Adipose, Bone, and Myeloma: Contributions from the Microenvironment.
Michelle M McDonaldHeather FairfieldCarolyne FalankMichaela R ReaganPublished in: Calcified tissue international (2016)
Researchers globally are working towards finding a cure for multiple myeloma (MM), a destructive blood cancer diagnosed yearly in ~750,000 people worldwide (Podar et al. in Expert Opin Emerg Drugs 14:99-127, 2009). Although MM targets multiple organ systems, it is the devastating skeletal destruction experienced by over 90 % of patients that often most severely impacts patient morbidity, pain, and quality of life. Preventing bone disease is therefore a priority in MM treatment, and understanding how and why myeloma cells target the bone marrow (BM) is fundamental to this process. This review focuses on a key area of MM research: the contributions of the bone microenvironment to disease origins, progression, and drug resistance. We describe some of the key cell types in the BM niche: osteoclasts, osteoblasts, osteocytes, adipocytes, and mesenchymal stem cells. We then focus on how these key cellular players are, or could be, regulating a range of disease-related processes spanning MM growth, drug resistance, and bone disease (including osteolysis, fracture, and hypercalcemia). We summarize the literature regarding MM-bone cell and MM-adipocyte relationships and subsequent phenotypic changes or adaptations in MM cells, with the aim of providing a deeper understanding of how myeloma cells grow in the skeleton to cause bone destruction. We identify avenues and therapies that intervene in these networks to stop tumor growth and/or induce bone regeneration. Overall, we aim to illustrate how novel therapeutic target molecules, proteins, and cellular mediators may offer new avenues to attack this disease while reviewing currently utilized therapies.
Keyphrases
- bone regeneration
- bone mineral density
- multiple myeloma
- induced apoptosis
- mesenchymal stem cells
- bone marrow
- bone loss
- soft tissue
- newly diagnosed
- adipose tissue
- stem cells
- single cell
- systematic review
- endoplasmic reticulum stress
- chronic pain
- insulin resistance
- case report
- high intensity
- metabolic syndrome
- fatty acid
- cell death
- replacement therapy
- childhood cancer