Aging
A study tying the aging process to the deterioration of tightly packaged bundles of cellular DNA could lead to methods of preventing and treating age-related diseases such as cancer, diabetes and Alzheimer's disease. |
Astudy tying the aging process to the deterioration of tightly packaged bundles of cellular DNA could lead to methods of preventing and treating age-related diseases such as cancer, diabetes and Alzheimer’s disease, as detailed in Science.
In the study, scientists at the Salk Institute and the Chinese Academy of Science found that the genetic mutations underlying Werner syndrome, a disorder that leads to premature aging and death like progeria, resulted in the deterioration of bundles of DNA known as heterochromatin.
The discovery, made possible through a combination of cutting-edge stem cell and gene-editing technologies, could lead to ways of countering age-related physiological declines by preventing or reversing damage to heterochromatin.
The top image shows normal human cells (left) and genetically modified cells developed by the Salk scientists to model Werner syndrome (right), which showed signs of aging, including their large size.
“Our findings show that the gene mutation that causes Werner syndrome results in the disorganization of heterochromatin, and that this disruption of normal DNA packaging is a key driver of aging,” says Juan Carlos Izpisua Belmonte, a senior author on the paper. “This has implications beyond Werner syndrome, as it identifies a central mechanism of aging–heterochromatin disorganization–which has been shown to be reversible.”
Werner syndrome is a genetic disorder that causes people to age more rapidly than normal. It affects around one in every 200,000 people in the United States. People with the disorder suffer age-related diseases early in life, including cataracts, type 2 diabetes, hardening of the arteries, osteoporosis and cancer, and most die in their late 40s or early 50s.
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"Accumulated alterations in the structure of heterochromatin may be a major underlying cause of cellular aging. This begs the question of whether we can reverse these alterations–like remodeling an old house or car–to prevent, or even reverse, age-related declines and diseases." |
This bundling of DNA acts as a switchboard for controlling genes’ activity and directs a cell’s complex molecular machinery. On the outside of the heterochromatin bundles are chemical markers, known as epigenetic tags, which control the structure of the heterochromatin. For instance, alterations to these chemical switches can change the architecture of the heterochromatin, causing genes to be expressed or silenced.
The Salk researchers discovered that deletion of the WRN gene leads to heterochromatin disorganization, pointing to an important role for the WRN protein in maintaining heterochromatin. And, indeed, in further experiments, they showed that the protein interacts directly with molecular structures known to stabilize heterochromatin–revealing a kind of smoking gun that, for the first time, directly links mutated WRN protein to heterochromatin destabilization.
“Our study connects the dots between Werner syndrome and heterochromatin disorganization, outlining a molecular mechanism by which a genetic mutation leads to a general disruption of cellular processes by disrupting epigenetic regulation,” says Izpisua Belmonte. “More broadly, it suggests that accumulated alterations in the structure of heterochromatin may be a major underlying cause of cellular aging. This begs the question of whether we can reverse these alterations–like remodeling an old house or car–to prevent, or even reverse, age-related declines and diseases.”
Izpisua Belmonte added that more extensive studies will be needed to fully understand the role of heterochromatin disorganization in aging, including how it interacts with other cellular processes implicated in aging, such as shortening of the end of chromosomes, known as telomeres. In addition, the Izpisua Belmonte team is developing epigenetic editing technologies to reverse epigenetic alterations with a role in human aging and disease.
SOURCE Salk Institute for Biological Studies
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