Public Release: 24-Apr-2018
Micronutrient availability can have early and long-lasting effects on egg quality
American Physiological Society
San Diego (April 24, 2018)–An estimated 10 percent of couples in the U.S. struggle with infertility. While a variety of factors can make it difficult for some people to get pregnant, ovulation disorders are a leading cause of female infertility. Now, researchers at Pennsylvania State University have found that zinc deficiency can negatively affect the early stages of egg development, reducing the ability of the egg cells to divide and be fertilized. This may affect fertility months in the future. The researchers will present their results at the American Physiological Society annual meeting at Experimental Biology 2018 in San Diego.
The availability of micronutrients in the ovarian environment and their influence on the development, viability and quality of egg cells (oocytes) is the focus of a growing area of research. In mammals, the ovary is made up of thousands of structures called follicles–women are born with approximately two million–which consist of one oocyte surrounded by layers of support cells (somatic cells). After puberty, a complex cascade of events occurs to prepare groups of oocytes for maturation, ovulation and fertilization. Though a group of oocytes begins to mature each month, only one will be ovulated and have the chance of being fertilized. Multiple factors can influence whether a given oocyte will mature correctly and one day be ovulated, including the presence of sufficient levels of certain micronutrients.
“More and more evidence is accumulating that zinc is a key player in oocyte development,” lead author James Hester said. In the current study, Hester and his adviser, Francisco Diaz, assessed the effects of zinc on egg development extremely early on in the oocyte maturation process.
“Fertility research and treatment has primarily focused on the largest class of follicles (antral follicles), which are capable of ovulating in response to hormonal signals from the pituitary gland,” Hester wrote. “In contrast, our study examines smaller preantral follicles, which are still growing and don’t respond to the ovulatory signal yet. In humans, preantral follicles have to keep growing for about 90 days before they are ready to ovulate. Previous studies showed that zinc levels are critical in the antral follicle, but no one had tested the effect of zinc deficiency on preantral follicle growth.”
The researchers collected preantral follicles from mice and matured them in a cell culture dish. They compared eggs matured in a zinc deficient environment to those grown with normal levels of zinc. They also exposed the zinc-deficient and control eggs to epidermal growth factor to mimic the hormonal environment necessary for ovulation after the maturation process.
Hester and Diaz found that preantral zinc deficiency:
- disrupted growth of cells in culture,
- led to smaller egg cells early in development,
- caused problems with development of somatic cells and elevated certain cell markers, and
- impaired the egg cell’s ability to properly divide (meiosis), a necessary step before successful fertilization can occur. This defect persisted even after more zinc was introduced to the environment.
“Animal studies have consistently shown a zinc requirement for oocytes during meiotic division, fertilization and embryo development. Our new research shows that zinc plays a role in oocyte growth at an earlier stage than previously investigated, during development and before division. Otherwise, it doesn’t matter what the conditions are during ovulation,” Hester explained. “Interestingly, the oocytes commonly used for [in vitro fertilization] are collected from antral follicles, so any effects from preantral development have already occurred.”
While the World Health Organization estimates that 17 percent of the global population is vulnerable to zinc deficiency in their diet, the estimate may not include cases of marginal zinc deficiency (people with some zinc in their diet, but less than recommended). Other at-risk populations include people with dietary and disease factors that also affect zinc status such as irritable bowel syndrome, Crohn’s disease, gastrointestinal disorders and liver disease; women facing food insecurity; or women with certain dietary restrictions, such as vegetarians or vegans who don’t take supplemental zinc.
James Hester, a graduate student at Pennsylvania State University will present the poster “Growing oocytes need zinc: zinc deficiency in the preantral follicle” on Tuesday, April 24, in the Exhibit Hall of the San Diego Convention Center.
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About Experimental Biology 2018
Experimental Biology is an annual meeting comprised of more than 14,000 scientists and exhibitors from five sponsoring societies and multiple guest societies. With a mission to share the newest scientific concepts and research findings shaping clinical advances, the meeting offers an unparalleled opportunity for exchange among scientists from across the United States and the world who represent dozens of scientific areas, from laboratory to translational to clinical research.
About the American Physiological Society (APS)
Physiology is the study of how molecules, cells, tissues and organs function in health and disease. Established in 1887, the American Physiological Society (APS) was the first U.S. society in the biomedical sciences field. The Society represents more than 10,500 members and publishes 15 peer-reviewed journals with a worldwide readership. http://www.the-aps.org