Research could lead to new biomarkers that detect Alzheimer’s much earlier than existing tests and help scientists understand why some people with the disease do not develop dementia
Key biomarkers for detecting the progression of Alzheimer’s disease have typically been based on amyloid-beta (Aβ) plaques. But these plaques show up after the disease has well-progressed and aren’t suited to early detection of the disease.
Now, researchers at the University of Pittsburgh School of Medicine (Pitt) have developed a cerebrospinal fluid (CFS) test that detects changes in tau protein prior to the formation of neurofibrillary tangles (NFTs) that proceed Aβ plaques.
With further research, Pitt’s test could lead to new clinical laboratory biomarkers that help detect the disease earlier and with more accuracy.
“The clumping of tau protein into well-ordered structures, referred to by pathologists as neurofibrillary tangles, is a more defining event for Alzheimer’s disease as it is more strongly associated with the cognitive changes,” as compared to amyloid-beta pathology, according to a Pitt news release.
The researchers showed that their CSF biomarker test worked independent of discovery of brain amyloid deposits and “correlates with severity of cognitive decline” to enable “early-stage disease diagnosis and intervention,” reported Genetic Engineering and Biotechnology News.
“Our test identifies very early stages of tau tangle formation—up to a decade before any tau clumps can show up on a brain scan,” said Thomas Karikari, PhD (above), senior author and assistant professor of psychiatry at Pitt, in a news release. (Photo copyright: University of Pittsburgh.)
Combining Biomarkers May Lead to Better Alzheimer’s Knowledge
The new biomarkers may also work with existing markers that detect amyloid-beta pathology. This could give researchers and healthcare providers a better understanding of the early stages of Alzheimer’s in specific patients.
“Amyloid-beta is a kindling, and tau is a matchstick,” said Thomas Karikari, PhD, senior author and assistant professor of psychiatry at Pitt. Karikari previously researched amyloid-beta.
“A large percentage of people who have brain amyloid-beta deposits will never develop dementia. But once the tau tangles light up on a brain scan, it may be too late to put out the fire, and their cognitive health can quickly deteriorate. Early detection of tangle-prone tau could identify the individuals who are likely to develop Alzheimer’s-associated cognitive decline and could be helped with new generation therapies,” he added.
“P-tau-217 and p-tau-181 are fantastic biomarkers. However, in the early days after we developed these markers, we wondered why they were much more reflective of amyloid pathology than tau pathology,” Karikari told MedPage Today.
“That’s what inspired this work. We believe that methods combining, say, p-tau-217 and p-tau-262 or 356, would provide more complete information on combined early-stage amyloid and tau pathologies in Alzheimer’s disease,” he noted.
Developing the Alzheimer’s Biomarker Test
Karikari and colleagues turned to biochemistry and molecular biology to develop their new test.
Specifically, they emphasized “building blocks of NFTs including oligomers and protomers” which they called “soluble tau assemblies,” Medical News Today explained.
According to the Pitt news release, using autopsied brain tissue, the researchers found:
A core region of the tau protein where NFTs form.
111 amino acids in the region.
New “phosphorylation sites of p-tau-262 and p-tau-356 can inform the status of early-stage tau aggregation that, with an appropriate intervention, could potentially be reversed.”
In other words, p-tau-262 and p-tau-356 “could predict future NFT production, making them potential biomarkers for early disease,” Medical News Today noted.
“Together, our findings inform about the status of early-stage tau aggregation, reveal aggregation-relevant phosphorylation epitopes in tau, and offer a diagnostic biomarker and targeted therapeutic opportunities for Alzheimer’s disease,” the authors wrote in Nature Medicine.
More Research Planned Before Clinical Lab Use
About seven million Americans are affected by Alzheimer’s, according to the Alzheimer’s Association, which expects that number to grow to 13 million by 2050. A cure for the disease does not exist.
More research is needed before the Pitt researchers’ new CSF assay can be used by clinical laboratories. Karikari said the next step is developing blood assays for the biomarkers, MedPage Today reported.
Study findings may lead to new clinical laboratory tests, as well as vaccines and immunotherapies for neurodegenerative diseases
Research into the human genome continues to produce useful new insights. This time, a study led by researchers at Stanford University identified a genetic variation that is believed to help “slow or even stall” progression of neurodegenerative diseases, including Alzheimer’s and Parkinson’s, according to a press release. Because these genetic variations are common, it is likely that diagnostic tests can be developed for use by clinical laboratories.
