Inhibition of Axin1 in Osteoblast Precursor Cells Leads to Defects in Postnatal Bone Growth Through Suppressing Osteoclast Formation

Overview

Journal Bone Res

Specialties Endocrinology
Orthopedics

Date 2020 Aug 22

PMID 32821442

Citations 16

Authors

Bing Shu

Yongjian Zhao

Shitian Zhao

Haobo Pan

Rong Xie

Dan Yi

Ke Lu

Junjie Yang

Chunchun Xue

Jian Huang

Jing Wang

Dongfeng Zhao

Guozhi Xiao

Yongjun Wang

Di Chen

Affiliations

Soon will be listed here.

Abstract

Axin1 is a negative regulator of β-catenin signaling and its role in osteoblast precursor cells remains undefined. In the present studies, we determined changes in postnatal bone growth by deletion of in osteoblast precursor cells and analyzed bone growth in newborn and postnatal mice and found that hypertrophic cartilage area was largely expanded in KO mice. A larger number of chondrocytes and unabsorbed cartilage matrix were found in the bone marrow cavity of KO mice. Osteoclast formation in metaphyseal and subchondral bone areas was significantly decreased, demonstrated by decreased TRAP-positive cell numbers, associated with reduction of MMP9- and cathepsin K-positive cell numbers in KO mice. OPG expression and the ratio of to were significantly increased in osteoblasts of KO mice. Osteoclast formation in primary bone marrow derived microphage (BMM) cells was significantly decreased when BMM cells were cultured with conditioned media (CM) collected from osteoblasts derived from mice compared with BMM cells cultured with CM derived from WT mice. Thus, the loss of Axin1 in osteoblast precursor cells caused increased OPG and the decrease in osteoclast formation, leading to delayed bone growth in postnatal KO mice.

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