Why do psychiatric drugs help some, but not others? Study offers clues

The study also offers a closer look at where, precisely, in the brain things may go wrong with it, marking an important step toward more targeted and less harmful therapies.

"The ultimate goal is to find the kink in the armor of mental illness -- the proteins in the brain that we can specifically target without impacting other organs and causing side effects," says Charles Hoeffer, an assistant professor of integrative physiology at the Institute for Behavioral Genetics. "Personalization is also key. We need to stop hitting every mental illness with the same hammer."

Discovered in the 1970s and best known for its potential role in causing cancer when mutated, AKT has more recently been identified as a key player in promoting "synaptic plasticity." That's the brain's ability to strengthen connections between neurons in response to experience.

"Let's say you see a shark and you're scared and your brain wants to form a memory. You have to make new proteins to encode that memory," explains Hoeffer.

AKT is one of the first proteins to come online, cranking the gears up on a host of downstream proteins in that memory factory. Without it, researchers have suspected, we can't learn new memories or extinguish old ones to make room for new, less harmful ones.

Previous studies have linked mutations in the AKT gene to a host of problems, from schizophrenia and post-traumatic stress disorder to autism and Alzheimer's.

But, as Hoeffer's previous research has discovered, not all AKTs are created equal:

Different flavors, or isoforms, function differently in the brain. For instance, AKT2 found exclusively in the star-shaped brain cells called astroglia, is often implicated in brain cancer.

AKT3 appears to be important for brain growth and development. And AKT1, in combination with AKT2 in the prefrontal cortex of the brain, appears to be critical for learning and memory.

"These subtle differences could be really important if you wanted to personalize treatments for people," explains Marissa Ehringer, an associate professor of integrative physiology who partnered with Hoeffer on some of the research.

Three years in the making, the study adds an important new wrinkle to the story. Following National Institutes of Health guidelines that in the past six years began to require researchers to include both male and female animals in studies, it looked closely at how different gendered mice responded to the loss of various AKT isoforms.

"We found the difference between males and females to be so great it became the focus of our work," Hoeffer said. "It was like night and day."

For instance, male mice whose AKT1 was functioning normally, were much better than those missing the protein when it came to "extinction learning" -- replacing an old memory, or association, that's not useful any more. (Imagine letting go of the memory of your favorite route home from work because you've moved or disassociating a loud sound with danger).

For female mice, it didn't make much of a difference.

Far more research is needed and underway, but Hoeffer suspects many other key proteins in the brain share similar nuances -- with different flavors serving different purposes or acting differently in men and women.

With one in five U.S. adults living with mental illness and women as much as four times as likely to experience mental illness during their lifetimes, he hopes that by disentangling all those nuances, he can move the dial toward better, safer treatments.

"To help more people suffering from mental illness we need much more knowledge about the difference between male and female brains and how they could be treated differently," Hoeffer said. "This study is an important step in that direction."