BackgroundGlutathione S-transferases (GSTs) metabolize drugs and xenobiotics. Yet despite high protein sequence homology, expression of π-class GSTs, the most abundant of the enzymes, varies significantly between species. In mouse liver, hepatocytes exhibit high mGstp expression, while in human liver, hepatocytes contain little or no hGSTP1 mRNA or hGSTP1 protein. π-class GSTs are known to be critical determinants of liver responses to drugs and toxins: when treated with high doses of acetaminophen, mGstp1/2+/+ mice suffer marked liver damage, while mGstp1/2−/− mice escape liver injury.Methodology/Principal FindingsTo more faithfully model the contribution of π-class GSTs to human liver toxicology, we introduced hGSTP1, with its exons, introns, and flanking sequences, into the germline of mice carrying disrupted mGstp genes. In the resultant hGSTP1+mGstp1/2−/− strain, π-class GSTs were regulated differently than in wild-type mice. In the liver, enzyme expression was restricted to bile duct cells, Kupffer cells, macrophages, and endothelial cells, reminiscent of human liver, while in the prostate, enzyme production was limited to basal epithelial cells, reminiscent of human prostate. The human patterns of hGSTP1 transgene regulation were accompanied by human patterns of DNA methylation, with bisulfite genomic sequencing revealing establishment of an unmethylated CpG island sequence encompassing the gene promoter. Unlike wild-type or mGstp1/2−/− mice, when hGSTP1+mGstp1/2−/− mice were overdosed with acetaminophen, liver tissues showed limited centrilobular necrosis, suggesting that π-class GSTs may be critical determinants of toxin-induced hepatocyte injury even when not expressed by hepatocytes.ConclusionsBy recapitulating human π-class GST expression, hGSTP1+mGstp1/2−/− mice may better model human drug and xenobiotic toxicology.
DNA hypermethylation can trigger silencing of tumor suppressor genes during cancer development and progression, partly through binding by methylated-DNA binding proteins (MBD), such as MBD2, that function as “epigenetic readers” and recruit co-repressor complexes to promote gene repression. Inhibiting MBD2-mediated repression represents an attractive cancer therapeutic strategy. Here, we used a cell-based screen to identify small molecules capable of reactivating hypermethylated promoter sequences. We used biochemical, molecular biologic, and pharmacologic approaches to characterize mechanism of action of identified MBD2 inhibitors. A subset of these compounds represent a new class of inhibitors capable of selectively antagonizing interactions between MBD2 and methylated DNA, leading to reactivation of the hypermethylated gene GSTP1 and the epigenetically silenced retinoic acid signaling pathway. Combinations of one of the newly identified MBD2 inhibitors, KCC-08, with the retinoic acid receptor agonist, isotretinoin, significantly reduced cancer cell growth/survival in vitro and in vivo. These novel MBD2 inhibitors are thus positioned for further pharmacologic lead development for use as probes to interrogate epigenetic gene silencing mechanisms and as cancer therapeutics. Citation Format: Hugh Giovinazzo, Zachary R. Reichert, Andries Bergman, Xiaohui Lin, Nicolas Wyhs, David Esopi, Ajay Vaghasia, Jianyong Liu, Yash Jain, Akshay Bhamidipati, Ruchama Steinberg, Traci Speed, Matthew Vaughn, Yonggang Zhang, Nate Brennen, Theodore Deweese, Srinivasan Yegnasubramanian, William G. Nelson. Novel inhibitors of the epigenetic reader protein MBD2 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 5881.
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