Researchers at Stanford Medicine led the study which discovered that approximately one in five individuals carry the gene variant, a protective allele identified as DR4 (aka, HLA-DR4). It’s one of a large number of alleles found in a gene known as DRB1.
DRB1 is part of a family of genes collectively known as the human lymphocyte antigen complex or HLA. The HLA-DRB1 gene plays a crucial role in the ability of the immune system to see a cell’s inner contents.
“In an earlier study, we’d found that carrying the DR4 allele seemed to protect against Parkinson’s disease,” said Emmanuel Mignot, MD, PhD (above), Director of the Stanford Center for Narcolepsy, in a Stanford press release. “Now, we’ve found a similar impact of DR4 on Alzheimer’s disease.” Clinical laboratories may soon have new vaccines for both neurodegenerative diseases. (Photo copyright: Stanford University.)
DR4 Found to Impact Both Parkinson’s and Alzheimer’s Diseases
To perform their research, the team examined a large collection of medical and genetic databases from 176,000 people who had either Alzheimer’s or Parkinson’s disease. The people involved in the study were from numerous countries located in East Asia, Europe, the Middle East and South America. Their genomes were then compared with people who did not have the diseases, focusing on the incidence and age of onset.
“In an earlier study we’d found that carrying the DR4 allele seemed to protect against Parkinson’s disease,” said Mignot in the Stanford press release. “Now, we’ve found a similar impact of DR4 on Alzheimer’s disease.”
The team found that about 20% to 30% of people carry DR4, and that they have around a 10% risk reduction for developing the two diseases.
“That this protective factor for Parkinson’s wound up having the same protective effect with respect to Alzheimer’s floored me,” said Emmanuel Mignot, MD, PhD, the Craig Reynolds Professor of Sleep Medicine in the Department of Psychiatry and Behavioral Sciences at Stanford University and the Director of the Stanford Center for Narcolepsy, in the Stanford Medicine press release. “The night after we found that out, I couldn’t sleep.”
The scientists also analyzed data from autopsied brains of more than 7,000 Alzheimer’s patients and discovered that individuals who carry DR4 had fewer neurofibrillary tangles and that those tangles are composed mainly of modified tau proteins, a common biomarker for Alzheimer’s.
The presence of these tangles corresponds with the severity of Alzheimer’s disease. They are not typically seen in Parkinson’s patients, but the Stanford team found that Parkinson’s patients who did carry DR4 experienced later onset of symptoms.
Mignot stated that tau, which is essential in Alzheimer’s, may also play a role in Parkinson’s, but that further research is required to prove its function.
Both diseases are characterized by the progressive loss of certain nerve cells or neurons in the brain and are linked to an accumulation of abnormal proteins. The Stanford researchers suggested that the DR4 gene variant may help protect individuals from Alzheimer’s and Parkinson’s by preventing the buildup of tau proteins.
“This is a very interesting study, providing additional evidence of the involvement of the immune system in the pathogenesis of Alzheimer’s and Parkinson’s,” neurologist Wassim Elyaman, PhD, Assistant Professor of Neurological Sciences in Neurology, the Taub Institute and the Institute for Genomic Medicine at Columbia University, told Live Science.
New Vaccines and Immunotherapies
According to the Alzheimer’s Association, more than six million Americans are currently living with Alzheimer’s disease and approximately one in three Americans die with Alzheimer’s or another dementia.
The Parkinson’s Foundation states that nearly one million Americans are currently living with Parkinson’s disease, and that number is expected to rise to 1.2 million by 2030. Parkinson’s is the second-most common neurodegenerative disease after Alzheimer’s disease.
Even though the genetic analysis of the Stanford research is strong, more immune cell and blood-based research is needed to definitively establish how tau is connected to the two diseases.
This research could have implications for clinical laboratories by giving them biomarkers for a useful new diagnostic test, particularly for diagnosing Alzheimer’s and Parkinson’s.
Further, Mignot suggested that an effective vaccine could delay the onset or slow the progression of both diseases. He hopes to test his hypothesis on genetically modified mice and eventually human subjects.
