Blood-based
neuronally-derived exosomes carry tell-tale proteins that could help forecast transition
from mild cognitive impairment to Alzheimer’s
Newswise, July 8, 2016 — Researchers at University of
California San Diego School of Medicine say tiny micro-vesicle structures used
by neurons and other cells to transport materials internally or dispose of them
externally carry tell-tale proteins that may help to predict the likelihood of
mild cognitive impairment (MCI) developing into full-blown Alzheimer’s disease
(AD).
The findings, published online this week in the journal Alzheimer’s
& Dementia, represent a quicker and less invasive way to identify
impending cognitive decline and begin treatment before progression to
established, irreversible dementia.
“MCI is often a transitional stage between normal aging and
dementia,” said senior author Robert A. Rissman, PhD, associate professor in
the Department of Neurosciences at UC San Diego School of Medicine, director of
the Biomarker Core for the Alzheimer’s Disease Cooperative Study (ADCS) and director
of the Neuropathology Core and Brain Bank for the UC San Diego Shiley-Marcos
Alzheimer’s Disease Research Center.
“It’s associated with more minor cognitive impairment and
carries an increased risk of developing Alzheimer’s dementia.”
MCI patients progress to AD at rates as high as 10 to 15
percent per year, prompting an increased emphasis upon diagnosing MCI early and
developing treatments that can delay or prevent conversion to AD.
The need is underscored, write the authors, by the fact that
clinical trials of treatments for established AD have thus far failed.
While clinically distinguishable from normal aging and AD, MCI
remains nonetheless a complex condition with many and varied causes.
“That has prompted great interest in pinpointing underlying
biomarkers that can predict the conversion from MCI to AD dementia,” said
Rissman.
“Finding such biomarkers would also identify persons most
likely to be responsive to preventive treatments.”
Currently, the accepted methods for diagnosing preclinical AD patients
is to detect protein biomarkers found in cerebrospinal fluid (CSF), in
combination with advanced neuroimaging and neuropsychological testing.
But CSF sampling involves an invasive, often painful, process.
Neuroimaging is expensive. Neuropsychological testing is time-consuming and can
often vary from visit to visit.
The new method described in the Alzheimer’s &
Dementia study evaluated the potential of exosomes – extremely small
vesicles or sacs found in most cell types, including neurons. Exosomes are
thought to move materials inside cells and are used to dump cellular trash into
the bloodstream for disposal.
In the case of disease, Rissman’s group predicted that
neuronal derived exosomes (NDEs) would carry damaged or excess proteins and
metabolites out of brain cells, among them amyloid and tau biomarker proteins
that are strongly associated with AD.
The researchers harvested NDEs from human blood plasma of 60
patients who participated in an 18-month ADCS clinical trial that enrolled MCI
patients only.
Some of these MCI patients converted to AD over the course of
the study and some did not. Rissman’s lab also gathered samples from control
patients and samples from known AD patients.
They enriched the NDE content of those originating from
neurons. The samples represented patients with normal cognitive function,
diagnoses of stable MCI and stable AD and patients who had recently
transitioned from MCI to AD.
After characterizing NDEs by size, shape and concentration,
the researchers compared that data with the different patient cohorts.
They found that NDEs carried targeted biomarker proteins,
which have previously been found to predict development of AD up to 10 years
before onset of clinical symptoms, and correctly distinguished 100 percent of
patients with AD from normal cohorts.
Moreover, the researchers showed for the first time that
plasma NDEs from AD and MCI patients may propagate tau tangles in the brains of
normal mice similar to what is seen in human AD brains.
The fact that these NDEs could induce pathological-like
structures in “naïve” mice (animals not previously subjected to experiments)
suggests that the contents of NDEs are bioactive, said Rissman. It also
suggests that released NDEs can be taken up by cells, raising the possibility
of NDEs potential for drug delivery.
The development of blood-based biomarkers for AD (and other
neurodegenerative diseases) diagnostics could significantly improve the
effectiveness and reliability of patient care and future research, said the
authors, who encouraged further studies to refine and validate the approach.
Co-authors include Charisse N. Winston, Bob C. Carter, Edward
M. Rockenstein, Douglas Galasko and Eliezer Masliah, all at UC San Diego; and
Edward J. Goetz and Johnny C. Akers, UC San Francisco.
Funding for this research came, in part, from the National
Institutes of Health (grants AG04484, BX003040, AG0051839), the Alzheimer’s
Association and the Alzheimer’s Art Quilt Initiative.
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