Chemical activation of mammalian oocytes and its application in camelid reproductive biotechnologies: A review

• Published in: Animal reproduction science Vol. 266; p. 107499
• Main Authors: Bellido-Quispe, Dionet Keny, Arcce, Irving Mitchell Laines, Pinzón-Osorio, César Augusto, Campos, Vinicius Farias, Remião, Mariana Härter
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.07.2024
• Subjects: Animals; Camelidae; Camelids; Chemical activation; Female; ICSI; Nuclear Transfer Techniques - veterinary; Oocyte activation; Oocytes - drug effects; Oocytes - physiology; Parthenogenesis (PA); SCNT; Oocyte activation; SCNT; ICSI; Chemical activation; Parthenogenesis (PA); Camelids
• ISSN: 0378-4320; 1873-2232; 1873-2232
• DOI: 10.1016/j.anireprosci.2024.107499

Mammalian oocyte activation is a critical process occurring post-gamete fusion, marked by a sequence of cellular events initiated by an upsurge in intracellular Ca2+. This surge in calcium orchestrates the activation/deactivation of specific kinases, leading to the subsequent inactivation of MPF and MAPK activities, alongside PKC activation. Despite various attempts to induce artificial activation using distinct chemical compounds as Ca2+ inducers and/or Ca2+-independent agents, the outcomes have proven suboptimal. Notably, incomplete suppression of MPF and MAPK activities persists, necessitating a combination of different agents for enhanced efficiency. Moreover, the inherent specificity of activation methods for each species precludes straightforward extrapolation between them. Consequently, optimization of protocols for each species and for each technique, such as PA, ICSI, and SCNT, is required. Despite recent strides in camelid biotechnologies, the field has seen little advancement in chemical activation methods. Only a limited number of chemical agents have been explored, and the effects of many remain unknown. In ICSI, despite obtaining blastocysts with different chemical compounds that induce Ca2+ and calcium-independent increases, viable offspring have not been obtained. However, SCNT has exhibited varying outcomes, successfully yielding viable offspring with a reduced number of chemical activators. This article comprehensively reviews the current understanding of the physiological activation of oocytes and the molecular mechanisms underlying chemical activation in mammals. The aim is to transfer and apply this knowledge to camelid reproductive biotechnologies, with emphasis on chemical activation in PA, ICSI, and SCNT. [Display omitted] •Chemical compounds that induce simple, oscillatory, or calcium-independent increases enhance activation.•The use of CDKIs enhances the activation of oocytes but inhibits other CDKs.•Zn2+ chelators as a focus of artificial activation in reproductive biotechnologies.•This review shows the AOA's relevance in camelid reproductive biotech for the first time.