Severe global DNA hypomethylation blocks differentiation and induces histone hyperacetylation in embryonic stem cells

It has been reported that DNA methyltransferase 1-deficient (Dnmt1-/-) embryonic stem (ES) cells are hypomethylated (20% CpG methylation) and die through apoptosis when induced to differentiate. Here, we show that Dnmt[3a-/-,3b-/-] ES cells with just 0.6% of their CpG dinucleotides behave differently: the majority of cells within the culture are partially or completely blocked in their ability to initiate differentiation, remaining viable while retaining the stem cell characteristics of alkaline phosphatase and Oct4 expression. Restoration of DNA methylation levels rescues these defects. Severely hypomethylated Dnmt[3a-/-,3b-/-] ES cells have increased histone acetylation levels, and those cells that can differentiate aberrantly express extraembryonic markers of differentiation. Dnmt[3a-/-,3b-/-] ES cells with >10% CpG methylation are able to terminally differentiate, whereas Dnmt1-/- ES cells with 20% of the CpG methylated cannot differentiate. This demonstrates that successful terminal differentiation is not dependent simply on adequate methylation levels. There is an absolute requirement that the methylation be delivered by the maintenance enzyme Dnmt1.     

CTCF elements direct allele-specific undermethylation at the imprinted H19 locus

The H19 imprinted gene locus is regulated by an upstream 2 kb imprinting control region (ICR) that influences allele-specific expression, DNA methylation, and replication timing. This ICR becomes de novo methylated during late spermatogenesis in the male but emerges from oogenesis in an unmethylated form, and this allele-specific pattern is then maintained throughout early development and in all tissues of the mouse. We have used a genetic approach involving transfection into embryonic stem (ES) cells in order to decipher how the maternal allele is protected from de novo methylation at the time of implantation. Our studies show that CCCTC binding factor (CTCF) boundary elements within the ICR have the ability to prevent de novo methylation on the maternal allele. Since CTCF does not recognize its binding sequence when methylated, this reaction does not occur on the paternal allele, thus preserving the gamete-derived, allele-specific pattern. These results suggest that CTCF may play a general role in the maintenance of differential methylation patterns in vivo.     

Retinoic acid-mediated down-regulation of Oct3/4 coincides with the loss of promoter occupancy in vivo.

Oct3/4, a hallmark of the earliest stages of embryogenesis, is expressed in undifferentiated embryonal carcinoma (EC) and embryonic stem (ES) cells. Oct3/4 gene expression is dependent on the promoter region, the proximal enhancer and the newly identified distal enhancer. We have analysed in vivo occupancy of these elements. In undifferentiated EC and ES cells, strong footprints were detected at specific sites of all three regulatory elements. These were promptly lost upon RA treatment in ES cells and in P19 EC cells, in parallel with sharply reduced Oct3/4 mRNA levels. Thus, the occupancy of regulatory elements is coupled with Oct3/4 expression, and RA treatment causes coordinated factor displacement, leading to extinction of gene activity. In F9 EC cells, footprint was first abolished at the proximal enhancer. However, this loss of binding site occupancy did not result in a decrease in Oct3/4 mRNA levels. The partial factor displacement seen in F9 EC cells, combined with the observation that EC and ES cells utilize the proximal and distal enhancers in differential manner, indicate the complex pattern of Oct3/4 gene regulation, which could reflect a cell type- and lineage-specific expression of the gene in vivo.