PHACTR3基因与中国汉族和美国高加索人群骨密度的关联研究

研究组前期的全基因组关联研究发现PHACTR3基因与骨折关联,为了检测该基因与骨密度的关联关系,采用精细定位关联研究来检测PHACTR3基因内及其附近的SNPs与骨密度的关系。首先在中国样本（1627个不相关的汉族样本）和美国样本（2286个不相关高加索样本）中对PHACTR3基因的140个SNPs进行基因分型,然后采用Plink软件检测PHACTR3基因与腰椎和髋部骨密度的关联关系。发现研究组以前报道的与骨折关联的SNPs rs1555364和rs6064822与腰椎和髋部骨密度关联（P=4．89×10^-2-1．26×10^-2）。另外还发现位于PHACTR3基因内含子中3个SNPs位点（rs6027138,rs1182531和rs1182532）与中国人群和白人腰椎骨密度均显著关联,将中国人与白人样本合并起来进行荟萃分析（Meta—analysis）,得到合并P值为1．40×10^-3到4．00×10^-4,另外发现rs6064820与髋部BMD相关联,合并P值为6．70×10^-3。本研究进一步证实了PHACTR3基因在骨密度变异中的作用,对骨质疏松发病机制的认识提供了新的理论依据。     

ZBTB40基因与中国汉族人群和美国高加索人群骨密度的关联研究

最近的全基因组关联研究发现ZBTB40(zinc finger and BTB domain containing 40)基因是一个潜在的调节骨密度的新基因,为了可靠地验证该基因与骨密度的关联关系,采用精细定位关联研究来检测ZBTB40基因内及其附近的SNPs与骨密度的关系.首先在中国样本(1 627个不相关的汉族样本)和美国样本(2 286个不相关高加索样本)中对ZBTB40基因的50个SNPs进行基因分型,然后采用Plink软件检测ZBTB40基因与腰椎和髋部骨密度的关联关系.证实了以前报道的SNPs rs7524102与腰椎和髋部骨密度的关联关系.另外还发现5个SNPs(rs10917209、rs6426748、rs4433361、rs3856183和rs7550872)与腰椎和髋部骨密度相关联.其中最显著的SNP是位于ZBTB40基因上游区域的rs6426748,其与腰椎骨密度的关联P值为9.82×10-4,多重检验校正后仍然显著.连锁不平衡分析表明rs6426748与rs10917209,rs7524102和rs7550872呈现高度连锁关系,位于长度为27 kb的单体型块内,因此ZBTB40基因的功能致病位点可能是rs6426748或该单体型块内某一未分型的SNP.     

广州地区中老年男性RANK/RANKL/OPG和WNT信号通路基因多态性与髋部骨强度的关联分析

为了探讨RANK/RANKL/OPG和WNT信号通路中6个基因10个单核苷酸多态性位点与中老年男性髋部骨强度的关联,征集788名广州地区40岁以上男性为研究对象,采用Mass Array检测基因型,双能X线吸收仪测定股骨颈骨密度(bone mineral density,BMD)、横截面积(cross-sectional area,CSA)、平均皮质厚度(average cortical thickness,ACT)、剖面模数(section modulus,SM)和抗屈曲率(buckling ratio,BR),以多重线性回归分析各位点与骨表型的关联。结果发现:OPG基因rs3134069的C等位基因与BMD(β=-0.017,P=0.024)和ACT(β=-0.004,P=0.040)负相关;LRP5基因rs3736228的T等位基因与低BMD、CSA、ACT(β=-0.050~-0.003,P0.050)和高BR(β=0.242,P=0.043)相关,rs491347的G等位基因与低BMD相关(β=-0.012,P=0.046)。研究结果支持了OPG和LRP5基因与中国中老年男性人群髋部骨强度相关。     

