By GRETCHEN REYNOLDS APRIL 11, 2018
If you give a mouse a running wheel, it will
run.
But it may not burn many additional calories,
because it will also start to move differently when it is not on the wheel,
according to an interesting new study of the behaviors and metabolisms of
exercising mice.
The study, published in Diabetes, involved
animals, but it could have cautionary implications for people who start
exercising in the hopes of losing weight.
In recent years, study after study examining
exercise and weight loss among people and animals has concluded that, by
itself, exercise is not an effective way to drop pounds.
In most of these experiments, the participants
lost far less weight than would have been expected, mathematically, given how
many additional calories they were burning with their workouts.
Scientists involved in this research have
suspected and sometimes shown that exercisers, whatever their species, tend to
become hungrier and consume more calories after physical activity. They also
may grow more sedentary outside of exercise sessions. Together or separately,
these changes could compensate for the extra energy used during exercise,
meaning that, over all, energy expenditure doesn’t change and a person’s or
rodent’s weight remains stubbornly the same.
Proving that possibility has been daunting,
though, in part because it is difficult to quantify every physical movement
someone or something makes, and how their movements do or do not change after
exercise. Mice, for instance, skitter, dart, freeze, groom, eat, roam, defecate
and otherwise flit about in frequent fits and starts.
But recently, animal researchers hit upon the
idea of using infrared light beams to track how animals move at any given
moment in their cages. Sophisticated software then can use that information to
map daily patterns of physical activity, showing, second-by-second, when, where
and for how long an animal roams, sits, runs or otherwise spends its time.
Intrigued, scientists at Vanderbilt University
and other institutions thought that this technology would be ideal for tracking
mice before and after they started exercising, especially if the technology
were used in specialized metabolic-chamber cages that can quantify how much
energy an inhabitant is expending throughout the day.
So the scientists fitted out cages, added
locked running wheels, and let young, healthy, normal-weight, male mice loose
in them to roam and explore for four days, providing the researchers with
baseline data about each mouse’s metabolism and natural peripatetic-ness.
The wheels then were unlocked and for nine
days, the mice could run at will, while also eating and moving around off the
wheels as much as they chose.
The mice, which seem to enjoy running, hopped
readily on the wheels and ran, off and on, for hours.
They showed a subsequent spike in their daily
energy expenditure, according to the metabolic measures, which makes sense,
since they had added exercise to their lives.
But they did not change their eating habits.
Although they were burning more calories, they did not gorge on more chow.
They did, however, alter how they moved.
Almost immediately after they started using the wheels, they stopped roaming
around their cages as they had before the wheels were unlocked.
In particular, they stopped engaging in the
kind of lengthy meanders that had been common before they began to run.
Instead, they now usually jogged on their wheels for a few minutes, hopped off,
rested or roamed in short spurts, and then climbed back on the wheels, ran,
rested, briefly roamed, and repeated.
These changes in how they spent their time
neatly managed to almost counteract the extra calorie costs from running, says
Daniel Lark, a research fellow in molecular physiology at the Vanderbilt
University School of Medicine, who led the new study.
In general, the running mice showed a slightly
negative energy balance, meaning that they were burning a few more calories
over the course of the day than they were taking in by chowing down.
But that caloric deficit would have been about
45 percent greater, the metabolic calculations showed, if they had not also
begun moving around their cages less.
What prompted the running mice to roam less is
still uncertain.
“But it does not seem to have been fatigue or
lack of time,” Dr. Lark says.
Wheel running is not arduous for mice, he
points out, and did not fill their waking hours.
Instead, he says, it is likely that the
animals’ bodies and brains sensed the beginnings of an energy deficit when the
mice began to run and sent out biological signals that somehow advised the
animals to slow down, conserve energy, maintain homeostasis and not drop
weight.
He and his colleagues would like, in future
experiments, to explore how, physiologically, the rodents’ bodies sensed the
changes in their energy balance and at what point they might begin to eat more.
They also would like to study female, older and obese animals.
Mice will never be people, of course, so we
cannot say whether the results of this and any follow-up experiments would
directly apply to us, Dr. Lark says.
But the results do intimate that if we hope to
exercise off excess pounds, we watch what we eat and try not to move less while
we work out more.
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