If further research can identify the substances that the bacteria of the gut are making to help muscles grow following exercise, we might be able to use some of those substances to promote the growth of muscles in people suffering from the loss of muscle as typically seen with ageing or cancer.

It is according to new research published today in The Journal of Physiology. The researchers found that for muscles to grow following exercise, and in-tact microbiome was necessary for mice.

The gut microbiome refers to bacteria (and other microbes) trillions inside our digestive systems. Over the last decade, research has found that these bacteria make substances needed for our health.

Some of these studies provided intriguing evidence suggesting the gut microbiome may also be necessary for the health of skeletal muscles. But is a healthy gut microbiome necessary for skeletal muscle to adapt to exercise?

To answer this question, the researchers let mice voluntarily exercise on running wheels every day for nine weeks, with some mice administered antibiotics through their drinking water. The antibiotic treatment killed the bacteria of the gut microbiome.

They then compared healthy mice’s muscles to those without an intact microbiome to see if the muscles adapted differently to wheel running. They found that the muscles of mice without an intact microbiome did not grow as much as the muscles of healthy mice, even though both groups of mice ran the same amount over the nine weeks of wheel running.

These findings indicate a healthy gut microbiome is necessary for skeletal muscles to grow after exercising fully.

The findings from this new study contribute to the growing body of evidence showing a connection between the gut microbiome and skeletal muscles. The findings suggest the gut microbiome makes substances that help skeletal muscles to become larger after exercising.

Although the researchers used a relatively low dose of antibiotics compared to previous studies, a limitation of the study is that they do not know if the antibiotics might have directly affected the ability of the skeletal muscle to adapt to exercise.

They only used female mice in this initial study, so they do not know if the findings will be similar in male mice. Finally, as with all animal studies, they do not know if the findings will translate into humans. 

Taylor Valentino, the first author on the paper, said: ‘If we can identify the substances that gut bacteria are making to help muscles grow after exercise, we might be able to use some of those substances to promote the growth of muscles in people suffering from the loss of muscle as typically seen with ageing or cancer.’

John McCarthy, the senior author, added: ‘From an athletic standpoint, world-class runners were found to have more of a particular type of bacteria that provided an additional source of energy which was thought to help them run faster. Thus, the gut microbiome makes substances that appear to be important for skeletal muscles to fully adapt to exercise as well as help improve athletic performance.’

‘We are currently trying to determine how exercise changes the composition and function of the gut microbiome.  This investigation, along with other studies in bacteria, will allow us to identify the substances made by the gut microbiome that help skeletal muscle grow larger in response to exercise.’