Researchers in California and Saudi Arabia have identified a potential treatment target for progeria, more commonly known as premature aging disease, and demonstrated proof of concept by extending the life of mice with similar characteristics.
Progeroid syndromes, which include Hutchinson-Gilford progeria syndrome and Werner syndrome, cause accelerated aging in children and adolescents. Patients develop not only striking physical appearances but also symptoms and diseases typically associated with older age, such as heart disease, cataracts, type 2 diabetes, osteoporosis and cancer. There are currently no effective treatments for progeroid syndromes.
Search Antibodies Search Now Use our Antibody Search Tool to find the right antibody for your research. Filter
by Type, Application, Reactivity, Host, Clonality, Conjugate/Tag, and Isotype.
But new research from Salk Institute for Biological Studies and King Abdullah University of Science and Technology (KAUST) and reported in the journal Science Translational Medicine has located a stretch of DNA that hops around the human genome and plays a role in such premature aging disorders. They found that in people with progeria, RNA known as LINE-1, which is encoded by this mobile DNA, builds up inside cells.
One of the molecular signatures of both normal aging and progeroid syndromes is the altered overall organization of DNA. When DNA is packaged differently into the nuclei of cells, it changes which genes are accessible for the cell to use and can therefore drastically change a cell’s behavior and function. They also knew that human genomes contain hundreds of LINE-1 elements that propagate and move around the genome, as well as encode LINE-1 RNA. The function of these elements is poorly understood, but they change and multiply with age, as well as in diseases including cancer and cardiovascular disease. The research team wondered whether they also play a role in progeroid syndromes.
“The repeat sequences like LINE-1 make up a large percentage of our genomes, but not much attention is paid to the effects of LINE-1 RNA that increase with age in the nuclei,” says co-first author Pradeep Reddy, a former Salk staff scientist and current principal scientist at Altos Labs.
The researchers studied cells derived from patients with progeroid syndromes and found that they had four to seven times more LINE-1 RNA than cells from healthy individuals. Moreover, they showed that the accumulation of LINE-1 RNA came before the major structural changes to DNA that were already associated with progeria.
The team then developed molecules that could specifically bind to LINE-1 RNA, preventing the RNA from accumulating and impacting the cells. This kind of treatment reversed the molecular signs of progeria in isolated cells and extended the life span of mice with genetic mutations that typically cause premature aging. In both cases, the expression of genes associated with cell proliferation and DNA structure increased after treatment, while the expression of genes associated with aging, inflammation and DNA damage decreased.
“Targeting LINE-1 RNA may be an effective way to treat progeroid syndromes, as well as other age-related diseases that have been connected to LINE-1, including neuropsychiatric, eye, metabolic disorders and cancers,” says Juan Carlos Izpisua Belmonte, a professor in Salk’s Gene Expression Laboratory and director of the Altos Labs San Diego Institute of Science. “Eventually, we think that this approach may lead to treatments to help extend human health span.”
The researchers are planning future studies to better understand what causes the accumulation of LINE-1 RNA and how it can be prevented with drugs in human patients. A patent application for the current work targeting the LINE-1 RNA has been filed.