and human-Mfn2 T111A/S442A-overexpressing (Mfn2AA) hearts.

Project description:We identified that global TIGAR deficiency inhibited VSMC dedifferentiation. The purpose of this experiment was to identify how TIGAR inhibited VSMC dedifferentiation.We then performed gene expression profiling analysis using data obtained from RNA-seq of VSMC from WT and TIGAR KO mice stimulated with LPS.

Project description:We identified that global TIGAR deficiency reduced the AS plaque formation and the systemic inflammatory response. The purpose of this experiment was to identify how TIGAR induces macrophage inflammation.We then performed gene expression profiling analysis using data obtained from RNA-seq of bone marrow derived macrophages from WT and TIGAR KO mice stimulated with LPS.

Project description:Epigenetic and metabolic reprogrammings are implicated in cancer progression with unclear mechanisms. We report here that the histone methyltransferase NSD2 drives cancer cell and tumor resistance to therapeutics such as tamoxifen, doxorubicin, and radiation by reprogramming of glucose metabolism. NSD2 coordinately up-regulates expression of TIGAR, HK2 and G6PD and stimulates pentose phosphate pathway (PPP) production of NADPH for ROS reduction. We discover that elevated expression of TIGAR, previously characterized as a fructose-2,6-bisphosphatase, is localized in the nuclei of resistant tumor cells where it stimulates NSD2 expression and global H3K36me2 mark. Mechanistically, TIGAR interacts with the antioxidant regulator Nrf2 and facilitates chromatin assembly of Nrf2-H3K4me3 methylase MLL1 and elongating Pol-II, independent of its metabolic enzymatic activity. In human tumors, high levels of NSD2 correlate strongly with early recurrence and poor survival and are associated with nuclear-localized TIGAR. This study defines a nuclear TIGAR-mediated, epigenetic autoregulatory loop functioning in redox rebalance for resistance to tumor therapeutics.