骨密度与跟骨定量超声测量之间的独特和共同遗传效应：费尔斯纵向研究

Unique and common genetic effects between bone mineral density and calcaneal quantitative ultrasound measures: the Fels Longitudinal Study.

作者信息

Lee M, Czerwinski S A, Choh A C, Demerath E W, Sun S S, Chumlea W C, Towne B, Siervogel R M

机构信息

Lifespan Health Research Center, Department of Community Health, Boonshoft School of Medicine, Wright State University, 3171 Research Blvd., Dayton, OH 45420, USA.

出版信息

Osteoporos Int. 2006;17(6):865-71. doi: 10.1007/s00198-006-0075-4. Epub 2006 Mar 16.

DOI:10.1007/s00198-006-0075-4

PMID:16541205

Abstract

INTRODUCTION

Areal bone mineral density (BMD) and calcaneal quantitative ultrasound (QUS) measures are correlated, and both traits predict osteoporotic fracture risk independently. However, few studies have examined whether common genetic effects (i.e., pleiotropy) exist between these traits in extended families. In this study, we estimated the additive genetic correlation and random environmental correlation between BMD measured at various skeletal sites and calcaneal QUS measures.

METHODS

Our sample included 537 adults (251 men and 286 women) from 110 families participating in the Fels Longitudinal Study. Total hip, femoral neck, lumbar spine, and total body BMD were measured using dual energy X-ray absorptiometry. Three measures of calcaneal structure--broadband ultrasound attenuation (BUA), speed of sound (SOS), and quantitative ultrasound index (QUI)--were collected from the non-dominant heel using the Sahara sonometer. Applying a variance components-based maximum likelihood method, we estimated the heritability of each trait and estimated the genetic and environmental correlations between the different BMD and QUS measures.

RESULTS

Heritability estimates were significant for all measures of BMD and QUS ranging from 0.55 to 0.78. Significant non-zero genetic correlations were found between the different BMD and QUS measures. All genetic correlations were also significantly different from 1. Genetic correlations between total hip BMD and each of the QUS measures were 0.63 with BUA, 0.50 with SOS, and 0.56 with QUI. For femoral neck BMD, genetic correlations were similar to those between total hip BMD and QUS measures. Genetic correlations between BMD of the lumbar spine and QUS measures ranged from 0.34 to 0.38, and those between total body BMD and QUS measures, from 0.51 to 0.54. In contrast, all random environmental correlations were not significantly different from zero.

CONCLUSION

This study demonstrates that BMD and calcaneal QUS measures among healthy men and women are significantly heritable and are, in part, jointly influenced by a common set of underlying genes. Additionally, this study also provides evidence for a unique set of genes that independently influences each individual trait.

摘要

引言

骨面积骨密度（BMD）和跟骨定量超声（QUS）测量结果具有相关性，且这两种特征均可独立预测骨质疏松性骨折风险。然而，很少有研究探讨在大家庭中这些特征之间是否存在共同的遗传效应（即多效性）。在本研究中，我们估计了不同骨骼部位测量的骨密度与跟骨QUS测量结果之间的加性遗传相关性和随机环境相关性。

方法

我们的样本包括来自参与费尔斯纵向研究的110个家庭的537名成年人（251名男性和286名女性）。使用双能X线吸收法测量全髋、股骨颈、腰椎和全身的骨密度。使用Sahara骨密度仪从非优势足跟收集跟骨结构的三项测量指标——宽带超声衰减（BUA）、声速（SOS）和定量超声指数（QUI）。应用基于方差成分的最大似然法，我们估计了每个特征的遗传力，并估计了不同骨密度和QUS测量结果之间的遗传和环境相关性。

结果

所有骨密度和QUS测量指标的遗传力估计值均显著，范围从0.55到0.78。在不同的骨密度和QUS测量结果之间发现了显著的非零遗传相关性。所有遗传相关性也均显著不同于1。全髋骨密度与各QUS测量指标之间的遗传相关性分别为：与BUA为0.63，与SOS为0.50，与QUI为0.56。对于股骨颈骨密度，遗传相关性与全髋骨密度和QUS测量指标之间的相似。腰椎骨密度与QUS测量指标之间的遗传相关性范围为0.34至0.38，全身骨密度与QUS测量指标之间的遗传相关性范围为0.51至0.54。相比之下，所有随机环境相关性均与零无显著差异。

结论

本研究表明，健康男性和女性的骨密度和跟骨QUS测量结果具有显著的遗传性，并且在一定程度上受到一组共同潜在基因的共同影响。此外，本研究还为一组独立影响每个个体特征的独特基因提供了证据。

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骨密度与跟骨定量超声测量之间的独特和共同遗传效应：费尔斯纵向研究

Unique and common genetic effects between bone mineral density and calcaneal quantitative ultrasound measures: the Fels Longitudinal Study.

作者信息

机构信息

出版信息

INTRODUCTION

METHODS

RESULTS

CONCLUSION

引言

方法

结果

结论

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