Female brown anole lizards have figured out how to pass on the genes of large males they mate to their sons, and the genes of small males to their daughters, Dartmouth College biologists have discovered.
Female brown anoles (center) produce more sons via large sires (left) and more daughters via small sires (right).
Image © Science/AAAS
“The females of this species mate with several males, then produce more sons with sperm from large fathers, and more daughters with sperm from smaller fathers,” Dartmouth said in a statement about the research.
The researchers believe that the lizards do this to ensure that the genes from large fathers are passed on to sons, who stand to benefit from inheriting the genes for large size.
The study is published in the March 4 issue of Science Express, the advance online publication of the journal Science.
“This species has figured out a clever way to pass on genes with gender-specific effects on fitness,” said Bob Cox, the lead author on the paper and a post-doctoral researcher at Dartmouth. “Usually, when natural selection pulls genes in different directions for each gender, the species faces an evolutionary dilemma. But these lizards have solved this puzzle, they’ve figured out how to get the right genes into the right gender.”
Photo of anole lizards courtesy of Dartmouth
By manipulating opportunities for females to mate with males of different sizes, the researchers determined that females prefer larger males, Dartmouth said. “But, when the choice of partners was limited to small males, females minimized the production of sons,” the university said.
The researchers explain that the genes that make males more fit are often different from the genes that benefit females, “which presents a conundrum because males and females share most of their DNA. The valuable traits for one gender are not always the same for the other.”
“In an evolutionary sense, what’s good for the goose is not always good for the gander,” Cox said.
In these lizards, however, mothers can enhance the fitness of their offspring by manipulating their gender depending on the size of the father, Dartmouth said. To demonstrate this, Cox and Calsbeek measured the survival rates of sons and daughters over eight months when released to their natural habitat in The Bahamas.
“As we predicted, the survival of the male offspring increased if they had large fathers,” said Calsbeek. “But, we found that the survival of the daughters was not influenced by the size of the father. This suggests that the genetic benefits of large size are specific to sons.”
A female brown anole, Anolis sagrei, in the Bahamas.
Image © Science/AAAS
How do females control the gender of their progeny? “That’s the big question at this point,” Cox said. The researchers will continue their studies to learn more about the mechanisms involved in this most fundamental of all evolutionary processes, the struggle to pass on advantageous genetic material, Dartmouth said.
Cox’s co-author is Ryan Calsbeek, an assistant professor of biological sciences at Dartmouth.