Oxygen concentration affects de novo DNA methylation and transcription in in vitro cultured oocytes

Background Reproductive biology methods rely on in vitro follicle cultures from mature follicles obtained by hormonal stimulation for generating metaphase II oocytes to be fertilised and developed into a healthy embryo. Such techniques are used routinely in both rodent and human species. DNA methylation is a dynamic process that plays a role in epigenetic regulation of gametogenesis and development. In mammalian oocytes, DNA methylation establishment regulates gene expression in the embryos. This regulation is particularly important for a class of genes, imprinted genes, whose expression patterns are crucial for the next generation. The aim of this work was to establish an in vitro culture system for immature mouse oocytes that will allow manipulation of specific factors for a deeper analysis of regulatory mechanisms for establishing transcription regulation-associated methylation patterns. Results An in vitro culture system was developed from immature mouse oocytes that were grown to germinal vesicles (GV) under two different conditions: normoxia (20% oxygen, 20% O2) and hypoxia (5% oxygen, 5% O2). The cultured oocytes were sorted based on their sizes. Reduced representative bisulphite sequencing (RRBS) and RNA-seq libraries were generated from cultured and compared to in vivo-grown oocytes. In the in vitro cultured oocytes, global and CpG-island (CGI) methylation increased gradually along with oocyte growth, and methylation of the imprinted genes was similar to in vivo-grown oocytes. Transcriptomes of the oocytes grown in normoxia revealed chromatin reorganisation and enriched expression of female reproductive genes, whereas in the 5% O2 condition, transcripts were biased towards cellular stress responses. To further confirm the results, we developed a functional assay based on our model for characterising oocyte methylation using drugs that reduce methylation and transcription. When histone methylation and transcription processes were reduced, DNA methylation at CGIs from gene bodies of grown oocytes presented a lower methylation profile. Conclusions Our observations reveal changes in DNA methylation and transcripts between oocytes cultured in vitro with different oxygen concentrations and in vivo-grown murine oocytes. Oocytes grown under 20% O2 had a higher correlation with in vivo oocytes for DNA methylation and transcription demonstrating that higher oxygen concentration is beneficial for the oocyte maturation in ex vivo culture condition. Our results shed light on epigenetic mechanisms for the development of oocytes from an immature to GV oocyte in an in vitro culture model.

Selectively and Efficiently Expanding Natural Killer Cells in Vitro

Natural killer (NK) cells are the main innate immune cells, and have powerful antitumor activity in vitro, but NK cells based immunotherapy does not often get satisfactory results in clinical practice due to insufficient number and poor activity of NK cells.. Therefore, how to improve expansion efficiency and killing activity of NK cells in vitro is critical. Here we report an in vitro culture system culturing peripheral blood mononuclear cells (PBMC) with irradiated LCL as feeder cells in 10%FBS/RPMI1640 culture medium in the presence of 100U/ml IL-2 and 5ng/ml IL-15 for 14 days could selectively expand NK cells. With this culture system, the purity of NK cells increased from 11.5%± 7.01% to 75.3±10.9% (P< 0.01), and the expansion efficiency was about 625±63 times than the original PBMC. Compared with the fresh NK cells isolated from PBMC, there was no significant change in the expression of inhibitory receptors on the surface of expanded NK cells, while the expression of activating receptors was significantly increased (p<0.05). The cytotoxicity of expanded NK cells against leukemia cell line K562 was significantly higher than that of freshly isolated NK cells (72± 5.6% vs 8.7±2.3%, E: T=1, P<0.01), expanded NK cells also showed stronger cytotoxicity to LCL (22±3.6%, E: T=1) and primary leukemia cells (42±5.2%, E:T=1). In summary, we could selectively expand NK cells with this in vitro culture system, the expanded NK cells gained higher expression of NCRs and NKG2D receptors, and displayed greater cytotoxicity against tumor cells, therefore could be readily applied to anti-tumor treatment in clinical treatment. Figure Disclosures No relevant conflicts of interest to declare.

In vitro Culture of Early Secondary Preantral Follicles to Obtain MII Oocyte Developmental Competence from CD-1 Outbred Mice

Background: The ovarian follicle is the fundamental functional tissue unit that consists of mammalian ovary. In humans, it has been known that females are born with a maximum number of follicles or oocytes that are not only non-renewable, but also undergoing degeneration with time with a sharply decreased oocyte quality after the age of 35. Methods: Here, we demonstrate that successful isolation of primary, early secondary and late secondary follicles from the ovaries of CD-1 outbred female mice and in vitro culture system to successfully induce the development of MII oocytes. Result: The 9 days of in vitro culture of early secondary follicles showed significant higher rates in growth and maturation displaying higher numbers of antral follicles and MII oocytes developed from early secondary follicles compared to those cultured for 11 days. However, there was no visible difference induced by the size of initial follicles in the rates of growth and maturation. MII oocytes derived from in vitro culture of early secondary follicles following in vitro fertilization developed into two-cell embryos. These observations demonstrate that developmentally competent MII oocytes can be obtained by in vitro culture of preantral follicles derived from the ovaries of CD-1 mice and reveal a crucial role for CD-1 mice as a novel model for research on human ovarian follicles. Furthermore, this study proposes an in vitro culture system using preantral follicle as a therapeutic strategy for fertility preservation of humans for assisted reproductive medicine.