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LRP5 高骨量 G171V 突变破坏了 LRP5 与 Mesd 的相互作用。

The LRP5 high-bone-mass G171V mutation disrupts LRP5 interaction with Mesd.

作者信息

Zhang Yazhou, Wang Yang, Li Xiaofeng, Zhang Jianhong, Mao Junhao, Li Zhong, Zheng Jie, Li Lin, Harris Steve, Wu Dianqing

机构信息

Department of Genetics and Developmental Biology, University of Connecticut Health Center, 263 Farmington Ave., Farmington, CT 06410, USA.

出版信息

Mol Cell Biol. 2004 Jun;24(11):4677-84. doi: 10.1128/MCB.24.11.4677-4684.2004.

DOI:10.1128/MCB.24.11.4677-4684.2004
PMID:15143163
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC416395/
Abstract

The mechanism by which the high-bone-mass (HBM) mutation (G171V) of the Wnt coreceptor LRP5 regulates canonical Wnt signaling was investigated. The mutation was previously shown to reduce DKK1-mediated antagonism, suggesting that the first YWTD repeat domain where G171 is located may be responsible for DKK-mediated antagonism. However, we found that the third YWTD repeat, but not the first repeat domain, is required for DKK1-mediated antagonism. Instead, we found that the G171V mutation disrupted the interaction of LRP5 with Mesd, a chaperone protein for LRP5/6 that is required for transport of the coreceptors to cell surfaces, resulting in fewer LRP5 molecules on the cell surface. Although the reduction in the number of cell surface LRP5 molecules led to a reduction in Wnt signaling in a paracrine paradigm, the mutation did not appear to affect the activity of coexpressed Wnt in an autocrine paradigm. Together with the observation that osteoblast cells produce autocrine canonical Wnt, Wnt7b, and that osteocytes produce paracrine DKK1, we think that the G171V mutation may cause an increase in Wnt activity in osteoblasts by reducing the number of targets for paracrine DKK1 to antagonize without affecting the activity of autocrine Wnt.

摘要

研究了Wnt共受体LRP5的高骨量(HBM)突变(G171V)调节经典Wnt信号传导的机制。先前已证明该突变可减少DKK1介导的拮抗作用,这表明G171所在的第一个YWTD重复结构域可能负责DKK介导的拮抗作用。然而,我们发现DKK1介导的拮抗作用需要第三个YWTD重复结构域,而不是第一个重复结构域。相反,我们发现G171V突变破坏了LRP5与Mesd的相互作用,Mesd是LRP5/6的伴侣蛋白,是共受体转运到细胞表面所必需的,导致细胞表面的LRP5分子减少。虽然细胞表面LRP5分子数量的减少导致旁分泌模式下Wnt信号传导的减少,但在自分泌模式下该突变似乎并未影响共表达的Wnt的活性。结合成骨细胞产生自分泌经典Wnt、Wnt7b以及骨细胞产生旁分泌DKK1的观察结果,我们认为G171V突变可能通过减少旁分泌DKK1拮抗的靶点数量而不影响自分泌Wnt的活性,从而导致成骨细胞中Wnt活性增加。

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