Molecular ‘Switch’ Reverses Chronic Inflammation And Aging
Chronic inflammation, which results when old age, stress or environmental toxins keep the body’s immune system in overdrive, can contribute to a variety of devastating diseases, from Alzheimer’s and Parkinson’s to diabetes and cancer.
Now, scientists at the University of California, Berkeley, have identified a molecular “switch” that controls the immune machinery responsible for chronic inflammation in the body. The finding, which appears online in the journal Cell Metabolism, could lead to new ways to halt or even reverse many of these age-related conditions.
“My lab is very interested in understanding the reversibility of aging,” said senior author Danica Chen, associate professor of metabolic biology, nutritional sciences and toxicology at UC Berkeley. “In the past, we showed that aged stem cells can be rejuvenated. Now, we are asking: to what extent can aging be reversed? And we are doing that by looking at physiological conditions, like inflammation and insulin resistance, that have been associated with aging-related degeneration and diseases.”
In the study, Chen and her team show that a bulky collection of immune proteins called the NLRP3 inflammasome — responsible for sensing potential threats to the body and launching an inflammation response — can be essentially switched off by removing a small bit of molecular matter in a process called deacetylation.
Overactivation of the NLRP3 inflammasome has been linked to a variety of chronic conditions, including multiple sclerosis, cancer, diabetes and dementia. Chen’s results suggest that drugs targeted toward deacetylating, or switching off, this NLRP3 inflammasome might help prevent or treat these conditions and possibly age-related degeneration in general.
“This acetylation can serve as a switch,” Chen said. “So, when it is acetylated, this inflammasome is on. When it is deacetylated, the inflammasome is off.”