ABSTRACT
The isoflavone calycosin-7-O-β-d-glucopyranoside (CG) is a principal constituent of Astragalus membranaceus (AR) and has been reported to inhibit osteoclast development in vitro and bone loss in vivo. The aim of this study was to investigate the osteogenic effects of CG and its underlying mechanism in ST2 cells. The results show that exposure of cells to CG in osteogenic differentiation medium increases ALP activity, osteocalcin (Ocal) mRNA expression and the osteoblastic mineralization process. Mechanistically, CG treatment increased the expression of bone morphogenetic protein 2 (BMP-2), p-Smad 1/5/8, β-catenin and Runx2, all of which are regulators of the BMP- or wingless-type MMTV integration site family (WNT)/β-catenin-signaling pathways. Moreover, the osteogenic effects of CG were inhibited by Noggin and DKK-1 which are classical inhibitors of the BMP and WNT/β-catenin-signaling pathways, respectively. Taken together, the results indicate that CG promotes the osteoblastic differentiation of ST2 cells through regulating the BMP/WNT signaling pathways. On this basis, CG may be a useful lead compound for improving the treatment of bone-decreasing diseases and enhancing bone regeneration.
ABSTRACT
A neoformação óssea em defeitos críticos em calvária de ratos depende fortemente das propriedades osteocondutoras dos enxertos e biomateriais. Ainda é controverso se os biomateriais podem substituir os enxertos de osso autógeno e se a suplementação dos biomateriais com Proteínas Ósseas Morfogenéticas (BMPs) é necessária para melhorar a formação óssea. Examinamos defeitos críticos em calvária de ratos (5 mm de diâmetro) tratados com β-tricálcio fosfato (TCP; Cerasorb ® M), gel de ácido polilático e poliglicólico (PLA/PGA; Fisiograft®) e cimento de fosfato de cálcio (CPC; Norian® CRS®), isoladamente ou na presença de 5μg de BMP-2 após 45 dias. Defeitos tratados com enxerto de osso autógeno particulado e defeitos não tratados serviram como controle. A formação óssea foi avaliada com base na análise de μCT, análise histomorfométrica e análise de fluorescência. Nós relatamos que o TCP apoia a formação óssea de forma mais eficiente do que o enxerto de osso autógeno particulado. A formação óssea na presença de TCP sozinho atingiu um nível máximo de neoformação óssea, enquanto que a suplementação de BMP-2 falhou em melhorar a neoformação óssea. Em contrapartida, não houve diferença significativa na formação óssea quando o PLA / PGA e o CPC foram comparados ao enxerto autógeno. Além disso, a presença de BMP-2 não alterou substancialmente as propriedades osteocondutoras de PLA/PGA ou de CPC. Conclui-se que as propriedades osteocondutoras do TCP são superiores aos dos enxertos autógenos e que o TCP não exige suplementação de BMP-2. Nossos resultados também mostram que a diminuição da capacidade osteocondutora do PLA/PGA e do CPC não podem ser superadas pela suplementação de BMP-2 em defeitos de calvária de ratos
Bone formation in critical-sized calvaria defects is strongly dependent on the osteoconductive properties of grafts. It remains a matter of controversy whether biomaterials can replace autografts and whether the supplementation of biomaterials with Bone Morphogenetic Proteins (BMPs) is necessary to enhance bone formation. We examined rat calvaria critical-sized defects (5mm diameter) treated with β-tricalcium phosphate (TCP; Cerasorb® M), polylactic and polyglycolic acid gel (PLA/PGA; Fisiograft®) and calcium phosphate cement (CPC; Norian® CRS®), either alone or in the presence of 5μg of BMP-2 after 45 days. Autografts and untreated defects served as controls. Bone formation was evaluated based on μCT analysis, histomorphometric analysis and fluorescence analysis. We report that TCP supported bone formation more efficiently than did autografts. Bone formation in the presence of TCP alone reached a maximal level, as BMP-2 supplementation failed to enhance bone formation. By contrast, no significant difference in bone formation was observed when PLA/PGA and CPC were compared to autografts. Moreover, the presence of BMP-2 did not substantially change the osteoconductive properties of PLA/PGA or CPC. We conclude that the osteoconductive properties of TCP are superior to those of autografts and that TCP does not require BMP-2 supplementation. Our findings also show that the decreased osteoconductive properties of PLA/PGA and CPC cannot be overcome by BMP-2 supplementation in rat calvaria defects