Public Release: 14-Feb-2018
The skeleton is often seen as an inert tissue, but this perception is quite wrong. In fact, the skeleton is constantly being remodelled: old bone fragments are broken down and new bone matrix is deposited, overall leading to a completely renewed skeleton every ten years. There are specific cells that form bone and other cells that resorb it. In diseases such as osteoporosis, the latter cells are too active and too much bone is degraded. Most drugs that are currently used primarily aim at blocking these resorptive cells. Unfortunately, this generally means that their counterparts, the cells responsible for the formation of bone, also stop working. As a consequence, the renewal of the bone is halted. In addition to the bone loss, the quality of the bone also deteriorates. Ultimately, this can lead to painful fractures that are difficult to heal.
To develop new drugs, scientists are investigating how the bone-forming cells can be activated. “To achieve this, it is crucial that we understand exactly how these cells work”, says professor Christa Maes. “Our research focuses on how these bone cells emerge and form bone at the right sites. A good blood supply is vital for the bone cells to work well. But we do not yet understand the full meaning of the close connection between blood vessels and bone cells. One aspect is that blood vessels provide oxygen. In this study, we investigated the importance of oxygen by analyzing mice with a mutation that makes their bone cells behave as if they were deprived of oxygen.”
The researchers found two consequences. Firstly, the mice formed abnormally heavy bones. Within the bones, they noted that the bone cells absorbed massive amounts of glucose. “That observation is in line with the usual response of cells to oxygen deprivation: they save on the consumption of oxygen by converting glucose to lactate instead of burning the glucose. No oxygen is needed for this conversion, but the downside is that it produces much less energy. In order to generate enough energy, the bone cells in our mice therefore take up much more glucose than normal.”
A second and rather unexpected effect was that the mice were lean. “The mice also did not seem to gain weight when they got older, like normal mice do. Still, they ate as much as their normal littermates and were even less physically active. Further research revealed that the mice had low blood sugar levels”, says PhD student Naomi Dirckx.
The two effects appeared to be connected: “Mice that had more glucose being absorbed into their skeleton, showed less glucose circulating in their blood. As such, the altered metabolism in the bone cells caused the mice to have a beneficial whole-body glucose turnover and a lean body. This reveals a new link between bone and the blood glucose level”, according to professor Christa Maes.
This finding offers new angles for further research into conditions such as osteoporosis, diabetes and obesity. “In diabetes, for instance, we see increased blood sugar levels combined with a poor bone quality that easily leads to fractures. With this new knowledge, we can continue working on treatments that could possibly solve both problems, although this will of course require many more years of research.”
Professor Christa Maes, Faculty of Medicine, Laboratory of Skeletal Cell Biology and Physiology (SCEBP), tel.: 016-37-26-56, email: email@example.com
The full text of the study “Vhl deletion in osteoblasts boosts cellular glycolysis and improves global glucose metabolism” by Naomi Dirckx, Robert J. Tower, Evi M. Mercken, Roman Vangoitsenhoven, Caroline Moreau-Triby, Tom Breugelmans, Elena Nefyodova, Ruben Cardoen, Chantal Mathieu, Bart Van der Schueren, Cyrille B. Confavreux, Thomas L. Clemens and Christa Maes is available on the website of the Journal of Clinical Investigation.
This research was funded by the European Research Council, the Research Foundation Flanders, the Flemish government agency for Innovation by Science and Technology (IWT), KU Leuven and the American National Institutes of Health.