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通过转移到Gcm2基因敲除背景上来挽救CasR缺陷小鼠的骨骼表型。

Rescue of the skeletal phenotype in CasR-deficient mice by transfer onto the Gcm2 null background.

作者信息

Tu Qisheng, Pi Min, Karsenty Gerard, Simpson Leigh, Liu Shiguang, Quarles L Darryl

机构信息

Center for Bone and Mineral Disorders, Duke University Medical Center, Durham, North Carolina 27710, USA.

出版信息

J Clin Invest. 2003 Apr;111(7):1029-37. doi: 10.1172/JCI17054.

DOI:10.1172/JCI17054

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC152586/

Abstract

To understand the role of the calcium-sensing receptor (CasR) in the skeleton, we used a genetic approach to ablate parathyroid glands and remove the confounding effects of elevated parathyroid hormone (PTH) in CasR-deficient mice. CasR deficiency was transferred onto the glial cells missing 2-deficient (Gcm2-deficient) background by intercrossing CasR- and Gcm2-deficient mice. Superimposed Gcm2 deficiency rescued the perinatal lethality in CasR-deficient mice in association with ablation of the parathyroid glands and correction of the severe hyperparathyroidism. In addition, the double homozygous CasR- and Gcm2-deficient mice demonstrated healing of the abnormal mineralization of cartilage and bone associated with CasR deficiency, indicating that rickets and osteomalacia in CasR-deficient mice are not due to an independent function of CasR in bone and cartilage but to the effect of severe hyperparathyroidism in the neonate. Analysis of the skeleton of 6-week-old homozygous CasR- and Gcm2-deficient mice also failed to identify any essential, nonredundant role for CasR in regulating chondrogenesis or osteogenesis, but further studies are needed to establish the function of CasR in the skeleton. In contrast, concomitant Gcm2 and CasR deficiency failed to rescue the hypocalciuria in CasR-deficient mice, consistent with direct regulation of urinary calcium excretion by CasR in the kidney. Double Gcm2- and CasR-deficient mice provide an important model for evaluating the extraparathyroid functions of CasR.

摘要

为了解钙敏感受体（CasR）在骨骼中的作用，我们采用遗传学方法切除甲状旁腺，以消除甲状旁腺激素（PTH）升高对CasR基因敲除小鼠造成的混杂影响。通过将CasR基因敲除小鼠与胶质细胞缺失2基因敲除（Gcm2基因敲除）小鼠杂交，将CasR缺陷转移到Gcm2缺陷背景上。叠加的Gcm2缺陷挽救了CasR缺陷小鼠的围产期致死率，这与甲状旁腺的切除以及严重甲状旁腺功能亢进的纠正有关。此外，双纯合CasR和Gcm2缺陷小鼠显示出与CasR缺陷相关的软骨和骨异常矿化的愈合，这表明CasR缺陷小鼠的佝偻病和骨软化症并非由于CasR在骨和软骨中的独立功能，而是由于新生儿严重甲状旁腺功能亢进的影响。对6周龄纯合CasR和Gcm2缺陷小鼠骨骼的分析也未能确定CasR在调节软骨生成或骨生成中的任何重要的、非冗余的作用，但需要进一步研究来确定CasR在骨骼中的功能。相比之下，同时存在的Gcm2和CasR缺陷未能挽救CasR缺陷小鼠的低钙尿症，这与CasR对肾脏尿钙排泄的直接调节一致。双Gcm2和CasR缺陷小鼠为评估CasR的甲状旁腺外功能提供了一个重要模型。