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The many ways exercise affects the body to improve health
Dr. Mercola
Mercola.com
Fri, 13 Feb 2015
Virtually everyone would agree that exercise improves health, but the mechanisms by which it actually produces those benefits have been challenging to tease out.
Fitness research has come a long way though, and modern science has made a number of interesting observations that help explain how exercise affects your body to improve your health.
Part of the answer lies in its ability to affect genetic expression; activating some genes, and deactivating others. A previous New York Times article1 delved into the latest research on this front, noting that:
The Epigenetics of Exercise
Dr. Mercola
Mercola.com
Fri, 13 Feb 2015
Virtually everyone would agree that exercise improves health, but the mechanisms by which it actually produces those benefits have been challenging to tease out.
Fitness research has come a long way though, and modern science has made a number of interesting observations that help explain how exercise affects your body to improve your health.
Part of the answer lies in its ability to affect genetic expression; activating some genes, and deactivating others. A previous New York Times article1 delved into the latest research on this front, noting that:
"The human genome is astonishingly complex and dynamic, with genes constantly turning on or off, depending on what biochemical signals they receive from the body. When genes are turned on, they express proteins that prompt physiological responses elsewhere in the body."
Far from being "written in stone," genetic expression can be altered by influences coming from outside the gene. This influence alters the operation of the gene, but does not affect the DNA blueprint itself. This process is known as "epigenetics," and occurs mainly through methylation. As described in the featured article:
Methylation patterns can be altered by a variety of lifestyle changes, such as diet and exercise. Toxic exposure also tends to affect genetic expression, by altering the types of proteins a particular gene will express.
In this way, your environment, diet, and general lifestyle play a significant role in your state of health and development of disease. When it comes to exercise, previous research has found that exercise can induce immediate changes in the methylation patterns of genes found in your muscle cells.
A study published in the journal Cell Metabolism2 in 2012 showed that while the underlying genetic code in the muscle remains unchanged, vigorous exercise—even if brief—causes structural and chemical changes in the DNA molecules within the muscles.
This gene activation is induced by contraction of the muscle, and this contraction-induced gene activation appears to be part of the chain of events that lead to the genetic reprogramming of muscle for strength—and to the structural and metabolic benefits of exercise.
Several of the genes affected by an acute bout of exercise are genes involved in fat metabolism. Specifically, the study suggests that when you exercise, your body almost immediately experiences genetic activation that increases the production of fat-busting proteins.
Previous studies have also identified and measured a wide variety of biochemical changes that occur during exercise. More than 20 different metabolites3 are affected, including compounds that help stabilize your blood sugar. All of these biochemical changes create a positive feedback loop, resulting in improved health and physical performance.
How Endurance Training Affects Your Genes "In methylation, clusters of atoms, called methyl groups, attach to the outside of a gene like microscopic mollusks and make the gene more or less able to receive and respond to biochemical signals from the body."
In this way, your environment, diet, and general lifestyle play a significant role in your state of health and development of disease. When it comes to exercise, previous research has found that exercise can induce immediate changes in the methylation patterns of genes found in your muscle cells.
A study published in the journal Cell Metabolism2 in 2012 showed that while the underlying genetic code in the muscle remains unchanged, vigorous exercise—even if brief—causes structural and chemical changes in the DNA molecules within the muscles.
This gene activation is induced by contraction of the muscle, and this contraction-induced gene activation appears to be part of the chain of events that lead to the genetic reprogramming of muscle for strength—and to the structural and metabolic benefits of exercise.
Several of the genes affected by an acute bout of exercise are genes involved in fat metabolism. Specifically, the study suggests that when you exercise, your body almost immediately experiences genetic activation that increases the production of fat-busting proteins.
Previous studies have also identified and measured a wide variety of biochemical changes that occur during exercise. More than 20 different metabolites3 are affected, including compounds that help stabilize your blood sugar. All of these biochemical changes create a positive feedback loop, resulting in improved health and physical performance.
These kinds of findings led to another question: does endurance training (opposed to a brief intense bout of exercise) also affect methylation, and if so, how? A Swedish study4 published in December 2014 sought to shed light on this question.
As reported in the featured article:
The volunteers performed their one-legged pedal exercise, at a moderate pace, for 45 minutes four times a week for three months. The result? The exercised leg was stronger than the unexercised leg, confirming that exercise led to physical improvement, as you would expect.
