Tricarboxylic Acid Cycle Metabolites as Mediators of DNA Methylation Reprogramming in Bovine Preimplantation Embryos.

In many cell types, epigenetic changes are partially regulated by the availability of metabolites involved in the activity of chromatin-modifying enzymes. Even so, the association between metabolism and the typical epigenetic reprogramming that occurs during preimplantation embryo development remains poorly understood. In this work, we explore the link between energy metabolism, more specifically the tricarboxylic acid cycle (TCA), and epigenetic regulation in bovine preimplantation embryos. Using a morphokinetics model of embryonic development (fast- and slow-developing embryos), we show that DNA methylation (5mC) and hydroxymethylation (5hmC) are dynamically regulated and altered by the speed of the first cleavages. More specifically, slow-developing embryos fail to perform the typical reprogramming that is necessary to ensure the generation of blastocysts with higher ability to establish specific cell lineages. Transcriptome analysis revealed that such differences were mainly associated with enzymes involved in the TCA cycle rather than specific writers/erasers of DNA methylation marks. This relationship was later confirmed by disturbing the embryonic metabolism through changes in α-ketoglutarate or succinate availability in culture media. This was sufficient to interfere with the DNA methylation dynamics despite the fact that blastocyst rates and total cell number were not quite affected. These results provide the first evidence of a relationship between epigenetic reprogramming and energy metabolism in bovine embryos. Likewise, levels of metabolites in culture media may be crucial for precise epigenetic reprogramming, with possible further consequences in the molecular control and differentiation of cells.

Early cleavages influence the molecular and the metabolic pattern of individually cultured bovine blastocysts.

Embryo morphokinetics suggests that the timing of the first embryonic cell divisions may predict the developmental potential of an embryo; however, correlations between embryonic morphokinetics and physiology are not clear. Here, we used RNA sequencing to determine the gene expression profile of in vitro-produced early- and late-dividing bovine embryos and their respective blastocysts, and compared these profiles to in vivo-produced blastocysts to identify differentially expressed genes (DEGs). Principal component analysis revealed that fast- and slow-dividing embryos possess similar transcript abundance over the first cleavages. By the blastocyst stage, however, more DEGs were observed between the fast- and slow-dividing embryo groups, whereas blastocysts from the slow-dividing group were more similar to in vivo-produced blastocysts. Gene ontology enrichment analysis showed that the slow-dividing and in vivo-produced blastocysts shared biological processes related to groups of up- or down-regulated genes when compared to the fast-dividing blastocysts. Based on these DEG results, we characterized the relationship between developmental kinetics and energy metabolism of in vitro-produced bovine embryos. Embryos from fast- and slow-dividing groups exhibited different pyruvate and lactate metabolism at 22 hr post-in vitro culture (hpc), glucose consumption at 96 hpc, and glutamate metabolism at 168 hpc. Glycogen storage was similar between cleavage-stage and morulae groups, but was higher in the blastocysts of the slow-dividing group. On the other hand, blastocysts of the fast-dividing group had a higher concentration of lipids. Taken together, these data identify transcriptomic and metabolic differences between embryos with different morphokinetics, suggesting that sorting embryos based on cleavage speed may select for different metabolic patterns. Mol. Reprod. Dev. 83: 324-336, 2016. © 2016 Wiley Periodicals, Inc.