by Temple University

Study led by Temple researchers reveals new link between Down syndrome and Alzheimer's

Domenico Praticò, M.D. Credit: The Lewis Katz School of Medicine at Temple University

Individuals with Down syndrome who survive into adulthood face the additional challenge of early-onset dementia, in which toxic amyloid plaques build up in the brain. The condition is strikingly similar to Alzheimer's disease, and as new work led by researchers at the Lewis Katz School of Medicine at Temple University (LKSOM) shows, dementia in Down syndrome involves defects in a regulatory enzyme known as γ-secretase activating protein (GSAP), which also happens to malfunction in Alzheimer's disease.

In the field of Down syndrome research, the new findings are groundbreaking, and according to Domenico Praticò, MD, Professor in the Departments of Pharmacology and Microbiology and the Center for Translational Medicine at LKSOM and senior investigator on the study, the work could soon lead to the development of a specific GSAP-targeted therapy that is capable of safely mitigating dementia in Down syndrome. Previous γ-secretase inhibiting drugs failed in patients because of their high intrinsic toxicity.

The study, which appeared online in the Annals of Neurology, is the first to draw a connection between GSAP hyperactivity and excess processing of the Aβ precursor protein (APP) - the protein responsible for the final formation of amyloid beta - in Down syndrome. Dr. Praticò and colleagues made the discovery after examining donated tissue from the brains of deceased Down syndrome patients. Relative to postmortem brain tissue from healthy subjects, the samples from individuals with Down syndrome showed substantially elevated levels of both GSAP protein and its activity.

Dr. Praticò's team also found that GSAP hyperactivity was associated with abnormalities in the GATA1 transcription factor, which controls GSAP production. They demonstrated that when GATA1 activity was silenced in neurons that overexpressed APP, both GSAP levels and amyloid beta peptide levels increased. Overexpression of GATA1, on the other hand, produced the opposite effect.

In Down syndrome, APP overexpression is extreme, reaching levels in the brain that are four to five times higher than normal. Its excess levels are a direct consequence of the triplicate copy of the 21st chromosome, which not only causes the syndrome in the first place but also houses the APP gene.

"The higher levels of APP in Down syndrome patients causes increased formation of amyloid beta peptides which then precipitate in the amyloid plaques in the brain much earlier in life," Dr. Praticò explained. "Amyloid plaques begin to form in the brain of Down syndrome patients in the late teens and early 20s." Symptoms of dementia emerge in the following years.

The new findings could mark a turning point for Down syndrome survivors. "We've shown that GSAP inhibition reduces amyloid production, and because GSAP is specific to the formation of amyloid, without affecting other pathways, it should be a safe alternative to other strategies of a direct γ-secretase inhibition," Dr. Praticò said.

Dr. Praticò and colleagues already have access to a GSAP inhibitor. They plan next to investigate the effects of the agent in preclinical studies in mice. "We are very optimistic that our animal models will work," he said. "If they do, we will move to a clinical trial, where we hope to be able to reduce amyloid production safely and effectively."

More information: Annals of Neurology: onlinelibrary.wiley.com/doi/10.1002/ana.24540/pdf

Journal information: Annals of Neurology 

Provided by Temple University