EMORY (US) — The same genetic mutation that makes it hard from fruit flies to climb and use their wings also appears to play a role in inherited intellectual disability in humans.
The flies can’t hold their wings tightly against their bodies, and have trouble with flying and climbing behaviors, because they have mutations in a gene called dNab2. In humans, mutations in the same gene (with a clunkier name, ZC3H14) have been found to cause intellectual disability (ID) in studies of some Iranian families. ID describes the condition that was previously called mental retardation.
The protein encoded by Nab2/ZC3H14 appears to be part of a group of proteins—including the one disrupted in fragile X syndrome—that regulate brain cell function by binding RNA.
Cross-species comparisons of Nab2/ZC3H14’s function are shedding light on how brain cells regulate genes by controlling the length of their RNA “tails.” The results are published in the Early Edition of the Proceedings of the National Academy of Sciences.
This unusual collaboration brought together investigators from Emory University, the Max Planck Institute for Molecular Genetics in Berlin, and the University of Social Welfare and Rehabilitation Sciences in Tehran.
At Emory, Anita Corbett, professor of biochemistry, had studied Nab2 in yeast since the 1990s. Her laboratory teamed up with Ken Moberg, assistant professor of cell biology, to look at the function of the gene in fruit flies. Study co-author Chang Hui Pak, a student in both Corbett’s and Moberg’s labs, generated flies with mutations in dNab2.
What made those flies easy to spot, next to regular flies, was that the mutant flies kept their wings stretched out. Healthy flies hold their wings folded together over their bodies. Several mutations that affect nerve or muscle development display this “wings held out” effect in flies, Moberg says.
“At this point, we didn’t know if it was a problem with the muscles connected to the wings, or with the nerve networks that control those muscles,” he says.
Unexpectedly, Corbett received an email in 2009 providing a flash of insight. Researchers in Berlin and Tehran had been studying families in Iran in which cousins marry, looking for genetic mutations that lead to intellectual disability.
“It has been more straightforward to find mutations that cause ID along the X chromosome, because they show up easily in boys—and they don’t need to have inherited the defective genes from both parents,” Moberg says. “Studying these families with blood-related parents is a way to explore new ground and learn more about genes on other chromosomes that can be linked to ID.”
The Berlin/Tehran team had found that a mutation in the ZC3H14 gene showed up in two independent family trees affected by intellectual disability. Affected individuals can be male or female and have “non-syndromic” intellectual disability, meaning that they don’t have altered anatomical development or other features such as autism.
The mutations in ZC3H14 in affected individuals don’t completely wipe out production of the protein. This may be why the consequences of the human mutation aren’t completely fatal. Puzzlingly, one form of the protein enriched in the brain is still there, but the forms of the protein found all over the body are gone.
“We suspect that the only reason these people are walking around is because that one isoform is still there,” Moberg says.
The discovery of the fly/human link has led to a bundle of new questions. The protein Nab2/ZC3H14 binds “poly-A tails” (flags the cell puts on RNA molecules when they’re ready to be decoded into protein). The protein restricts the length of the tails, which may be more important for some genes than others, Moberg says.
At Emory, scientists are studying the mutant flies to figure out more precisely what’s wrong with them: which cells in the fly’s brain are affected and what genes and processes go awry in these cells. Although the overall structure of the brain and nervous system in mutant flies looks okay, preliminary evidence suggests the mutation alters structures in the brain important for learning and memory. Collaborator Gary Bassell is collaborating with Corbett to engineer mice lacking the ZC3H14 gene.
“Although mice may better reflect the human situation, exploring the function of Nab2 in flies first allowed us to be quicker and nimbler in designing experiments,” Moberg says.
The Berlin/Tehran team is now examining how common mutations in ZC3H14 are in population groups outside Iran, and whether it can account for other forms of intellectual disability.
The research was supported by the National Institutes of Health, the German Federal Ministry of Education and Research, the Max Planck Innovation Fund, and the Iranian National Science Foundation.
More health news from Emory Univerity: http://emoryhealth.org