A dose-sensitive OGT-TET3 complex is necessary for normal Xist RNA distribution and function

Female (XX) mouse embryonic stem cells (mESCs) differ from their male (XY) counterparts because they have lower levels of 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC). This difference in DNA modifications is a result of having two X chromosomes (Xs), both of which are active at this developmental stage. We identified an X-linked gene, Ogt, that controls levels of 5mC and 5hmC in mESCs. OGT is a post-translational modification enzyme and we identified the 5-methylcytosine dioxygenase TET3 as an OGT target that is differentially modified in XX and XY mESCs. In addition to influencing 5mC and 5hmC abundance, OGT dose also controls TET3 and OGT distribution. OGT and TET3 are predominantly nuclear in XX mESCs and cytoplasmic in XY mESCs. Furthermore, these proteins are present in different complexes in XX and XY mESCs. Mutational analysis revealed that TET3 determines the XX-specific abundance of 5mC and 5hmC in mESCs. While TET3 null XX mESCs exhibited modest changes in gene expression, there were substantial alterations upon differentiation into epiblast-like cells (mEpiLCs). In addition, these TET3 null XX mESCs did not undergo X-chromosome inactivation (XCI) when differentiated. These data suggest that an X-dose sensitive complex containing OGT and TET3 regulates cytosine modifications and XCI.

DNA-mediated coupling of ATPase, translocase and nuclease activities of a Type ISP restriction-modification enzyme

Enzymes involved in nucleic acid transactions often have a helicase-like ATPase coordinating and driving their functional activities, but our understanding of the mechanistic details of their coordination is limited. For example, DNA cleavage by the antiphage defense system Type ISP restriction-modification enzyme requires convergence of two such enzymes that are actively translocating on DNA powered by Superfamily 2 ATPases. The ATPase is activated when the enzyme recognizes a DNA target sequence. Here, we show that the activation is a two-stage process of partial ATPase stimulation upon recognition of the target sequence by the methyltransferase and the target recognition domains, and complete stimulation that additionally requires the DNA to interact with the ATPase domain. Mutagenesis revealed that a β-hairpin loop and motif V of the ATPase couples DNA translocation to ATP hydrolysis. Deletion of the loop inhibited translocation, while mutation of motif V slowed the rate of translocation. Both the mutations inhibited the double-strand (ds) DNA cleavage activity of the enzyme. However, a translocating motif V mutant cleaved dsDNA on encountering a translocating wild-type enzyme. Based on these results, we conclude that the ATPase-driven translocation not only brings two nucleases spatially close to catalyze dsDNA break, but that the rate of translocation influences dsDNA cleavage.

Effects of Endophytic Fungus MF23 on Dendrobium nobile Lindl. in an artificial primary environment

The quality of Dendrobium nobile Lindl. is related to the endophytic fungus. It had reported that the mycorrhizal fungus MF23 helps to increase the content of dendrobine, but few studies had explained the mechanism of the phenomenon. In previous study, we verified the symbiotic mechanism of the mycorrhizal fungus MF23 with D. nobile on the agar medium. In this study, the research carried on the bark medium, nearly like the natural environment, which had special meaning because of its benefits for the widely application. As a result, it showed a significant effect especially in the later period of the cultivation, suggesting that mycorrhizal fungus MF23 had a promotion for D. nobile in the natural environment, which enabled the application of the technique in the experimental field. It also implied that post-modification enzyme genes might play an important role in stimulating biosynthesis of dendrobine.