Study on mice has determined that the most pronounced changes occur in the white matter
A new study offers insight into the cognitive decline of normal ageing, shedding light on how ageing contributes to neurodegenerative conditions such as Alzheimer’s and Parkinson’s diseases. Most of us who have reached their middle age must have experienced a slowing memory and cognition. Until now, scientists did not have a clear picture of the molecular changes that take place in the brain to cause it.
Now, a study on mice has determined that
the most pronounced changes occur in the white matter, a type of nervous system
tissue that is integral to transmitting signals across the brain.
The study that identified a gene
"fingerprint" for brain ageing also examined two treatments — caloric
restriction and infusions of plasma from young mice — that affect certain
regions of the brain, with the plasma appearing to slow the age-related memory
decline.
In many neurodegenerative diseases,
certain areas of the brain are more vulnerable to damage, but there was a lack
of clarity on the exact reason.
“I saw this study as a way to explain
that somewhat mysterious regional vulnerability,” said Tony Wyss-Coray, PhD, a
neurology professor who led the study that examined gene expression in
different regions of the mouse brain as it matures.
This study by Stanford scientists was
published on August 16 in Cell journal.
The research team sampled 15 regions in
both hemispheres of the brains of 59 female and male mice aged 3 to 27 months.
They identified and ranked the top genes expressed by cells found in each
region of the brain and identified 82 genes that are found frequently and vary
in concentration in 10 or more regions.
The team used these genes to develop a
common ageing score, assessing how gene activity in different regions of the
brain change with age.
The researchers found that white matter,
which is found deep in the brain and contains nerve fibres protected by
white-coloured myelin, showed the earliest and most pronounced changes in gene
expression for mice 12 and 18 months old. According to Wyss-Coray, these mice
are about as old, in mouse years, as a person in their 50s.
Past work has shown that ageing disrupts
an otherwise stable gene expression pattern in the brain, turning on genes that
regulate inflammation and the immune response, and turning off genes
responsible for protein and collagen synthesis. The inflammation and immune
response affect the integrity of the myelin sheath, the insulation layer around
nerves responsible for transmitting signals across the brain.
“White matter has been a rather
neglected area in ageing research, which usually focuses on the neuron-dense
regions like the cortex or hippocampus,” Hahn said. “The fact that white matter
is emerging in our data as an area of particular vulnerability to ageing opens
up new and intriguing hypotheses.” Interventions to slow the genetic shift that
leads to the decline in specific regions of the brain could be beneficial in
addressing neurodegenerative disease as well as the general decline associated
with ageing.
During the study, the team explored two
interventions — caloric restriction and injections of plasma from young mice —
to evaluate whether they protected against the region-specific shifts in gene
expression. Each intervention began when the mice were 19 months old and lasted
four weeks.
The researchers found that the dietary intervention
caused genes associated with circadian rhythms to turn on, while the plasma
intervention turned on genes involved in stem cell differentiation and neuronal
maturation led to a selective reversal of age-related gene expression.
“The interventions appeared to act on
very different regions in the brain and [induce] strikingly different effects,”
Hahn said. “This suggests that there are multiple regions and pathways in the
brain that have the potential to improve cognitive performance in old age.” The
team also examined age-related changes in genes associated with three
neurodegenerative diseases — Alzheimer's disease, Parkinson's disease and
multiple sclerosis — that typically affect specific regions of the brain. The
expression distribution for each gene had changed in older animals and occurred
in regions of the brain that are not typically associated with a particular
neurodegenerative condition. This finding could offer insight into the vast
number of patients who have neurodegenerative diseases without a firm genetic
link.
The study could also offer new
opportunities to explore treatments and interventions by using the gene
expression data to zero in on the cell populations vulnerable to ageing. Future
studies could explore how gene expression leads to functional changes in
neuronal activity and structure.
Wyss-Coray and colleagues at the Knight
Initiative for Brain Resilience aim to expand on this work by building similar
genetic atlases of ageing in the human brain.
“The individual gene
changes observed in the mouse may not directly translate to humans,” Wyss-Coray
said. “But we believe the vulnerability of white matter to ageing probably
does.”
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