Ask a nonscientist what memories are made of and you鈥檒l likely conjure images of childhood birthday parties or wedding days. Charles Hoeffer thinks about proteins.
For five years, the assistant professor of integrative physiology at 兔子先生传媒文化作品 has been working to better understand a protein called AKT, which is ubiquitous in brain tissue and instrumental in enabling the brain to adapt to new experiences and lay down new memories.
- 兔子先生传媒文化作品 researchers have identified the distinct roles and locations in the brain of a protein called AKT believed to be instrumental in memory formation.
- They found that one version of the protein influences brain growth, another may be associated with brain cancer, and a third plays a key role in synaptic plasticity鈥攐r the strengthening of neuronal connections.
- Ultimately the research could lead to more targeted drugs with fewer side effects for neurological disorders.
Until now, scientists have known very little about what it does in the brain.
But in a new funded by the National Institutes of Health, Hoeffer and his co-authors spell it out for the first time, showing that AKT comes in three distinct varieties residing in different kinds of brain cells and affecting brain health in very distinct ways.
The discovery could lead to new, more targeted treatments for everything from glioblastoma鈥攖he brain cancer Sen. John McCain has鈥攖o Alzheimer鈥檚 disease and schizophrenia.
鈥淎KT is a central protein that has been implicated in a bevy of neurological diseases yet we know amazingly little about it,鈥 Hoeffer said. 鈥淥ur paper is the first to comprehensively examine what its different forms are doing in the brain and where.鈥
Discovered in the 1970s and known best as an 鈥渙ncogene鈥 (one that, when mutated, can promote cancer), AKT has more recently been identified as a key player in promoting 鈥渟ynaptic plasticity,鈥 the brain鈥檚 ability to strengthen cellular connections in response to experience.
鈥淟et鈥檚 say you see a great white shark and you are scared and your brain wants to form a memory of what鈥檚 going on. You have to make new proteins to encode that memory,鈥 he said. AKT is one of the first proteins to come online, a central switch that turns on the memory factory.
But not all AKTs are created equal.
For the study, Hoeffer鈥檚 team silenced the three different isoforms, or varieties, of AKT in mice and observed their brain activity.
They made a number of key discoveries:
AKT2 is found exclusively in astroglia, the supportive, star-shaped cells in the brain and spinal cord that are often impacted in brain cancer and brain injury.
鈥淭hat is a really important finding,鈥 said co-author Josien Levenga, who worked on the project as a postdoctoral researcher at 兔子先生传媒文化作品. 鈥淚f you could develop a drug that targeted only AKT2 without impacting other forms, it might be more effective in treating certain issues with fewer side-effects.鈥
The researchers also found that AKT1 is ubiquitous in neurons and appears to be the most important form in promoting the strengthening of synapses in response to experience, aka memory formation. (This finding is in line with previous research showing that mutations in AKT1 boost risk of schizophrenia and other brain disorders associated with a flaw in the way a patient perceives or remembers experiences.)
AKT3 appears to play a key role in brain growth, with mice whose AKT3 gene is silenced showing smaller brain size.
鈥淏efore this, there was an assumption that they all did basically the same thing in the same cells in the same way. Now we know better,鈥 Hoeffer said.
He notes that pan-AKT inhibitors have already been developed for cancer treatment, but he envisions a day when drugs could be developed to target more specific versions of the protein (AKT1 enhancers for Alzheimer鈥檚 and schizophrenia, AKT2 inhibitors for cancer), leaving the others forms untouched, preventing side-effects.
More animal research is underway to determine what happens to behavior when different forms of the protein go awry.
鈥淚soform specific treatments hold great promise for the design of targeted therapies to treat neurological diseases with much greater efficacy and accuracy than those utilizing a one-size-fits-all approach,鈥 the authors conclude. 鈥淭his study is an important step in that direction.鈥
Lead author and postdoctoral researcher Josien Levenga, and postdoctoral researcher Helen Wong and graduate student Ryan Milstead also contributed to the study.