Osteocalcin effect on human β-cells mass and function

OM Sabek, SK Nishimoto, D Fraga, N Tejpal… - …, 2015 - academic.oup.com
OM Sabek, SK Nishimoto, D Fraga, N Tejpal, C Ricordi, AO Gaber
Endocrinology, 2015academic.oup.com
The osteoblast-specific hormone osteocalcin (OC) was found to regulate glucose
metabolism, fat mass, and β-cell proliferation in mice. Here, we investigate the effect of
decarboxylated OC (D-OC) on human β-cell function and mass in culture and in vivo using a
Nonobese diabetic-severe combined immunodeficiency mouse model. We found that D-OC
at dose ranges from 1.0 to 15 ng/mL significantly augmented insulin content and enhanced
human β-cell proliferation of cultured human islets. This was paralleled by increased …
The osteoblast-specific hormone osteocalcin (OC) was found to regulate glucose metabolism, fat mass, and β-cell proliferation in mice. Here, we investigate the effect of decarboxylated OC (D-OC) on human β-cell function and mass in culture and in vivo using a Nonobese diabetic-severe combined immunodeficiency mouse model. We found that D-OC at dose ranges from 1.0 to 15 ng/mL significantly augmented insulin content and enhanced human β-cell proliferation of cultured human islets. This was paralleled by increased expression of sulfonylurea receptor protein; a marker of β-cell differentiation and a component of the insulin-secretory apparatus. Moreover, in a Nonobese diabetic-severe combined immunodeficiency mouse model, systemic administration of D-OC at 4.5-ng/h significantly augmented production of human insulin and C-peptide from the grafted human islets. Finally, histological staining of the human islet grafts showed that the improvement in the β-cell function was attributable to an increase in β-cell mass as a result of β-cell proliferation indicated by MKI67 staining together with the increased β-cell number and decreased α-cell number data obtained using laser scanning cytometry. Our data for the first time show D-OC-enhanced β-cell function in human islets and support future exploitation of D-OC-mediated β-cell regulation for developing useful clinical treatments for patients with diabetes.
Oxford University Press