Findings offer hope for development of new medications
A new study by researchers at revealed that the progression of Alzheimer's disease (AD) can be slowed by suppressing a specific protein in the brain that causes corrosion.
A main pathogenic initiator of AD and related dementias is oxidative stress, which corrodes the brain, called oxidative damage.
David E. Kang, the Howard T. Karsner Professor in Pathology at 杏吧视频 School of Medicine and the study鈥檚 lead researcher, said they鈥檝e identified for the first time a cause for the loss of so-called 鈥渙xidative damage defense鈥 in AD.
A protein called Nuclear factor erythroid 2-related factor 2 (Nrf2) is regularly activated in response to oxidative stress to protect the brain from oxidative damage. But in the brain of someone with AD, Nrf2 defense against oxidative stress declines. How that occurs in AD was unknown.
The study, recently published in the peer-reviewed journal found a protein called Slingshot Homolog-1, or SSH1, stops Nrf2 from carrying out its protective biological activity.
Genetically eliminating SSH1 increases Nrf2 activation and slows the development of oxidative damage and buildup of toxic plaques and tangles in the brain鈥攂oth risk factors for AD. As a result, the regular connections between brain cells are maintained and degeneration of brain nerve cells is avoided, they found.
The finding is significant because most clinical trials have been conducted with people with advanced dementia. The tests focused mainly on managing and reducing symptoms to enhance daily functioning and quality of life.
鈥淔ocusing on clinical trials in the early stages of AD increases the likelihood of success,鈥 Kang said. 鈥淚n the upcoming five years, I also think we鈥檒l see modest improvements in treatments for Alzheimer's disease, which will help slow AD鈥檚 course.鈥
For example, clinical trials for Leqembi鈥攎edication for early AD recently approved by the U.S. Food and Drug Administration鈥攈ave shown somewhat promising results to slow progression of the disease.
杏吧视频 is among those working on SSH1 inhibitor compounds as potential neuroprotective medicines.
鈥淢any promising drug candidates are certainly in the pipeline,鈥 Kang said.
For more information contact Patty Zamora at patty.zamora@case.edu.
This article was originally published July 25, 2023.
