An Lei

Characterization and comparative analyses of transcriptomes for in vivo and in vitro produced peri-implantation conceptuses and endometria from sheep.

An increasing number of reports indicate that in vitro fertilization (IVF) is highly associated with long‑term side effects on embryonic and postnatal development, and can sometimes result in embryonic implant failure. While high‑throughput gene expression analysis has been used to explore the mechanisms underlying IVF-induced side effects on embryonic development, little is known about the effects of IVF on conceptus–endometrial interactions during the peri-implantation period. Using sheep as a model, we performed a comparative transcriptome analysis between in vivo (IVO; in vivo fertilized followed by further development in the uterus) and in vitro produced (IVP; IVF with further culture in the incubator) conceptuses, and the caruncular and intercaruncular areas of the ovine endometrium. We identified several genes that were differentially expressed between the IVO and IVP groups on day 17, when adhesion between the trophoblast and the uterine luminal epithelium begins in sheep. By performing Gene Ontology enrichment analysis and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis, we found that, in the conceptus, differentially expressed genes (DEGs) were associated mainly with functions relating to cell binding and the cell cycle. In the endometrial caruncular area, DEGs were involved in cell adhesion/migration and apoptosis, and in the intercaruncular area, they were significantly enriched in pathways of signal transduction and transport. Thus, these DEGs are potential candidates for further exploring the mechanism underlying IVF/IVP-induced embryonic implant failure that occurs due to a loss of interaction between the conceptus and endometrium during the peri-implantation period.

High-resolution profiles of gene expression and DNA methylation highlight mitochondrial modifications during early embryonic development

Well-organized mitochondrial functions and dynamics are critical for early embryonic development and are operated via a large number of mitochondria-related genes (MtGs) encoded by both the nuclear and the mitochondrial genome. However, the mechanisms underlying mitochondrial modifications during the critical window between blastocyst implantation and postimplantation organogenesis are poorly understood. Herein, we performed high-resolution dynamic profiling of MtGs to acquire a more detailed understanding of mitochondrial modifications during early development. Our data suggest that the resumption of mitochondrial mass growth is not only facilitated by increased mitochondrial biogenesis and mitochondrial DNA (mtDNA) replication, but also by the appropriate balance between mitochondrial fission and fusion. In addition, increased levels of reactive oxygen species (ROS) resulting from enhanced mitochondrial functions may be the critical inducer for activating the glutathione (GSH)-based stress response system in early embryos. The appropriate balance between the mitochondrial stress response and apoptosis appears to be significant for cell differentiation and early organogenesis. Furthermore, we found that most MtGs undergo de novo promoter methylation, which may have functional consequences on mitochondrial functions and dynamics during early development. We also report that mtDNA methylation can be observed as early as soon after implantation. DNMT1, the predominant enzyme for maintaining DNA methylation, localized to the mitochondria and bound to mtDNA by the implantation stage. Our study provides a new insight into the involvement of mitochondria in early mammalian embryogenesis. We also propose that the epigenetic modifications during early development are significant for modulating mitochondrial functions and dynamics.

miR-6539 is a novel mediator of somatic cell reprogramming that represses the translation of Dnmt3b

Global DNA hypomethylation has been shown to be involved in the pluripotency of induced pluripotent stem (iPS) cells. Relatedly, DNA methyltransferases (DNMTs) are believed to be a substantial barrier to genome-wide demethylation. There are two distinct stages of DNMT expression during iPS cell generation. In the earlier stage of reprogramming, the expression of DNMTs is repressed to overcome epigenetic barriers. During the late stage, the expression of DNMTs is upregulated to ensure iPS cells obtain the full pluripotency required for further development. This fact is strongly reminiscent of microRNAs (miRNAs), critical regulators of precise gene expression, may be central to coordinate the expression of DNMTs during reprogramming. Using a secondary inducible system, we found that miR-6539 had a unique expression dynamic during iPS cell generation that inversely correlated with DNMT3B protein levels. Enforced upregulation of miR-6539 during the early stage of reprogramming increased the efficiency of iPS cell generation, while enforced downregulation impaired efficiency. Further analysis showed that Dnmt3b mRNA is the likely target of miR-6539. Notably, miR-6539 repressed Dnmt3b translation via a target site located in the coding sequence. Our study has therefore identified miR-6539 as a novel mediator of somatic cell reprogramming and, to the best of our knowledge, is the first to demonstrate miRNA-mediated translation inhibition in somatic cell reprogramming via targeting the coding sequence. Our study contributes to understand the mechanisms that underlie the miRNA-mediated epigenetic remodeling that occurs during somatic cell reprogramming.