DNA methylation of specific CpG sites in the promoter region regulates the transcription of the mouse oxytocin receptor.

Oxytocin is a peptide hormone, well known for its role in labor and suckling, and most recently for its involvement in mammalian social behavior. All central and peripheral actions of oxytocin are mediated through the oxytocin receptor, which is the product of a single gene. Transcription of the oxytocin receptor is subject to regulation by gonadal steroid hormones, and is profoundly elevated in the uterus and mammary glands during parturition. DNA methylation is a major epigenetic mechanism that regulates gene transcription, and has been linked to reduced expression of the oxytocin receptor in individuals with autism. Here, we hypothesized that transcription of the mouse oxytocin receptor is regulated by DNA methylation of specific sites in its promoter, in a tissue-specific manner. Hypothalamus-derived GT1-7, and mammary-derived 4T1 murine cell lines displayed negative correlations between oxytocin receptor transcription and methylation of the gene promoter, and demethylation caused a significant enhancement of oxytocin receptor transcription in 4T1 cells. Using a reporter gene assay, we showed that methylation of specific sites in the gene promoter, including an estrogen response element, significantly inhibits transcription. Furthermore, methylation of the oxytocin receptor promoter was found to be differentially correlated with oxytocin receptor expression in mammary glands and the uterus of virgin and post-partum mice, suggesting that it plays a distinct role in oxytocin receptor transcription among tissues and under different physiological conditions. Together, these results support the hypothesis that the expression of the mouse oxytocin receptor gene is epigenetically regulated by DNA methylation of its promoter.

The contribution of oxytocin and vasopressin to mammalian social behavior: potential role in autism spectrum disorder.

Oxytocin (OT) and arginine-vasopressin (AVP) are 2 peptides that are produced in the brain and released via the pituitary gland to the peripheral blood, where they have diverse physiological functions. In the last 2 decades it has become clear that these peptides also play a central role in the modulation of mammalian social behavior by their actions within the brain. Several lines of evidence suggest their involvement in autism spectrum disorder (ASD), which is known to be associated with impaired social cognition and behavior. Recent clinical trials using OT administration to autistic patients have reported promising results. Here, we aim to describe the main data that suggest a connection between these peptides and ASD. Following a short illustration of several major topics in ASD biology we will (a) briefly describe the oxytocinergic and vasopressinergic systems in the brain, (b) discuss a few compelling cases manifesting the involvement of OT and AVP in mammalian social behavior, (c) describe data supporting the role of these peptides in human social cognition and behavior, and (d) discuss the possibility of the involvement of OT and AVP in ASD etiology, as well as the prospect of using these peptides as a treatment for ASD patients.

What do unicellular organisms teach us about DNA methylation?

DNA methylation is an epigenetic hallmark that has been studied intensively in mammals and plants. However, knowledge of this phenomenon in unicellular organisms is scanty. Examining epigenetic regulation, and more specifically DNA methylation, in these organisms represents a unique opportunity to better understand their biology. The determination of their methylation status is often complicated by the presence of several differentiation stages in their life cycle. This article focuses on some recent advances that have revealed the unexpected nature of the epigenetic determinants present in protozoa. The role of the enigmatic DNA methyltransferase Dnmt2 in unicellular organisms is discussed.

Sensing DNA methylation in the protozoan parasite Entamoeba histolytica.

In the protozoan parasite Entamoeba histolytica, 5-methylcytosine (m5C) was found predominantly in repetitive elements. Its formation is catalysed by Ehmeth, a DNA methyltransferase that belongs to the Dnmt2 subfamily. Here we describe a 32 kDa nuclear protein that binds in vitro with higher affinity to the methylated form of a DNA encoding a reverse transcriptase of an autonomous non-long-terminal repeat retrotransposon (RT LINE) compared with the non-methylated RT LINE. This protein, named E. histolytica-methylated LINE binding protein (EhMLBP), was purified from E. histolytica nuclear lysate, identified by mass spectrometry, and its corresponding gene was cloned. EhMLBP corresponds to a gene of unknown function that shares strong homology with putative proteins present in Entamoeba dispar and Entamoeba invadens. In contrast, the homology dropped dramatically when non-Entamoebidae sequences were considered and only a weak sequence identity was found with Trypanosoma and several prokaryotic histone H1. Recombinant EhMLBP showed the same binding preference for methylated RT LINE as the endogenous EhMLBP. Deletion mapping analysis localized the DNA binding region at the C-terminal part of the protein. This region is sufficient to assure the binding to methylated RT LINE with high affinity. Western blot and immunofluorescence microscopy, using an antibody raised against EhMLBP, showed that it has a nuclear localization. Chromatin immunoprecipitation (ChIP) confirmed that EhMLBP interacts with RT LINE in vivo. Finally, we showed that EhMLBP can also bind rDNA episome, a DNA that is methylated in the parasite. This suggests that EhMLBP may serve as a sensor of methylated repetitive DNA. This is the first report of a DNA-methylated binding activity in protozoa.

DNA methylation and targeting of LINE retrotransposons in Entamoeba histolytica and Entamoeba invadens.

In this study, we have isolated by affinity chromatography, using anti-m5C antibody as a ligand, a DNA encoding reverse transcriptase of LINE retrotransposon (RT LINE) in both Entamoeba invadens and Entamoeba histolytica. RT LINE transcripts were detected in E. histolytica but were absent from E. invadens. The methylation status of genomic copies of E. invadens RT LINE was confirmed by bisulfite analysis. In contrast, all the genomic copies of the E. histolytica RT LINE analyzed in this study were not methylated. Many of these genomic copies diverge from the RT LINE isolated by m5C affinity chromatography by a number of mutations that includes conversion of C to T and G to A. These mutations are reminiscent of the conversion of C to T (and G to A on the complementary DNA strand) that occurred during primate evolution in Alu elements following accelerated deamination of methylated cytosines. E. invadens and E. histolytica RT LINEs isolated by affinity chromatography were cloned in a pEhAct Neo vector, amplified in E. coli GM2163 (dam-dcm) and transformed into E. histolytica. Bisulfite analysis of transfected amoeba showed the presence of m5C in E. invadens RT LINE replicated in E. histolytica, but not in E. histolytica RT LINE or in the neomycine phosphotransferase gene, which is also carried by the pEhAct Neo vector. These results suggest the existence of a specific mechanism based on DNA methylation that controls retrotransposons in these parasites.