Effect of oxygen and glucose availability during in vitro maturation of bovine oocytes on development and gene expression.

PURPOSE: Oxygen tension during the in vitro maturation (IVM) of oocytes is important for oocyte developmental competence. A conflict exists in the literature as to whether low oxygen during IVM is detrimental or beneficial to the oocyte. Many research and clinical labs use higher than physiological oxygen tension perhaps believing that low-oxygen tension is detrimental to oocyte development. Other studies show that glucose is important if low-oxygen tension is used during maturation. In this study, we look at the link between low oxygen and glucose availability during IVM to resolve misconceptions around low-oxygen tension during IVM. METHODS: Bovine cumulus oocyte complexes (COCs) were matured at 20% vs 7% oxygen in media containing differing glucose concentrations or varying availability. Cleavage and blastocyst rates were recorded. RT-PCR determined expression levels of metabolic, oxygen, and stress-responsive genes following IVM. RESULTS: Embryo development in 7% oxygen groups with 2.3mM glucose/low glucose availability was lower than 20% oxygen groups. Under 7% oxygen with 5.6mM glucose or higher glucose availability, rates were restored to those seen in 20% oxygen. Expressions of BNIP3, ENO1, GAPDH, and SLC2A1, were upregulated in 7% oxygen/low glucose, compared to 20% oxygen groups. BNIP3 expression was higher in 7% oxygen group with low glucose availability compared to the 20% groups. CONCLUSION: Oocyte developmental competence is negatively impacted following IVM in low oxygen when glucose availability is limited. Glucose concentration and physical culture conditions need to be considered when comparing the effects of different oxygen concentrations during IVM.

Gray level Co-occurrence Matrices (GLCM) to assess microstructural and textural changes in pre-implantation embryos.

The preimplantation embryo is extraordinarily sensitive to environmental signals and events such that perturbations can alter embryo metabolism and program an altered developmental trajectory, ultimately affecting the phenotype of the adult individual; indeed, the physical environment associated with in vitro embryo culture can attenuate development. Defining the underlying metabolic changes and mechanisms, however, has been limited by the imaging technology used to evaluate metabolites and structural features in the embryo. Here, we assessed the impact of in vitro fertilization and culture on mouse embryos using three metabolic markers: peroxyfluor 1 (a reporter of hydrogen peroxide), monochlorobimane (a reporter of glutathione), and Mitotracker Deep Red (a marker of mitochondria). We also evaluated the distribution pattern of histone 2AX gamma (γH2AX) in the nuclei of 2- and 8-cell embryos and blastocysts to investigate the degree of DNA damage caused by in vitro embryo culture. In vitro-fertilized embryos, in vivo-developed embryos, and in vivo-fertilized embryos recovered and cultured in vitro were compared at the 2-, 8-cell, and blastocyst stages. In addition to assessments based on fluorescence intensity, textural analysis using Gray Level Co-occurrence Matrix (GLCM), a statistical approach that assesses texture within an image, was used to evaluate peroxyfluor 1, monochlorobimane, and Mitotracker Deep Red staining in an effort to develop a robust metric of embryo quality. Our data provide strong evidence of modified metabolic parameters identifiable as altered fluorescence texture in embryos developed in vitro. Thus, texture-analysis approach may provide a means of gaining additional insight into embryo programming beyond conventional measurements of staining intensity for metabolic markers. Mol. Reprod. Dev. 83: 701-713, 2016 © 2016 Wiley Periodicals, Inc.