When an animal faces a predator or sudden danger, the heart rate goes up, breathing becomes more rapid, and fuel in the form of glucose is pumped throughout the body to prepare theย animal to fight or flee.
These physiological changes, which constitute the โfight or flightโ response, are thought to be triggered in part by the release of the hormone adrenaline.
But a newย studyย from Columbia researchers suggests that bony vertebrates canโt muster this response to danger without the skeleton. The researchers found in mice and humans that almost immediately after the brain recognizes danger, it instructs the skeleton to flood the bloodstream with the bone-derived hormone osteocalcin, which is needed to turn on the fight or flight response.
โIn bony vertebrates, the acute stress response is not possible without osteocalcin,โ says the studyโs senior investigator,ย Gรฉrard Karsenty, MD, PhD, chair of the Department of Genetics &ย Development at Columbia University Vagelos College of Physicians and Surgeons.
โIt completely changes how we think about how acute stress responses occur.โ
Why bone?
โThe view of bones as merely an assembly of calcified tubes is deeply entrenched in our biomedical culture,โ Karsenty says. But about a decade ago, his lab hypothesized and demonstrated that the skeleton has hidden influences on other organs.
The research revealed that the skeleton releases osteocalcin, which travels through the bloodstream to affect the functions of the biology of the pancreas, the brain, muscles, and other organs.
A series of studies since then hasย shown that osteocalcin helps regulate metabolism by increasing the ability of cells to take inย glucose, improvesย memory, and helps animalsย runย faster with greater endurance.
Why does bone have all these seemingly unrelated effects on other organs?
โIf you think of bone as something that evolved to protect the organism from dangerโthe skull protects the brain from trauma, the skeleton allows vertebrates to escape predators, and even the bones in the ear alert us to approaching dangerโthe hormonal functions of osteocalcin begin to make sense,โ Karsenty says. If bone evolved as a means to escape danger, Karsenty hypothesized that the skeleton should also be involved in the acute stress response, which is activated in the presence of danger.
Osteocalcin necessary to react to danger
If osteocalcin helps bring about the acute stress response, it must work fast, in the first few minutes after danger is detected.
In the new study, the researchers presented mice with predator urine and other stressors and looked for changes in the bloodstream. Within twoย to threeย minutes, they saw osteocalcin levels spike.
Similarly, the researchers found that osteocalcin also surges in people when they are subjected to the stress of public speaking or cross-examination.
When osteocalcin levels increased, heart rate, body temperature, and blood glucose levels in the mice also rose as the fight or flight response kicked in.
In contrast, mice that had been genetically engineered so that they were unable to make osteocalcin or its receptor were totally indifferent to the stressor. Karsenty says. โWithout osteocalcin, they didnโt react strongly to the perceived danger,โ Karsenty says. โIn the wild, theyโd have a short day.โ
As a final test, the researchers were able to bring on an acute stress response in unstressed mice simply by injecting large amounts of osteocalcin.
Adrenaline not necessary for fight or flight
The findings also may explain why animals without adrenal glands and adrenal-insufficient patientsโwith no means of producing adrenaline or other adrenal hormonesโcan develop an acute stress response.
Among mice, this capability disappeared when the mice were unable to produce large amounts of osteocalcin.
โThis shows us that circulating levels of osteocalcin are enough to drive the acute stress response,โ says Karsenty.
Physiology: new frontier of biology
Physiology may sound like old-fashioned biology, but new genetic techniques developed in the past 15 years have established it as a new frontier in science.
The ability to inactivate single genes in specific cells inside an animal, and at specific times, has led to the identification of many new inter-organ relationships. The skeleton is just one example; the heart and muscles also exert influence over other organs.
โI have no doubt that there areย many more new inter-organ signals to be discovered,โ Karsenty says, โand these interactions may be as important as the ones discovered in the early part of the 20th century.โ
More Information
Dr. Karsenty also is the Paul A. Marks Professor of Genetics &ย Development and professor of medicine at Columbia University Vagelos College of Physicians and Surgeons.
The study, โMediation of the acute stress response by the skeleton,โ was published Sept. 12 in Cell Metabolism.
Other authors: Julian Meyer Berger (Columbia University Irving Medical Center), Parminder Singh (National Institute of Immunology, New Delhi, India), Lori Khrimian (CUIMC), Donald A. Morgan (University of Iowa and Veteran Health Care System), Subrata Chowdhury (CUIMC), Emilio Arteaga-Solis (CUIMC), Tamas L. Horvath (Yale University School of Medicine), Ana I. Domingos (University of Oxford, UK), Anna L. Marsland (University of Pittsburgh), Vijay Kumal Yadav (CUIMC and National Institute of Immunology, New Delhi, India), Kamal Rahmouni (University of Iowa and Veteran Health Care System), and Xiao-Bing Gao (Yale University School of Medicine).
This work was supported by the National Institutes of Health (grants 2P01AG032959-06A1, 1R01DK104727-03, 1R01AR073180-01A1, DA040782-01A1, 5T32DK007328, 5T32DK007328-38, and 2P01HL084207); a Ramalingaswamy Fellowship; a CIHR Fellowship, the Veterans Administration (BX004249); and the Fraternal Order of Eagles Diabetes Research Center at the University of Iowa.
The authors declare no competing financial interests.
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