Shayan Ahmed, Jamia Millia Islamia, New Delhi
During fertilization, mammalian eggs undergo significant changes in zinc concentration and localization. Half a decade back, researchers at Northwestern University discovered that when human ova are fertilised by sperm, they emit billions of zinc ions. This abrupt exocytosis of about 10 billion zinc ions is known as zinc sparks and is considered one of the most remarkable events in embryology. The discovery of zinc and manganese fluxes is intriguing because it implies that these transition metals may have additional basic signalling roles.
The Quest for Zinc Sparks
Recently, Northwestern University, in collaboration with the U.S. Department of Energy’s (DOE) Argonne National Laboratory and Michigan State University (MSU), discovered the same patterns of zinc sparks during the fertilization of Xenopus eggs. The exocytosis of zinc is accompanied by the release of intracellular manganese ions, which has just recently been discovered. These expelled manganese ions appear to clash with sperm around the fertilised egg, preventing them from entering. According to this study, Zn and Mn fluxes are a conserved characteristic of fertilization in vertebrates and serve as a physiological barrier to polyspermy. These findings support an emerging theory that transition metals are utilised by cells to govern some of an organism’s initial choices.
Xenopus eggs are an order of magnitude greater than human or mouse eggs, and they are available in huge quantities, making them ideal for such research. Before and after fertilization, the researchers used X-ray and electron microscopy to establish the identities, concentrations, and intracellular distributions of metals. The quantity of zinc, manganese and other metals localised in tiny pockets surrounding the eggs’ outer layer were measured using X-ray analysis. Metals in these pockets were almost entirely liberated after fertilization, according to X-ray and electron microscopy.
Significance of Study
It is commonly assumed that genes are the most important regulatory variables, however, this study shows that elements such as zinc and manganese are important in the early phases of development following fertilization. This study suggests that the evolutionary origins of early conception chemistry may be traced back at least 300 million years, to the last common ancestor of frogs and humans. It might also help guide future research into how metals affect human development at the earliest stages.
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Source: Seeler, J. F., Sharma, A., Zaluzec, N. J., Bleher, R., Lai, B., Schultz, E. G., Hoffman, B. M., LaBonne, C., Woodruff, T. K., & O’Halloran, T. V. (2021). Metal ion fluxes controlling amphibian fertilization. Nature chemistry, 13(7), 683–691. https://doi.org/10.1038/s41557-021-00705-2
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About the author: Shayan Ahmed is currently pursuing a Master of Science degree in Microbiology from the Department of Biosciences, Jamia Millia Islamia, New Delhi. His area of research interest lies in antibiotic resistance and associated molecular mechanisms. His recent work was focused on understanding colistin resistance patterns in the environment, particularly in water bodies.
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