For people with a type of jaw joint disorder that results from loss of cartilage, the only treatments available address symptoms but do not repair the damaged tissue. Now, a new study of mice suggests stem cells already present in the jaw joint could be manipulated to repair it.
The researchers found fibrocartilage stem cells (blue) from the TMJ spontaneously regenerated cartilage (red) when transplanted into a live mouse.
Image credit: Mildred C. Embree / Columbia University Medical Center
The study, led by Columbia University Medical Center in New York, NY, is published in the journal Nature Communications. The authors describe how manipulating stem cells in the temporomandibular joint (TMJ) of mice with TMJ degeneration led the cells to repair cartilage in the joint.
The researchers also found that transplanting just a single TMJ stem cell into a mouse spontaneously generated cartilage and bone and even began to form a bone marrow niche.
Lead and corresponding author Mildred C. Embree, assistant professor of dental medicine at Columbia, says:
“This is very exciting for the field because patients who have problems with their jaws and TMJs are very limited in terms of clinical treatments available.”
Stem cells – immature cells that have the potential to mature into virtually any type of tissue cell – hold great promise for regenerative medicine, where faulty, damaged, or injured tissue is repaired by encouraging new cells to grow.
Alternative to stem cell transplanting
One way to regenerate tissue is to transplant stem cells into the affected area. However, as the authors explain in their paper, this approach can be risky – for instance, the donor cells could be rejected by the recipient’s immune system, introduce pathogens, or even give rise to tumors.
An alternative approach that could avoid these risks is the possibility that stem cells already present in the affected area could be induced to make new cells repair the damaged tissue.
Cartilage is a type of tissue that cushions bones and lines the joints to enable smooth movement without damage.
Within the TMJ, the cartilage is of a type called fibrocartilage. This type is also found in the knee meniscus and the discs between the vertebrae of the spine.
Once it is damaged – for instance through injury or disease – fibrocartilage does not regrow or heal, with the result that people suffer permanent disability.
In the United States alone, there are up to 10 million people – mostly women – with TMJ disorders. Children with juvenile idiopathic arthritis can also have stunted jaw growth that cannot be treated with existing drugs. The researchers suggest their findings could lead to new treatments that help these groups.
Suppressing Wnt signals
In their study, Prof. Embree and colleagues – including Jeremy Mao, the Edwin S. Robinson Professor of Dentistry (in Orthopedic Surgery) at Columbia – show for the first time that the “fibrous superficial zone” in the TMJ of mice harbors fibrocartilage stem cells (FCSCs).
They also discovered that a single FCSC transplanted into a live mouse is capable of not only generating cartilage and bone, but also of organizing the microenvironment to support the process – rather like specialized niches in bone marrow.
Moreover, the researchers showed that they could manipulate FCSCs to differentiate into the required cell types by suppressing a type of cell signal called Wnt. They found that overactive Wnt signals disrupt the stability of fibrocartilage and promote degeneration by depleting FCSCs.
The findings could also open up routes to new treatments for repairing fibrocartilage in joints other than the TMJ, including the knees and vertebral discs, as Prof. Embree explains:
“Those types of cartilage have different cellular constituents, so we would have to really investigate the molecular underpinnings regarding how these cells are regulated.”
“The implications of these findings are broad, including for clinical therapies. They suggest that molecular signals that govern stem cells may have therapeutic applications for cartilage and bone regeneration.”
Prof. Jeremy Mao
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