Scientists from Johns Hopkins University report that the amount of mitochondrial DNA (mtDNA) found in peoples' blood directly relates to how frail they are medically. This DNA may prove to be a useful predictor of overall risk of frailty and death from any cause 10 to 15 years before symptoms appear, according to the researchers.

The team says its findings contribute to the scientific understanding of aging and may lead to a test that could help identify at-risk individuals whose physical fitness can be improved with drugs or lifestyle changes. A summary of the study (“Association of mitochondrial DNA levels with frailty and all-cause mortality”) was published in the Journal of Molecular Medicine.

“We don't know enough yet to say whether the relationship is one of correlation or causation,” points outs Dan Arking, Ph.D., associate professor of genetic medicine. “But either way, mitochondrial DNA could be a very useful biomarker in the field of aging.”

Previous research from Dr. Arking's laboratory linked genetic differences in mtDNA to increased frailty and reduced muscle strength in older individuals. Medically speaking, frailty refers to a well-recognized collection of aging symptoms that include weakness, decreased energy, lower activity levels, and weight loss.

To further test this link, Dr. Arking's team analyzed the amount of mtDNA in blood samples collected for two large, human studies that began in the late 1980s and tracked individuals' health outcomes for 10 to 20 years. After calculating how much mtDNA each sample contained relative to the amount of nuclear DNA, the team looked at measures of frailty and health status gathered on the studies' participants over time.

On average, Dr. Arking says, subjects who met the criteria for frailty had 9% less mtDNA than nonfrail participants. And, when grouped by amount of mtDNA, white participants in the bottom one-fifth of the study population were 31% more likely to be frail than participants in the top one-fifth.

“In race-stratified meta-analyses, we observe a significant inverse association of mtDNA copy number with age and higher mtDNA copy number in women relative to men. Lower mtDNA copy number was also significantly associated with prevalent frailty in white participants from CHS (OR 0.91, 95 % CI 0.85–0.97),” wrote the investigators. “Additionally, mtDNA copy number was a strong independent predictor of all-cause mortality in an age- and sex-adjusted, race-stratified analysis of 16,401 participants from both cohorts with a pooled hazard ratio of 1.47 (95 % CI 1.33–1.62) for the lowest quintile of mtDNA copy number relative to the highest quintile.”

“It makes intuitive sense that decreased mtDNA is associated with bad health outcomes,” says Dr. Arking. “As we age, our energy reserves decrease, and we become more susceptible to all kinds of health problems and disease.”

The researchers also analyzed the age at which participants died. In one of the studies, high levels of mtDNA corresponded to a median of 2.1 extra years of life compared to those with the lowest levels of mtDNA.

Using data from both studies, the team found that those with mtDNA levels in the bottom one-fifth of the population were 47% more likely to die of any cause during the study period than were those in the top one-fifth. They also found that women had an average of 21% more mtDNA than men. According to Dr. Arking, this could play a small role in why women live two to four years longer than men on average.

Dr. Arking says that the research team would like to take repeated blood samples from individuals over several years to learn if and by how much mtDNA levels decrease over time. What the investigators saw in the current study is that, averaged over the population, an increase of 10 years in age corresponded to 2.5 percent less mtDNA.

The authors say they hope that mtDNA tests could detect people at risk of frailty 10 to 15 years before they begin to experience symptoms so that doctors can prescribe strength training or other interventions. If low numbers of mitochondria are shown to cause or contribute to frailty, the team can use their simple test on lab-grown cells to assess the effectiveness of new drugs to increase the numbers of mitochondria.

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