Objectives Increased availability of high-calorie palatable food in most countries has resulted in overconsumption of these foods, suggesting that excessive eating is driven by pleasure, rather than metabolic need. The behavior contributes to the rise in eating disorders, obesity, and associated pathologies like diabetes, cardiac disease, and cancers. The mesocorticolimbic dopamine and homeostatic circuits are interconnected and play a central role in palatable food intake. The endocannabinoid system is expressed in these circuits and represents a potent regulator of feeding, but the impact of an obesogenic diet on its expression is not fully known. Methods Food intake and body weight were recorded in male Wistar rats over a 6-week free-choice regimen of high fat and sugar; transcriptional regulations of the endocannabinoid system were examined post-mortem in brain reward regions (prefrontal cortex, nucleus accumbens, ventral tegmental area, and arcuate nucleus). K-means cluster analysis was used to classify animals based on individual sensitivity to obesity and palatable food intake. Endocannabinoid levels were quantified in the prefrontal cortex and nucleus accumbens. Gene expression in dopamine and homeostatic systems, including ghrelin and leptin receptors, and classical homeostatic peptides, were also investigated. ResultsThe free-choice high-fat -and sugar diet induced hyperphagia and obesity in rats. Cluster analysis revealed that the propensity to develop obesity and excessive palatable food intake was differently associated with dopamine and endocannabinoid system gene expression in reward and homeostatic brain regions. CB2 receptor mRNA was increased in the nucleus accumbens of high sugar consumers, whereas CB1 receptor mRNA was decreased in obesity prone rats. Conclusions Transcriptional data are consistent with observations of altered dopamine function in rodents that have access to an obesogenic diet and point to cannabinoid receptors as GPCR targets involved in neuroplasticity mechanisms associated with maladaptive intake of palatable food.
3263 Introduction Sickle cell disease and beta thalassemia are disorders caused by mutations in adult hemoglobin (HbA) or defects in HbA expression. A potential therapeutic solution is reactivation of fetal hemoglobin (HbF) expression. Although HbF, comprising two alpha and two gamma globin chains, is the primary form of hemoglobin expressed in utero, gamma globin expression is silenced in adults. One proposed mechanism of gamma globin silencing involves binding of the direct repeat erythroid definitive (DRED) repressor complex to sequences in the gamma globin promoter. The DRED complex is reported to include the orphan nuclear hormone receptors TR2 and TR4, lysine specific demethylase (LSD1) and DNA methyltransferase (DNMT1). As both LSD1 and DNMT1 are epigenetic modifiers, gamma globin repression is proposed to be mediated by LSD1- and DNMT1-induced epigenetic changes. To investigate the role of DNMT1 and LSD1 in HbF silencing, HbF expression was evaluated in an erythroid differentiation model where hematopoietic progenitor cells were treated with either DNMT1 or LSD1 small molecule inhibitors or siRNA. Methods Human hematopoietic progenitor cells from healthy donors were induced to become erythroid using a two step protocol including erythropoietin, SCF, IL-3 and hydrocortisone for days 1–7 and erythropoietin and SCF for days 8–14. Cultures were treated with a range of concentrations of either tranylcypromine or S2101 (LSD1 inhibitors) or 5-azacytidine (DNMT1 inhibitor) and compared to HbF-inducing, positive control small molecules pomalidomide and lenalidomide. Cultures were also treated with LSD1 siRNAs and compared to controls. The effect of treatment on gamma, beta and alpha globin transcription was determined by qRT-PCR. The effect of treatment on HbA and HbF levels was determined by ELISA, HPLC, flow cytometry and imaging. Differentiation was characterized by morphology and flow-based detection of CD34 and glycophorin. Effects on viability were characterized by ViCell and flow cytometry. Results Treatment with a concentration range of 5-azacytidine increased the rate of red blood cell differentiation as measured by daily changes in CD34 and glycophorin and hemoglobinization. Quantitative ELISA demonstrated that HbF expression increased two-fold. In contrast, LSD1 inhibition reduced both the rate of proliferation and differentiation of erythroid progenitors. Consistent with impaired differentiation, both beta globin transcription and HbA expression were reduced by up to 84% (qRT-PCR) and 65% (quantitative ELISA), respectively. No increase in gamma globin transcription or HbF expression was observed in response to LSD1 inhibition. Control cultures differentiated as expected: after 14 days of treatment the majority of vehicle-, lenalidomide- or pomalidomide-treated cells were glycophorin-positive and enucleation was readily apparent. Both lenalidomide and pomalidomide treatment induced a two-fold increase in HbF expression, as previously reported. Conclusions Although both LSD1 and DNMT1 are reported to be components of the DRED complex and are proposed to be jointly responsible for epigenetically modifying the gamma globin promoter to silence HbF expression, inhibition of the two proteins had different outcomes on HbF expression. DNMT1 inhibition upregulated HbF expression to a similar extent as pomalidomide (currently in Phase 1 clinical trials for HbF induction), whereas LSD1 inhibition impaired erythroid differentiation and hemoglobinization. These results suggest that the mechanism of gamma globin silencing and the proposed role of the DRED complex require further evaluation. Furthermore, this work also suggests that LSD1 inhibition is not a therapeutic strategy for HbF induction in patients with sickle cell disease or beta thalassemia. Disclosures: Arvedson: Amgen: Employment. Tran:Amgen: Employment. Ross:Amgen: Employment. Yoder:Amgen: Employment. Hertz:Amgen: Employment. Hale:Amgen: Employment. Eschelbach:Amgen: Employment. Dineen:Amgen: Employment. Matyas:Amgen: Employment. Hartley:Amgen: Employment. Morgenstern:Amgen: Employment. Winters:Amgen: Employment. Cindy:Amgen: Employment. Molineux:Amgen: Employment. Coxon:Amgen: Employment.
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