Abstract:
In recent times, cattle embryology has been under the spotlight of investigation due to its apparent economic values. This is especially relevant in the case of New Zealand, owing to its high percentage of livestock export. Specifically, the period of peri-implantation development has been of particular relevance. During this stage, the developing zygote will establish 3 key lineages – epiblast, hypoblast and trophoblast. Previous studies have elucidated that a significant number of embryos die prior to implantation, therefore highlighting the importance of correctly establishing these 3 lineages to overall embryonic survival.
However, while embryological stages of the preimplantation embryo have been extensively studied in their eutherian cousin, mice, the molecular regulation of that of cattle remains much less addressed. Whereas the regulation of bovine embryo development is orchestrated by many transcriptional regulators, or genetic regulatory networks (GNP), we aimed to focus our studies on 2 key transcriptional regulators, GATA4 and GATA6. During early embryogenesis, both these transcriptional factors are known molecular regulators that drive the establishment of the hypoblast lineage in mice. By and large, while their respective expression has been documented in cattle embryos, functional studies towards these markers have not yet been performed.
Latest advances in molecular biology have given us novel methods to study the mechanism of bovine embryogenesis. To this end, the continuing perfection of CRISPR technologies in the last decade - in particular its delivery through lentiviral vectors, has established an ability to generate stable, targeted knock-out mutants. Therefore, it is aimed in this thesis to design and test lentiviral particles that induce knock-out mutants of GATA4 and GATAT6, to test their efficacy in primary cell cultures (bovine cumulus cells) and to functionally analyse the effect of GATA4 and GATA6 knockdowns in early bovine embryos.
