Protein-targeting reverse genetic approaches: the future of oocyte and preimplantation embryo research.

Abstract

Reverse genetic approaches are the standard in molecular biology to determine a protein's function. Traditionally, nucleic acid targeting via gene knockout (DNA) and knockdown (RNA) has been the method of choice to remove proteins-of-interest. However, the nature of mammalian oocyte maturation and preimplantation embryo development can make nucleic acid targeting approaches difficult. Gene knockout allows time for compensatory mechanisms and secondary phenotypes to develop which can make interpretation of a protein's function difficult. Furthermore, genes can be essential for animal and/or oocyte survival, and therefore, gene knockout is not always a viable approach to investigate oocyte maturation and preimplantation embryo development. Conversely, RNA-targeting approaches, ie RNA interference (RNAi) and morpholinos, rely on protein half-life and therefore are unable to knockdown every protein-of-interest. An increasing number of reverse genetic approaches that directly target proteins have been developed to overcome the limitations of nucleic acid-based approaches, including Trim-Away and auxin-inducible degradation. These protein-targeting approaches give researchers exquisite and fast control of protein loss. This review will discuss how Trim-Away and auxin-inducible degradation can overcome many of the challenges of nucleic acid based reverse genetic approaches. Furthermore, it highlights the unique research opportunities these approaches afford, such as targeting post-translationally modified proteins.