Capacity for exercise can be inherited, UC Riverside biologists find

RIVERSIDE, Calif. — Biologists at the University of California, Riverside have found that voluntary activity, such as daily exercise, is a highly heritable trait that can be passed down genetically to successive generations.

Working on mice in the lab, they found that activity level can be enhanced with “selective breeding” — the process of breeding plants and animals for particular genetic traits. Their experiments showed that mice that were bred to be high runners produced high-running offspring, indicating that the offspring had inherited the trait for activity.

“Our findings have implications for human health,” said Theodore Garland Jr., a professor of biology, whose laboratory conducted the multi-year research. “Down the road people could be treated pharmacologically for low activity levels through drugs that targeted specific genes that promote activity. Pharmacological interventions in the future could make it more pleasurable for people to engage in voluntary exercise. Such interventions could also make it less comfortable for people to sit still for long periods of time.”

In humans, activity levels vary widely from couch-potato-style inactivity to highly active athletic endeavors.

“We have a huge epidemic of obesity in Western society, and yet we have little understanding of what determines variation among individuals for voluntary exercise levels,” Garland said.

Study results appear online Sept. 1 in the Proceedings of the Royal Society B.

The researchers began their experiments in 1993 with 224 mice whose levels of genetic variation bore similarity to those seen in wild mouse populations. The researchers randomly divided the base population of mice into eight separate lines — four lines bred for high levels of daily running, with the remaining four used as controls — and measured how much distance the mice voluntarily ran per day on wheels attached to their cages.

With a thousand mice born every generation and four generations of mice each year, the researchers were able to breed highly active mice in the four high-runner lines by selecting the highest running males and females from every generation to be the parents of the next generation. In the control lines, breeders were chosen with no selection imposed, meaning that the mice either changed or did not change over time purely as a result of random genetic drift.

By studying the differences among the replicate lines, the researchers found that mice in the four high-runner lines ran 2.5-3-fold more revolutions per day as compared with mice in the four control lines. They also found that female and male mice evolved differently: females increased their daily running distance almost entirely by speed; males, on the other hand, increased speed but they also ran more minutes per day.

The study is an example of an “experimental evolution” approach applied rigorously to a problem of biomedical relevance. Although this approach is common with microbial systems and fruit flies, it has rarely been applied to vertebrates due to their longer generation times and greater costs of maintenance. The results of such studies can inform biologists about fundamental evolutionary processes as well as “how organisms work” in a way that may lead to new therapeutic strategies.

“This study of experimental evolution confirms some previous observations and raises new questions,” said Douglas Futuyma, a distinguished professor of ecology and evolution at Stony Brook University, New York, who was not involved in the research. “It shows that ‘there are many ways to skin a cat’: different ways in which a species may evolve a similar adaptive characteristic — running activity, in this case. Garland and coauthors go further by beginning to explore the detailed ways in which an adaptive feature, such as muscle size or metabolic rate, may be realized and by showing sex differences in the response to selection. It would be fascinating to know, and challenging to find out, if any one of these different responses is adaptively better than others.”

Garland was joined in the research by Scott Kelly, Jessica Malisch, Erik Kolb, Robert Hannon, Brooke Keeney, Shana Van Cleave and Kevin Middleton, all of whom work in his lab.

The study was supported primarily by a grant to Garland from the National Science Foundation.

Details of the experimental set-up

The mice run on wheels attached to their cages. Wheel running is a completely voluntary behavior for the mice. They can sit in their cages and not run at all. If they do run, they can get off the wheels at any time. For the experiments, each mouse was given access to the wheels for only six days of their lives. A computer recorded every minute how much distance (revolutions) the mice ran for the six days. The researchers selected breeders depending on how much distance the mice ran on days 5 and 6.

About Theodore Garland Jr.

Garland received his doctoral degree in biological sciences from UC Irvine. Before joining UCR in 2001, he was a faculty member at the University of Wisconsin-Madison. He is trained in comparative physiology and evolutionary biology, as well as quantitative genetics with emphasis on exercise physiology. He is co-editor of Experimental evolution: concepts, methods, and applications of selection experiments (University of California Press, 2009). On the editorial boards of several scientific journals, he is the author/coauthor of nearly 200 peer-reviewed publications.

The University of California, Riverside (www.ucr.edu) is a doctoral research university, a living laboratory for groundbreaking exploration of issues critical to Inland Southern California, the state and communities around the world. Reflecting California’s diverse culture, UCR’s enrollment of about 18,000 is expected to grow to 21,000 students by 2020. The campus is planning a medical school and has reached the heart of the Coachella Valley by way of the UCR Palm Desert Graduate Center. The campus has an annual statewide economic impact of more than $1 billion.

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