“Several species of fish—and in particular coral reef fish—are able to swap their sex during their lifespan,” explained Timothy Ravasi, KAUST Professor of Bioengineering from the University's Environmental Epigenetics Program. “This is known as sequential hermaphroditism.”
Such characteristics can render fish communities more resilient to disruptions that might otherwise prove catastrophic to their reproductive capabilities. One fish species is able to adjust the gender ratio of its population through changes at the molecular level in response to changing environmental conditions1. Clownfish “families” normally comprise one mature male and female plus numerous juveniles. If the female disappears, the remaining male alters hormone levels to transform into a female, restoring the previous gender balance.
The precise biology of this is unclear, and Ravasi and his KAUST colleagues set out to identify changes in gene expression within the brain and gonads that drive this process of sequential hermaphroditism. They compared gene activity profiles from fully developed males and females as well as males at multiple stages of the process.
After two weeks of being separated from a female, the researchers detected clear changes in gene expression within the brains of males that apparently herald the onset of gender transition, and complementary changes in gonadal gene expression became apparent a few weeks later.
The researchers were subsequently able to map the genetic machinery driving this process.
“We identified a large number of candidate molecular pathways that are potentially able to fine-tune and therefore control the gender ratio in a population of fish,” noted Ravasi.
One key candidate is a gene encoding an enzyme called aromatase, which is known to be involved in the production of estrogen. Aromatase was highly expressed in both the brain and the gonads of fish adapting to gender ratio alterations. Ravasi and the research team also found many other genes that are likely to interact with aromatase in managing the degeneration of the testes and the development of the ovaries.
With these foundational insights into this complex biological process, Ravasi now hopes to explore how this adaptive process is influenced by environmental factors and specifically climate change.
“We are not sure whether the ocean’s warming and acidification can influence the tightly controlled regulation of gender ratio changes,” he said. “We are systematically exposing the fish to end-of-century predicted ocean conditions and trying to understand whether climate change alters these molecular pathways.”