Environmental factors affecting interferon-τ expression and secretion by in vitro produced bovine blastocysts

Interferon (IFN)τ is the luteotrophic signal in ruminants and is secreted by bovine blastocysts both in vivo and in vitro. IFNτ secretion is highly variable and its control is only partly understood. Most studies on the effects of environmental factors on IFNτ production have evaluated IFNτ production during the time of embryo elongation and attachment. There is less knowledge of how IFNτ production at the blastocyst stage is modulated. Therefore, the hypothesis of this thesis was that the amounts of IFNτ expressed and/or secreted by bovine blastocysts produced in vitro were modulated by environmental factors. In the first set of experiments, bovine embryos were incubated with a cytokine (granulocyte macrophage colony stimulating factor, GM-CSF). GM-CSF had been shown previously to promote embryo viability in a range of species and to modulate IFNτ secretion by ovine blastocysts and thus was classified as a beneficial environmental factor. Three experiments were conducted to test whether GM-CSF stimulated bovine blastocyst development and IFNτ secretion. Embryos were incubated with a range of different concentrations of GM-CSF (2, 5, 10 and 50 ng mL-1) and at different stages of development (1 to 3 and 1 to 9 days post-insemination). Bovine embryos were unresponsive to GM-CSF in terms of IFNτ secretion, pyruvate oxidation, rate of development, blastocyst yield, morphological quality and apoptotic index, irrespective of timing of exposure and/or concentration of GM-CSF. In the second part of the thesis, bovine blastocysts were exposed to a mild heat treatment (42°C for four h) to determine whether heat stress affected IFNτ expression by bovine blastocysts. A novel multiplex reverse-transcription polymerase chain reaction methodology was validated to detect IFNτ and heat shock protein (HSP)70 mRNA in individual bovine embryos relative to an endogenous gene (YWHAZ) and an exogenous mRNA (α-globin) and results were expressed both in absolute terms and in relation to the endogenous control. Heat treatment upregulated IFNτ mRNA expression, suggesting that detrimental environmental factors may influence IFNτ expression. Heat treatment also caused an increase in HSP70 mRNA expression but did not affect blastocyst morphology, suggesting that the level of stress caused by the heat treatment was great enough to activate the cellular stress response, but mild enough not to cause a change in morphology. In addition, the positive correlation between HSP70 and IFNτ transcript levels and the higher IFNτ expression by embryos which showed signs of degeneration and collapse compared to those which progressed in development suggested that IFNτ expression may be indicative of stress. The relationship between IFNτ expression and secretion in vitro with morphology, pyruvate metabolism, apoptotic index and cell number was inconsistent, suggesting that IFNτ production did not correlate with ‘quality’ (defined as an index of viability). Blastocyst yield, day of blastulation and change in morphology index did account for at least part of the variation in IFNτ production, suggesting that some intrinsic factors may regulate IFNτ secretion. These intrinsic factors, however, did not explain all the variation in IFNτ secretion between blastocysts. Therefore, the amount of IFNτ secreted by bovine blastocysts is modulated by both intrinsic and environmental factors. A model was proposed where different levels of stress affect survivability to different extents, and the ability to respond to mild levels of stress may be indicative of improved survivability

Modelling a risk classification of aneuploidy in human embryos using non-invasive morphokinetics

This study determined whether morphokinetic variables between aneuploid and euploid embryos differ as a potential aid to select euploid embryos for transfer. Following insemination, EmbryoScope time-lapse images from 98 blastocysts were collected and analysed blinded to ploidy. The morphokinetic variables were retrospectively compared with ploidy, which was determined following trophectoderm biopsy and analysis by array comparative genomic hybridization or single-nucleotide polymorphic array. Multiple aneuploid embryos were delayed at the initiation of compaction (tSC; median 85.1 hours post insemination (hpi); P = 0.02) and the time to reach full blastocyst stage (tB; median 110.9 hpi, P = 0.01) compared with euploid embryos (tSC median 79.7 hpi, tB median 105.9 hpi). Embryos having single or multiple aneuploidy (median 103.4 hpi, P = 0.004 and 101.9 hpi, P = 0.006, respectively) had delayed initiation of blastulation compared with euploid embryos (median 95.1 hpi). No significant differences were observed in first or second cell-cycle length, synchrony of the second or third cell cycles, duration of blastulation, multinucleation at the 2-cell stage and irregular division patterns between euploid and aneuploid embryos. This non-invasive model for ploidy classification may be used to avoid selecting embryos with high risk of aneuploidy while selecting those with reduced risk. Chromosome anomalies (aneuploidy) are prevalent in human embryos and result in either IVF failure, miscarriage or the birth of children with chromosome disorders. After IVF, it is imperative to try to detect aneuploid embryos in order to transfer an embryo with a normal chromosome copy number (euploid) to maximize the chances of a successful and healthy live birth. Currently, the only option is to biopsy a cell (or cells) from the embryo and analyse these using complex and expensive genetic technology. Novel uninterrupted culturing methods using the EmbryoScope now enables detailed observation of the each embryo via time-lapse photography during the whole culture period, for up to 6 days. This new technology has permitted us to observe the development of human embryos in detail after IVF, providing analysis of complex patterns of cell division and cell movement (morphokinetics). As far as is known for the first time, we have demonstrated differences between aneuploid and euploid embryos based on their morphokinetic patterns, whereby aneuploid embryos are significantly delayed in reaching the later stages of development, during days 4 and 5 in culture. We postulate that, by using the unique, non-invasive and specifically designed models or algorithms developed in this study, embryologists can make more informed choices on the most viable embryo to select for transfer and reduce the risk of selecting an aneuploid embryo