If your grandparents were able to celebrate their 90th birthday there’s a good chance you might do the same.
Our age is determined partly by our genes – not only how long we live, but also how we well we are, physically and psychologically.
That some people become really old while others don’t even reach pension age is determined partly by inherited molecular variations in the DNA code in our genes.
A Danish researcher has now studied the genetic variations that make people live longer.
“The study shows that small variations in our genetic code give large differences in how long we live and in the quality of our old age,” says Mette Sørensen, of the epidemiology research unit of the Institute of Public Health at the University of Southern Denmark, who has just defended her PhD thesis on the importance of genetic processes for the length of our lives.
Sørensen studied variations in the genes behind three of the body’s systems that influence the length of our lives:
Sørensen studied 168 genes for variations in a control group of middle-aged people and a test group comprising people aged 92 or over.
How long we live is decided by our environment (75 percent) and by our genes (25 percent).
With knowledge of the genetic variations that decide whether we live longer or shorter lives, tomorrow’s doctors will be able to find out whether people run the risk of developing diseases such as cardiovascular diseases or Alzheimer’s disease, which can arise as we get older.
The result showed that specific variations of 23 genes are more prevalent in the elderly part of the population and can potentially influence the length of their lives.
That a genetic variation is more prevalent in the elderly part of the population than in the population generally is a good indicator of the influence the genetic variation has had for people living longer.
A variation in the Foxo3 gene is particularly interesting. Foxo3 is part of the collection of genes that control insulin signalling, and specific variations of this gene are very common in people who live a long time.
“We are convinced that the Foxo3 gene has an influence on lengths of peoples’ lives,” says Sørensen.
“People who have Foxo3 genetic variations with an over-representation of a certain nucleotide [see Factbox] live longer than average. We can see that in the genetic material from the test group of people over 92 years old. But we don’t yet know why.”
The researcher underlines that people do not necessarily live longer simply because they have the specific Foxo3 genetic variation – there are far too many other factors that play a role.
Although the researchers can see that a specific variation of a gene means we live longer, there is little that can be done today for the people who do not have this genetic variation and are thus at risk of having a shorter life.
Nucleotides are the building blocks of DNA. The DNA contains four types of nucleotides, and sets of three are needed to decode the body’s cells. Replacing one nucleotide type by another can change the way in which a protein is constructed. The protein can still function, but it can also change processes in the body that influence the length of our lives.
But that may change in the future.
With knowledge of the genetic variations that increase the risk of developing diseases – such as cardiovascular diseases or Alzheimer’s disease – that can shorten our lives, or reduce the quality of our lives, doctors in the future can examine patients for such genetic variations and start treating them far earlier.
Sørensen continues her work of generating an overview of the genetic variations in the body’s processes that have influence on how long we live.
She will do this as part of a research group at the University of Southern Denmark. The researchers will also study the whole genome in their hunt for genetic variations that are over-represented in the eldest members of the population and which can potentially determine how old we will be and the quality of our life.
“This isn’t just a matter of getting old, but also of getting old with a good quality of life,” she says. “In many processes it is therefore relevant to study the underlying genetics.”
Read this story in Danish at videnskab.dk