Use of histone deacetylases inhibitors in bovine somatic cell nuclear transfer

Cloning of mammals by somatic cell nuclear transfer (SCNT) is still plagued by the low efficiency. The epigenetic marks established during the cell differentiation process are among the main cause. These modifications act as a barrier restricting the nuclear reprogramming process of somatic nuclei. Based on this, molecules that promotes chromatin decondensing, including Histone Deacetylases inhibitors (HDACis), has been demonstrated increase the efficiency of nuclear reprogramming, making their use common on SCNT procedure. Herein, we tested two histone deacetylase inhibitors: Valproic Acid and β-hydroxybutyric Acid, the former a pharmacological drug and the latter, an endogenous metabolite on SCNT. Our objective was to test whether the donor cells treatment or zygotes with these HDACis improve the bovine cloned embryos development. Regarding the VPA, we observed that fibroblasts treatment with VPA increases the histone acetylation and expression of developmentally important genes such as IGF2R and PPARGC1A. However, when treated cells were used as nuclear donors, we did not observe difference on H3K9ac levels between the groups. Moreover, the alterations were quickly removed after SCNT. Regarding the developmental rates, the use of treated cells as nuclear donors did not affect the pre- and post-implantation development. In the second experiment, we used the BOHB in a series of experiments to test whether this molecule acts as a histone deacetylase inhibitor in bovines. We observed that treatment of fibroblasts with BOHB increased the global levels of H3K9ac. Also, treatment alters the expression of important genes such as glucose transporters and a key enzyme regulating lipid synthesis. Additionally, we demonstrated that this metabolite affect at least one epigenetic mark in cloned zygotes, that lasts until the blastocyst stage. However, zygote treatment with this endogenous metabolite did not increase the pre-implantation developmental rates, albeit increased the expression of a transcription factor that protects cells against oxidative stress, the FOXO3a. Treatment of parthenogenetic embryos with BOHB did not affect the embryo development, neither ATP production, suggesting that BOHB is not toxic as previously believed. Concluding, the results presented here shows that the HDAC inhibition through a pharmacological compound or an endogenous metabolite did not increase the efficiency of bovine SCNT. However, here we showed that the ketone body BOHB might be a nexus between the extracellular environment and the cellular metabolism. Also, it can used as a in vitro model to interrogate questions about does metabolic disturbances such as ketosis in cattle affects the epigenome and cellular metabolism in bovines (AU)