Control of organ-specific demethylation by an element of the T-cell receptor-alpha locus control region

DNA methylation is important for mammalian development and the control of gene expression. Recent data suggest that DNA methylation causes chromatin closure and gene silencing. During development, tissue specifically expressed gene loci become selectively demethylated in the appropriate cell types by poorly understood processes. Locus control regions (LCRs), which are cis-acting elements providing stable, tissue-specific expression to linked transgenes in chromatin, may play a role in tissue-specific DNA demethylation. We studied the methylation status of the LCR for the mouse T-cell receptor alpha/delta locus using a novel assay for scanning large distances of DNA for methylation sites. Tissue-specific functions of this LCR depend largely on two DNase I-hypersensitive site clusters (HS), HS1 (T-cell receptor alpha enhancer) and HS1'. We report that these HS induce lymphoid organ-specific DNA demethylation in a region located 3.8 kilobases away with little effect on intervening, methylated DNA. This demethylation is impaired in mice with a germline deletion of the HS1/HS1' clusters. Using 5'-deletion mutants of a transgenic LCR reporter gene construct, we show that HS1' can act in the absence of HS1 to direct this tissue-specific DNA demethylation event. Thus, elements of an LCR can control tissue-specific DNA methylation patterns both in transgenes and inside its native locus.     

Germ cell specific promoter drives ectopic transgene expression during embryogenesis

In this study, we used the male germ cell-specific phosphoglycerate kinase 2 (Pgk2) promoter to generate Pgk2Cre transgenic mice to allow investigation of genes critically involved in meiosis. The Pgk2 promoter had been used previously to target transgene expression to spermatocytes and spermatids in several laboratories including ours. In several Cre targeting experiments using other promoters, ectopic Cre expression had been observed, but the timing and extent of this expression was not analyzed. We demonstrate that in adult mice the Pgk2Cre transgene is expressed specifically in spermatocytes and spermatids, as expected. However, in offspring from matings of Pgk2Cre mice and an H19loxP indicator strain, we discovered that recombination events had occurred in several, but not all, tissues to varying extents. The lacZ-loxP transgenic indicator strain was next used to uncover ectopic Cre expression even in single cells, which indicated that the Pgk2Cre transgene is expressed between days 11 and 15 during embryogenesis in several tissues and organs. Using an RT PCR assay we were unable to detect endogenous Pgk2 mRNA during embryogenesis or in adult tissues other than testis. In conclusion, the Pgk2 promoter is a valid choice for targeting gene expression to meiotic male germ cells, since transient ectopic expression is unlikely to have a discernable effect in most studies, but it may be inappropriate for utilization with Cre recombinase.     

Mouse embryonic stem cells induce targeted DNA demethylation within human MAGE-A1 transgenes

Human tumor development is often associated with a DNA demethylation process. This results in the activation of germline-specific genes, such as MAGE-A1, which rely on DNA methylation for repression in somatic tissues. Here, we searched to identify a cell line possessing ongoing DNA demethylation activity targeted to MAGE-A1. We first assessed MAGE-A1-expressing human tumor cell lines, by evaluating their ability to induce demethylation of MAGE-A1 transgenes that were methylated in vitro before transfection. All cell lines lacked such activity, suggesting that MAGE-A1 hypomethylation in tumors results from a past demethylation event. We then turned to mouse embryonic stem (mES) cells, which are characterized by a high level of methylation plasticity. Interestingly, in vitro methylated MAGE-A1 transgenes became demethylated after transfection into mES cells. Demethylation was targeted to the 5’-region of MAGE-A1, and was strongly reduced at mutated MAGE-A1 transgenes exhibiting impaired promoter activity. Our results indicate that mES cells induce demethylation of MAGE-A1, and represent therefore a valuable system to study this tumor-related process.