Genetic alterations within the cells of the muscles revealed there was more to the story however. More than 5,000 sites on the muscle cells' genome, biopsied from the exercised leg, had altered methylation patterns. These changes were not found in biopsied cells from the unexercised leg. A majority of the methylation changes that occurred in the exercised leg play a role in:
Endurance Training versus High Intensity Exercise As reported in the featured article:
"[S]cientists at the Karolinska Institute in Stockholm recruited 23 young and healthy men and women, brought them to the lab for a series of physical performance and medical tests, including a muscle biopsy, and then asked them to exercise half of their lower bodies for three months.
One of the obstacles in the past to precisely studying epigenetic changes has been that so many aspects of our lives affect our methylation patterns, making it difficult to isolate the effects of exercise from those of diet or other behaviors.
The Karolinska scientists overturned that obstacle by the simple expedient of having their volunteers bicycle using only one leg, leaving the other unexercised.
In effect, each person became his or her own control group. Both legs would undergo methylation patterns influenced by his or her entire life; but only the pedaling leg would show changes related to exercise."
One of the obstacles in the past to precisely studying epigenetic changes has been that so many aspects of our lives affect our methylation patterns, making it difficult to isolate the effects of exercise from those of diet or other behaviors.
The Karolinska scientists overturned that obstacle by the simple expedient of having their volunteers bicycle using only one leg, leaving the other unexercised.
In effect, each person became his or her own control group. Both legs would undergo methylation patterns influenced by his or her entire life; but only the pedaling leg would show changes related to exercise."
Genetic alterations within the cells of the muscles revealed there was more to the story however. More than 5,000 sites on the muscle cells' genome, biopsied from the exercised leg, had altered methylation patterns. These changes were not found in biopsied cells from the unexercised leg. A majority of the methylation changes that occurred in the exercised leg play a role in:
- Energy metabolism
- Insulin response
- Muscle inflammation
Quite clearly, exercise—in all its forms—tends to have a positive effect. It has the power to affect your entire body, and your overall state of health. Its beneficial impact on your insulin response (normalizing your glucose and insulin levels by optimizing insulin receptor sensitivity) is among the most important benefits of exercise, as insulin resistance is a factor in most chronic disease. According to lead author Malene Lindholm:5
High intensity interval training (HIIT) has been shown to be far more effective at producing positive results however, when compared to endurance training. And while the study above concluded that endurance training indeed induces genetic alterations that promote good health, HIIT is known to do so far more efficiently. Mounting research shows that by focusing on endurance-type exercises, such as jogging on a treadmill, you actually forgo many of the most profound benefits of exercise.
Some of the latest research in high intensity exercise involves myokines—a class of cell-signaling proteins produced by muscle fibers—and how they can combat diseases like metabolic syndrome and cancer. I interviewed Dr. Doug McGuff about this research last year. These myokines—which are cytokines produced in muscle—are very anti-inflammatory. They also increase your insulin sensitivity and your glucose utilization inside the muscle. High intensity strength training, also known as "super-slow strength training," is likely the most effective in terms of activating myokines.
The reason for this is because it induces a rapid and deep level of muscle fatigue. This triggers the synthesis of more contractile tissue, and all the metabolic components to support it—including more myokines. If you still have not incorporated high intensity exercise into your fitness regimen, I highly recommend getting started. You can learn more about HIIT here,6 as there are many different programs to choose from. I also review the similarities and differences between super-slow and super-super-slow strength training techniques in this previous article.7
"Through endurance training — a lifestyle change that is easily available for most people and doesn't cost much money—we can induce changes that affect how we use our genes and, through that, get healthier and more functional muscles that ultimately improve our quality of life."
Some of the latest research in high intensity exercise involves myokines—a class of cell-signaling proteins produced by muscle fibers—and how they can combat diseases like metabolic syndrome and cancer. I interviewed Dr. Doug McGuff about this research last year. These myokines—which are cytokines produced in muscle—are very anti-inflammatory. They also increase your insulin sensitivity and your glucose utilization inside the muscle. High intensity strength training, also known as "super-slow strength training," is likely the most effective in terms of activating myokines.
The reason for this is because it induces a rapid and deep level of muscle fatigue. This triggers the synthesis of more contractile tissue, and all the metabolic components to support it—including more myokines. If you still have not incorporated high intensity exercise into your fitness regimen, I highly recommend getting started. You can learn more about HIIT here,6 as there are many different programs to choose from. I also review the similarities and differences between super-slow and super-super-slow strength training techniques in this previous article.7
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