Abstract
Patients with type 1 diabetes have lower bone mineral density and higher risk of fractures. The role of osteoblasts in diabetes-related osteoporosis is well acknowledged whereas the role of osteoclasts (OCLs) is still unclear. We hypothesize that OCLs participate in pathological bone remodeling. We conducted studies in animals (streptozotocin-induced type 1 diabetic mice) and cellular models to investigate canonical and non-canonical mechanisms underlying excessive OCL activation. Diabetic mice show an increased number of active OCLs. In vitro studies demonstrate the involvement of acidosis in OCL activation and the implication of transient receptor potential cation channel subfamily V member 1 (TRPV1). In vivo studies confirm the establishment of local acidosis in the diabetic bone marrow (BM) as well as the ineffectiveness of insulin in correcting the pH variation and osteoclast activation. Conversely, treatment with TRPV1 receptor antagonists re-establishes a physiological OCL availability. These data suggest that diabetes causes local acidosis in the BM that in turn increases osteoclast activation through the modulation of TRPV1. The use of clinically available TRPV1 antagonists may provide a new means to combat bone problems associated with diabetes.
Highlights
Patients with type 1 diabetes have lower bone mineral density and higher risk of fractures
We investigate the involvement of TRPV1 cation channel in hypoxia/acidosis both in vitro and in vivo
Using a murine model of DM1, we demonstrate the activation of osteoclasts in trabecular bone since early stages of the disease
Summary
Patients with type 1 diabetes have lower bone mineral density and higher risk of fractures. Diabetic mice show an increased number of active OCLs. In vitro studies demonstrate the involvement of acidosis in OCL activation and the implication of transient receptor potential cation channel subfamily V member 1 (TRPV1). In vivo studies confirm the establishment of local acidosis in the diabetic bone marrow (BM) as well as the ineffectiveness of insulin in correcting the pH variation and osteoclast activation. Treatment with TRPV1 receptor antagonists re-establishes a physiological OCL availability These data suggest that diabetes causes local acidosis in the BM that in turn increases osteoclast activation through the modulation of TRPV1. Represents a predominant trigger of TRP cation channels-induced osteoclast activation in DM1 Blockade of this mechanism prevents osteoclast activation in vivo, opening new avenues for treatment of a common complication of DM
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