Abstract
Phospholipase C zeta (PLCζ) has emerged as a pivotal sperm-specific factor responsible for triggering oocyte activation, a process essential for successful fertilization and early embryogenesis. A narrative review was conducted to examine the molecular architecture and biochemical features of PLCζ, with particular emphasis on how its distinctive structural domains facilitate the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP(2)) and the induction of calcium (Ca(2)(+)) oscillations in the oocyte. Notably, PLCζ exhibits unique sensitivity to basal Ca(2)(+) levels and the capacity to sustain repetitive intracellular Ca(2)(+) transients that drive meiotic progression and block polyspermy. Clinically, PLCζ deficiency-whether caused by genetic mutations, reduced expression, or improper localization-represents a unifying explanation for certain forms of male infertility, including total fertilization failure (TFF) following intracytoplasmic sperm injection (ICSI). Globozoospermia is a prime example; this condition is characterized by round-headed sperm devoid of acrosomes and exhibiting significantly reduced or absent PLCζ and often results in fertilization failure. Diagnostic methods such as immunofluorescence, Western blotting, and the mouse oocyte-activation test collectively support the identification and characterization of PLCζ-related defects, while genetic testing for mutations in the PLCZ1 gene has proven valuable for identifying hereditary causes of sperm-borne oocyte-activation deficiency (OAD). Therapeutic approaches range from assisted oocyte activation (AOA) with calcium ionophores to emerging interventions that introduce functional PLCζ protein or mRNA directly into the oocyte. These advancements demonstrate the rapid translation of foundational discoveries into clinically actionable interventions. Future investigations are poised to refine diagnostic assays, standardize measurement protocols, and explore the potential of gene therapy or CRISPR/Cas9-mediated correction for heritable PLCζ abnormalities. By addressing both the molecular basis and translational applications of PLCζ, recent findings underscore its indispensable role in fertility care and lay out a path toward further innovation in assisted reproductive technologies.