Brain activity has role in human aging and longevity
For the first time, scientists have shown that brain activity has a significant influence on human life span. In a new study, they demonstrate how neural activity is higher in individuals with shorter life spans and lower in those who live longer lives.
In a recent Nature paper, researchers from Harvard Medical School in Boston, MA, report how they found a distinct signature of human longevity in the genes of the brain's cerebral cortex.
The signature that they found is a pattern of gene expression that "is characterized by downregulation of genes related to neural excitation and synaptic function," write the authors.
Neural activity is to do with the amount of signaling — in the form of electrical currents and other transmitters — that is going on the brain. Too much neural activity, or excessive excitation, can present in various ways, such as a muscle twitch or a mood change.
For the study, the researchers performed cellular, genetic, and molecular experiments in worms. They also analyzed mice with altered genes and examined brain tissue from people who were more than 100 years old when they died.
These tests revealed not only that altering neural activity can influence life span, but they also gave clues on the molecular processes that might be involved.
"An intriguing aspect of our findings," says senior study author Bruce A. Yankner, a professor of genetics and neurology at Harvard Medical School, "is that something as transient as the activity state of neural circuits could have such far ranging consequences for physiology and life span."
Molecular influencers of longevity
Scientists have known for some time that neural activity affects a range of conditions, including epilepsy and dementia. However, while some animal studies have pointed to an effect on aging, it was not clear until now whether this influence might also extend to humans.
Signaling by the hormones insulin and insulin-like growth factor (IGF) are already well-known as molecular influencers of longevity. Scientists also believe that this is the same signaling pathway that caloric restriction works through.
The new findings reveal that neural excitation also influences longevity down this insulin and IGF signaling pathway. The key lies with a transcription factor called REST.
Transcription factors are proteins that switch genes on and off, that is, they control gene expression. In this way, the same sequence of genes can have quite different effects in cells, depending on which ones are on and which are off.
It is largely due to transcription factors and their control of gene expression that the cells of humans and other advanced organisms have such a huge repertoire of genetic reactions to their environment.
In previous work, Prof. Yankner and his team had already shown that REST helps to protect the brain from stressful effects that damage nerve cells, such as those that lead to dementia.