Dual Inhibition of the Wnt Inhibitors DKK1 and Sclerostin Promotes Fracture Healing and Increases the Density and Strength of Uninjured Bone: An Experimental Study in Nonhuman Primates.

BACKGROUND: Fracture repair involves the reactivation of developmental signaling cascades, including Wnt signaling that stimulates bone formation and bone regeneration. Rodent data indicate that dual inhibition of the Wnt signaling antagonists sclerostin and Dickkopf-1 (DKK1) increases callus bone volume and strength while increasing bone mass systemically. METHODS: We evaluated the effects of 16 weeks of subcutaneously administered carrier solution (vehicle, VEH), anti-sclerostin antibody (Scl-Ab), anti-DKK1 antibody (DKK1-Ab), or Scl-Ab plus DKK1-Ab combination therapy (COMBO) on ulnar osteotomy healing in nonhuman primates (cynomolgus monkeys; 20 to 22 per group). RESULTS: Scl-Ab and COMBO therapy increased systemic markers of bone formation versus VEH, with COMBO leading to synergistic increases versus Scl-Ab or DKK1-Ab monotherapies. The COMBO and Scl-Ab groups showed reduced serum markers of bone resorption versus VEH. The COMBO and DKK1-Ab groups exhibited greater callus bone mineral density (BMD), torsional stiffness, and torsional rigidity versus VEH. Lumbar vertebrae from the Scl-Ab and COMBO groups showed greater BMD and bone formation rate versus VEH, and the femoral mid-diaphysis of the Scl-Ab and COMBO groups showed greater periosteal and endocortical bone formation rates versus VEH. CONCLUSIONS: DKK1-Ab increased BMD and strength at the ulnar osteotomy site, Scl-Ab increased bone formation and BMD at uninjured skeletal sites, and Scl-Ab plus DKK1-Ab combination therapy induced all of these effects, in some cases to a greater degree versus 1 or both monotherapies. These results in nonhuman primates suggest that DKK1 preferentially regulates bone healing while sclerostin preferentially regulates systemic bone mass. CLINICAL RELEVANCE: Combination therapy with antibodies against sclerostin and DKK1 may offer a promising therapeutic strategy for both fracture treatment and fracture prevention.

Progressive increases in bone mass and bone strength in an ovariectomized rat model of osteoporosis after 26 weeks of treatment with a sclerostin antibody.

The effects of up to 26 weeks of sclerostin antibody (Scl-Ab) treatment were investigated in ovariectomized (OVX) rats. Two months after surgery, 6-month-old osteopenic OVX rats were treated with vehicle or Scl-Ab (25 mg/kg, sc, one time per week) for 6, 12, or 26 weeks. In vivo dual-energy x-ray absorptiometry analysis demonstrated that the bone mineral density of lumbar vertebrae and femur-tibia increased progressively through 26 weeks of Scl-Ab treatment along with progressive increases in trabecular and cortical bone mass and bone strength at multiple sites. There was a strong correlation between bone mass and maximum load at lumbar vertebra, femoral neck, and diaphysis at weeks 6 and 26. Dynamic histomorphometric analysis showed that lumbar trabecular and tibial shaft endocortical and periosteal bone formation rates (BFR/BS) increased and peaked at week 6 with Scl-Ab-treatment; thereafter trabecular and endocortical BFR/BS gradually declined but remained significantly greater than OVX controls at week 26, whereas periosteal BFR/BS returned to OVX control levels at week 26. In the tibia metaphysis, trabecular BFR/BS in the Scl-Ab treated group remained elevated from week 6 to week 26. The osteoclast surface and eroded surface were significantly lower in Scl-Ab-treated rats than in OVX controls at all times. In summary, bone mass and strength increased progressively over 26 weeks of Scl-Ab treatment in adult OVX rats. The early gains were accompanied by increased cortical and trabecular bone formation and reduced osteoclast activity, whereas later gains were attributed to residual endocortical and trabecular osteoblast stimulation and persistently low osteoclast activity.

Inhibition of sclerostin by monoclonal antibody enhances bone healing and improves bone density and strength of nonfractured bones.

Therapeutic enhancement of fracture healing would help to prevent the occurrence of orthopedic complications such as nonunion and revision surgery. Sclerostin is a negative regulator of bone formation, and treatment with a sclerostin monoclonal antibody (Scl-Ab) results in increased bone formation and bone mass in animal models. Our objective was to investigate the effects of systemic administration of Scl-Ab in two models of fracture healing. In both a closed femoral fracture model in rats and a fibular osteotomy model in cynomolgus monkeys, Scl-Ab significantly increased bone mass and bone strength at the site of fracture. After 10 weeks of healing in nonhuman primates, the fractures in the Scl-Ab group had less callus cartilage and smaller fracture gaps containing more bone and less fibrovascular tissue. These improvements at the fracture site corresponded with improvements in bone formation, bone mass, and bone strength at nonfractured cortical and trabecular sites in both studies. Thus the potent anabolic activity of Scl-Ab throughout the skeleton also was associated with an anabolic effect at the site of fracture. These results support the potential for systemic Scl-Ab administration to enhance fracture healing in patients.

One year of transgenic overexpression of osteoprotegerin in rats suppressed bone resorption and increased vertebral bone volume, density, and strength.

RANKL is an essential mediator of bone resorption, and its activity is inhibited by osteoprotegerin (OPG). Transgenic (Tg) rats were engineered to continuously overexpress OPG to study the effects of continuous long-term RANKL inhibition on bone volume, density, and strength. Lumbar vertebrae, femurs, and blood were obtained from 1-yr-old female OPG-Tg rats (n = 32) and from age-matched wildtype (WT) controls (n = 23). OPG-Tg rats had significantly greater serum OPG (up to 260-fold) and significantly lower serum TRACP5b and osteocalcin compared with WT controls. Vertebral histomorphometry showed significant reductions in osteoclasts and bone turnover parameters in OPG-Tg rats versus WT controls, and these reductions were associated with significantly greater peak load in vertebrae tested through compression. No apparent differences in bone material properties were observed in OPG-Tg rat vertebrae, based on their unchanged intrinsic strength parameters and their normal linear relationship between vertebral bone mass and strength. Femurs from OPG-Tg rats were of normal length but showed mild osteopetrotic changes, including reduced periosteal perimeter (-6%) and an associated reduction in bending strength. Serum OPG levels in WT rats showed no correlations with any measured parameter of bone turnover, mass, or strength, whereas the supraphysiological serum OPG levels in OPG-Tg rats correlated negatively with bone turnover parameters and positively with vertebral bone mass and strength parameters. In summary, low bone turnover after 1 yr of OPG overexpression in rats was associated with increased vertebral bone mass and proportional increases in bone strength, with no evidence for deleterious effects on vertebral material properties.