Washington: Tumour cells are known to be fickle sleepers, typically lying dormant in distant tissues for years before reactivating and producing metastasis. Numerous elements, ranging from cells and molecules to other components in the so-called tissue microenvironment, have been researched to determine why activation occurs.
Now, an interdisciplinary Cornell team has identified a new mechanism regulating tumor growth in the skeleton, the primary site of breast cancer metastasis: mineralization of the bone matrix, a fibrous mesh of organic and inorganic components that determines the unique biochemical and biomechanical properties of our skeleton.
Health News: Tiny, Flexible Spinal Probe System May Lead To Better Therapies: Study
The team’s paper, “Bone-Matrix Mineralization Dampens Integrin-Mediated Mechanosignalling and Metastatic Progression in Breast Cancer,” published Aug. 7 in Nature Biomedical Engineering. The co-lead authors are research associate Siyoung Choi and doctoral student Matthew Whitman.
The project is the latest collaboration between co-senior authors Claudia Fischbach, the Stanley Bryer 1946 Professor of Biomedical Engineering, and Lara Estroff, the Herbert Fisk Johnson Professor of Industrial Chemistry, both in Cornell Engineering, who together have been exploring the metastatic spread of breast cancer to bone for more than a decade.
Fischbach’s lab uses biomaterials in combination with cellular and tissue engineering approaches to understand how the tissue microenvironment regulates cancer in different contexts, while Estroff’s group specializes in biomineralization – the way biological organisms control the growth of crystals in their tissues.
“We know that cancer cells behave like seeds that need the right soil to grow, and we’re very interested in how the extracellular matrix, which is basically the material in between cells that holds everything together, affects tumor growth,” Fischbach said.
During physiological mineralization, bone mineral particles are deposited in and around collagen type I fibers. This process occurs naturally and is necessary for bone health but decreases with age – for example, due to hormonal changes as seen in women undergoing menopause. It can also result from dietary changes or chemotherapy.
A connection between reduced bone health and the behavior of tumor cells is well-established. For example, decreased bone-mineral density has been correlated with increased risk for metastasis, and incomplete fracture healing has been shown to enhance bone metastasis. However, no one had been able to isolate which specific role bone-matrix mineralization plays in this process.