Posts tagged phosphorylated tau
Articles and news from the latest research reports.
Study explores genetics behind Alzheimer’s resiliency
Autopsies have revealed that some individuals develop the cellular changes indicative of Alzheimer’s disease without ever showing clinical symptoms in their lifetime.
Vanderbilt University Medical Center memory researchers have discovered a potential genetic variant in these asymptomatic individuals that may make brains more resilient against Alzheimer’s.
“Most Alzheimer’s research is searching for genes that predict the disease, but we’re taking a different approach. We’re looking for genes that predict who among those with Alzheimer’s pathology will actually show clinical symptoms of the disease,” said principal investigator Timothy Hohman, Ph.D., a post-doctoral research fellow in the Center for Human Genetics Research and the Vanderbilt Memory and Alzheimer’s Center.
The article, “Genetic modification of the relationship between phosphorylated tau and neurodegeneration,” was published online recently in the journal Alzheimer’s and Dementia.
The researchers used a marker of Alzheimer’s disease found in cerebrospinal fluid called phosphorylated tau. In brain cells, tau is a protein that stabilizes the highways of cellular transport in neurons. In Alzheimer’s disease tau forms “tangles” that disrupt cellular messages.
Analyzing a sample of 700 subjects from the Alzheimer’s Disease Neuroimaging Initiative, Hohman and colleagues looked for genetic variants that modify the relationship between phosphorylated tau and lateral ventricle dilation — a measure of disease progression visible with magnetic resonance imaging (MRI). One genetic mutation (rs4728029) was found to relate to both ventricle dilation and cognition and is a marker of neuroinflammation.
“This gene marker appears to be related to an inflammatory response in the presence of phosphorylated tau,” Hohman said.
“It appears that certain individuals with a genetic predisposition toward a ‘bad’ neuroinflammatory response have neurodegeneration. But those with a genetic predisposition toward no inflammatory response, or a reduced one, are able to endure the pathology without marked neurodegeneration.”
Hohman hopes to expand the study to include a larger sample and investigate gene and protein expression using data from a large autopsy study of Alzheimer’s disease.
“The work highlights the possible mechanism behind asymptomatic Alzheimer’s disease, and with that mechanism we may be able to approach intervention from a new perspective. Future interventions may be able to activate these innate response systems that protect against developing Alzheimer’s symptoms,” Hohman said.
(Source: news.vanderbilt.edu)
New Alzheimer’s research suggests possible cause: the interaction of proteins in the brain
Research shows interaction of tau and amyloid-beta in the brain may cause cognitive decline
For years, Alzheimer’s researchers have focused on two proteins that accumulate in the brains of people with Alzheimer’s and may contribute to the disease: plaques made up of the protein amyloid-beta, and tangles of another protein, called tau.
But for the first time, an Alzheimer’s researcher has looked closely at not the two proteins independently, but at the interaction of the two proteins with each other — in the brain tissue of post-mortem Alzheimer’s patients and in mouse brains with Alzheimer’s disease. The research found that the interaction between the two proteins might be the key: as these interactions increased, the progression of Alzheimer’s disease worsened.
The research, by Hemachandra Reddy, Ph.D., an associate scientist at the Oregon National Primate Research Center at Oregon Health & Science University, is detailed in the June 2013 edition of the Journal of Alzheimer’s Disease.
Reddy’s paper suggests that when the interaction between the phosphorylated tau and the amyloid-beta — particularly in its toxic form — happens at brain synapses, it can damage those synapses. And that can lead to cognitive decline in Alzheimer’s patients.
"This complex formation between amyloid-beta and tau — it is actually blocking the neural communication," Reddy said. "If we could somehow find a molecule that could inhibit the binding of these two proteins at the synapses, that very well might be the cure to Alzheimer’s disease."
To conduct the research, Reddy and his team studied three different kinds of mice, who had been bred to have some of the brain characteristics of Alzheimer’s disease, including having amyloid-beta and phosphorylated tau in their brains. Reddy also analyzed postmortem brain tissue from people who had Alzheimer’s disease.
Using multiple antibodies that recognize amyloid-beta and phosphorylated tau, Reddy and Maria Manczak, Ph.D., a research associate in Reddy’s laboratory, specifically looked for the evidence of the amyloid-beta and phosphorylated tau interactions. They found amyloid-beta/tau complexes in the human Alzheimer’s brain tissue and in the Alzheimer’s disease mouse brains. The Reddy team also found much more of those amyloid-beta/tau complexes in brains where Alzheimer’s disease had progressed the most.
Reddy found very little or no evidence of the same interaction in the “control” subjects — mice that did not have the Alzheimer’s traits and human brain tissue of people who did not have Alzheimer’s.
"So much Alzheimer’s research has been done to look at amyloid-beta and tau," Reddy said. "But ours is the first paper to strongly demonstrate that yes, there is an amyloid-beta/phosphorylated tau interaction. And that interaction might be causing the synaptic damage and cognitive decline in persons with Alzheimer’s disease."
Reddy and his lab are already working on the next crucial questions. One is to define the binding site or sites and exactly where within the neuron the interaction of amyloid-beta and tau first occurs. The second is to find a way to inhibit that interaction — and thus maybe prevent or slow the progression of Alzheimer’s.
Manczak was a co-author on the Journal of Alzheimer’s Disease article.
(Image: Shutterstock)