Fast facts:• A mutation in flies causes stem cells in the testes to make ovarylike cells.• The find sheds light on how cells can convert from one type to another, a tactic that may be useful for regenerating damaged organs or tissues.
Newswise — New research in flies shows how cells in adult reproductive organs maintain their sexual identity. The study, published online on Nov. 13 in Developmental Cell, also identified a mutation that can switch the cells’ sexual identity. The findings could lead to new insights on how to alter cells for therapeutic purposes.
Sperm and eggs are made from germ cells, but instructions from their neighboring support cells, called somatic cells, are also essential for their development. By studying the formation of sperm in fruit flies, which is remarkably similar to the process that occurs in people, investigators serendipitously found a mutation that gave testes a very unusual appearance. “Rather than becoming sperm, germ cells were stuck at an early stage, and they were surrounded by support cells that looked suspiciously like those belonging in an ovary,” says senior author Erika Matunis, Ph.D., a professor of cell biology at the Johns Hopkins University School of Medicine. Her research team found that the mutation blocked the function of a specific gene in the stem cells that become support cells in the testis, causing the fruit flies to change from male to female.
The research is the first to show that adult stem cells actively maintain their sexual identity. The mutation the investigators found causes the stem cells in males to switch their sexual identities and start making support cells that belong in the ovary. This ultimately derails the production of sperm. “The molecules that govern this process are highly conserved, which suggests that similar mechanisms could operate in human testes,” says Matunis.
The changes seen in this study are an example of transdifferentiation, or the conversion from one cell type to another. The topic is of considerable interest, because promoting transdifferentiation in a directed manner may be useful for regenerating damaged organs or tissues. Doing so will require a thorough understanding of how cell fate conversions are regulated. “We are excited to have a powerful genetic system for studying transdifferentiation of stem cells at the mechanistic level,” says Matunis. The research might also provide insights into how cells transform from a normal state to a cancerous one.
--text courtesy of Cell Press
Other authors on the paper were Qing Ma of The Johns Hopkins University and Matthew Wawersik of the College of William and Mary.
The study was funded by the National Institute of Child Health and Human Development (grant numbers HD040307 and HD052937).
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Developmental Cell; HD040307; HD052937