November
3, 2014
Northwestern
University
Summary:Aging is the most significant risk factor for developing
neurodegenerative diseases, and the risk increases disproportionately with age.
Now a team of scientists has uncovered some clues as to why. The researchers
are the first to find that the quality of protective genes called molecular
chaperones declines dramatically in the brains of older humans, both healthy
and not, and that the decline is accelerated even more in humans with
neurodegenerative disease.
Aging is the most significant and universal
risk factor for developing neurodegenerative diseases, such as amyotrophic
lateral sclerosis (ALS) and Alzheimer's, Parkinson's and Huntington's diseases.
This risk increases disproportionately with age, but no one really knows why.
Now
a team of scientists from Northwestern University, Proteostasis Therapeutics,
Inc. and Harvard University has uncovered some clues. The researchers are the
first to find that the quality of protective genes called molecular chaperones
declines dramatically in the brains of older humans, both healthy and not, and
that the decline is accelerated even more in humans with neurodegenerative
disease.
Molecular
chaperones are a special set of highly conserved genes that watch over cells,
keeping them and the entire organism healthy by preventing protein damage.
The
researchers specifically found the decline in 100 genes, approximately
one-third of all human molecular chaperone genes. Then, with additional
studies, they winnowed that number down to 28 human genes specifically involved
in age-associated neurodegeneration. These critical genes provide a basis for a
biomarker, an early indicator of disease and a target for new therapeutics.
"Imagine
if we had biomarkers that tell doctors how you are doing in terms of aging,
warning of any problems long before neurological deficits appear," said
Northwestern's Richard I. Morimoto, one of the senior scientists on the study.
"This would be a remarkable tool, especially considering the increases in
life expectancy in many parts of the world.
"Let's
say a person is age 50, but we see his molecular chaperones have declined and
aren't repairing proteins and cellular damage. The chaperones are acting more
like age 85 or 90. That's a sign that medical intervention could help," he
said.
Morimoto
is the Bill and Gayle Cook Professor of Biology in the Department of Molecular
Biosciences and director of the Rice Institute for Biomedical Research in
Northwestern's Weinberg College of Arts and Sciences.
"Molecular
chaperones really are the barrier we have between disease and no disease,"
Morimoto said. "If this critical system declines, it leads to misfolded
and damaged proteins, and eventually tissues become dysfunctional and die. If
we can keep the chaperones healthy, we should be able to keep the person
healthy."
The
study will be published in the Nov. 6 issue of the journal Cell Reports.
To
zero in on the subnetwork of 28 key genes, the scientists combined genomic
analysis of human brain tissue, from both healthy individuals and those with
neurodegenerative diseases (Alzheimer's, Parkinson's and Huntington's), with
functional studies of C. elegans, a transparent roundworm. (The worm has a
biochemical environment similar to that of human beings and is a popular
research tool for the study of human disease.)
"To
our surprise, the results from the studies of humans and C. elegans told us the
same thing -- 10 percent of the 332 human genes are really important to cell
health," Morimoto said. "Now we are down to 28 genes. This really
tells us what to focus on."
After
observing the dramatic decline in the health of molecular chaperones in humans
both healthy and with neurodegenerative disease, the researchers systematically
and individually "knocked down" all 219 chaperone genes in C. elegans
(using neurodegenerative disease models) to see what effect the gene's absence
had on an animal's function.
They
identified a subnetwork of 16 molecular chaperone genes in C. elegans that are
critical to preventing protein misfolding and damage to the cell. These genes
correspond to 28 human "cousin" genes.
Humans
encode approximately 25,000 genes, and getting any process down to a small
number of genes will help scientists put their fingers on what's most
important.
"It's
a lot easier to enhance a handful of genes, such as those we've
identified," Morimoto said. "The next step is to understand the basis
for the decline of these specific chaperones and to develop treatments that
prevent their decline. The goal is not to make people live forever but rather
to match health span more closely with life span -- to improve the quality of
life being lived."
Story Source:
The
above story is based on materials provided
by Northwestern University.
The original article was written by Megan Fellman. Note: Materials may
be edited for content and length.
Journal Reference:
1 Marc Brehme, Cindy
Voisine, Thomas Rolland, Shinichiro Wachi, James H. Soper, Yitan Zhu, Kai
Orton, Adriana Villella, Dan Garza, Marc Vidal, Hui Ge, Richard I.
Morimoto. A Chaperome Subnetwork Safeguards Proteostasis in Aging and
Neurodegenerative Disease. Cell Reports, 2014; DOI: 10.1016/j.celrep.2014.09.042
Cite This Page:
Northwestern
University. "Even when you're older, you need chaperones: Protective genes
reduce as we age." ScienceDaily. ScienceDaily, 3 November 2014.
<www.sciencedaily.com/releases/2014/11/141103114238.htm>.
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