The epigenetic mechanisms underlying gamete origin of adult-onset diseases

Single-cell and spatial transcriptomes reveal the impact of maternal low protein diet on follicular cell composition and ovarian micro-environment in the offspring

Maternal low protein diet around pregnancy reduces the primordial follicles in offspring ovary. Resolving cellular and molecular mechanisms associated with low protein diet is therefore urgently needed for the guidance of dietary interventions. Here, we utilized single-cell and spatial RNA-seq to create transcriptomic atlases of offspring ovaries from maternal low protein diet mice. Analysis of cell type specific low protein diet associated transcriptional changes revealed increased unfolded protein and decreased oxidative phosphorylation defense as a hallmark of low protein diet effects. Altered pathways included hedgehog signaling in granulosa cells, BMP signaling in theca cells and PTN signaling in early theca cells. Notably, the disordered follicular cell function and ovarian microenvironment may closely corelated with decreased follicular number and quality. Collectively, our findings depict the transcriptomic atlases of the offspring ovary derived from maternal low protein diet group and provide candidate molecular mechanisms underlying the complex ovarian cell changes conferred by low protein diet.

Ultrafast Formation of a Delocalized Triplet-Excited State in an Epigenetically Modified DNA Duplex under Direct UV Excitation

Epigenetic modifications impart important functionality to nucleic acids during gene expression but may increase the risk of photoinduced gene mutations. Thus, it is crucial to understand how these modifications affect the photostability of duplex DNA. In this work, the ultrafast formation (<20 ps) of a delocalized triplet charge transfer (CT) state spreading over two stacked neighboring nucleobases after direct UV excitation is demonstrated in a DNA duplex, d(G5fC)9•d(G5fC)9, made of alternating guanine (G) and 5-formylcytosine (5fC) nucleobases. The triplet yield is estimated to be 8 ± 3%, and the lifetime of the triplet CT state is 256 ± 22 ns, indicating that epigenetic modifications dramatically alter the excited state dynamics of duplex DNA and may enhance triplet state-induced photochemistry.

Research progress on the effects of adverse exposure during pregnancy on skeletal muscle function in the offspring

Skeletal muscle plays a crucial role in maintaining metabolism, energy homeostasis, movement, as well as endocrine function. The gestation period is a critical stage for myogenesis and development of the skeletal muscle. Adverse environmental exposures during pregnancy may impose various effects on the skeletal muscle health of the offspring. Maternal obesity during pregnancy can mediate lipid deposition in the skeletal muscle of the offspring by affecting fetal skeletal muscle metabolism and inflammation-related pathways. Poor dietary habits during pregnancy, such as high sugar and high fat intake, can affect autophagy of skeletal muscle mitochondria and reduce the quality of the offspring skeletal muscle. Nutritional deficiencies during pregnancy can affect the development of the offspring skeletal muscle through epigenetic modifications. Gestational diabetes may affect the function of the offspring skeletal muscle by upregulating the levels of miR-15a and miR-15b in the offspring. Exposure to environmental endocrine disruptors during pregnancy may impair skeletal muscle function by interfering with insulin receptor-related signaling pathways. This article reviews the research progress on effects and possible mechanisms of adverse maternal exposures during pregnancy on the offspring skeletal muscle function based on clinical and animal studies, aiming to provide scientific evidence for the prevention and treatment strategies of birth defects in the skeletal muscle.