PI3K/AKT信号通路调控Myogenin和MCK基因的表达

骨骼肌分化过程受多个信号通路调控, PI3K/AKT信号通路是其中最重要的信号转导通路之一。PI3K/AKT信号通路可以调控骨骼肌分化, 但在染色质水平上的调控机制还不是很清楚。文章以小鼠成肌细胞(C2C12)为研究材料, 采用免疫印迹、染色质免疫共沉淀(Chromatin immunoprecipitation, ChIP)、定量PCR (Q-PCR)的方法研究PI3K/AKT信号通路调控Myogenin和MCK基因的表达。研究发现, C2C12细胞分化过程中添加PI3K/AKT信号通路激活剂处理24 h, Myogenin和MCK蛋白表达水平显著升高, 组蛋白H3K27me3去甲基化酶UTX的表达也升高, H3K27me3在Myogenin基因启动子区和MCK基因启动子及增强子区的富集与对照组相比显著降低。用PI3K/AKT信号通路抑制剂处理, 结果相反。因此, PI3K/AKT信号通路可能通过调控组蛋白去甲基化酶UTX的表达活性改变靶基因的H3K27me3的富集进而调控骨骼肌分化。     

TAZ介导的Wnt/β-catenin信号通路与骨髓基质干细胞的成骨分化

骨质疏松症是由于骨重建过程中骨形成和骨吸收失平衡导致骨总量丢失所致,与成骨细胞分化密切相关。Hippo通路影响着哺乳动物体内细胞增殖、分化和凋亡过程。Wnt/β-catenin通路在成骨细胞分化中扮演重要角色。Hippo下游的靶基因转录共激活因子TAZ脱磷酸化后具有促进骨髓基质干细胞(BMSCs)向成骨细胞分化,调节成骨特异基因骨钙素表达,调节骨、肾发育,激活Wnt/β-catenin通路转录反应的功能;而激活的Wnt/β-catenin通路能通过抑制β-catenin降解进而抑制TAZ的降解。因此,TAZ与Wnt/β-catenin通路相互调控。但是,对TAZ与Wnt/β-catenin通路串话是否影响BMSCs成骨能力尚不清楚。因此,深入研究TAZ介导的Wnt/β-catenin通路在骨代谢中的作用,将为深入了解骨质疏松的发病机制具有重要意义。     

全基因组关联分析显示SOX6为影响腕部骨密度的候选基因

骨质疏松症是一种高度遗传且极易导致骨折的骨骼疾病, 它严重损害患者的生活质量. 因骨质疏松而导致的手腕骨折, 很大程度是由于手腕部位的骨量低. 本研究在1000个不相关的白人中采用Affymetix 500K芯片扫描了500000个SNPs, 运用全基因组关联分析(GWAS), 发现SOX6为影响手腕骨密度的一个新的基因, SOX6基因中rs11023787与手腕部骨密度关联, P值为9.00×10^-5. SOX6基因中, rs11023787 C等位基因携带者的手腕骨密度显著高于T等位基因携带者(C等位基因 vs. T等位基因携带者: 0.485 g/cm² vs. 0.462 g/cm²). 为进一步验证该结果, 在中国人群中检测了SOX6基因与骨密度的关联并发现, rs11023787与手腕骨密度显著关联(P=6.41×10^-3). 对GWAS与验证结果进行荟萃分析, 得到联合P值为5.20×10^-6, SOX6基因参与软骨形成过程. 本结果提示, SOX6基因是影响骨密度变异的重要基因.     

组蛋白修饰对胚胎干细胞分化过程[]的调控机制

选用人类胚胎干细胞系和由人类胚胎干细胞系分化来的神经干细胞系为研究对象,分析组蛋白修饰对胚胎干细胞分化过程的调控作用。得到了两种细胞系差异表达基因转录起始位点侧翼区域内八种组蛋白修饰的分布模式,以及组蛋白修饰功能簇。研究表明在两类细胞系中,八种组蛋白修饰谱分布模式一致,且呈现两种分布类型; H3K27ac,H3K4me3和H3K9ac组成的功能簇是保守的;H3K27me3,H3K36me3和H3K79me1组成的功能簇以及H3K9me3和H3K27me3组成的功能簇在胚胎干细胞向神经干细胞分化的过程中消失。结果揭示了组蛋白修饰对胚胎干细胞系向神经干细胞系分化过程的部分调控机制,为该分化过程分子调控机制的研究提供部分重要的理论基础。     

基于核心家系的EGR3基因与精神分裂症的关联研究

研究表明位于染色体8p21.3区域的EGR3(Early growth response 3)是精神分裂症(Schizophrenia)的重要易感基因,然而,仍有两个病例-对照研究未能验证上述发现。为了研究EGR3基因在我国患者中是否与疾病关联,文章在中国汉族的核心家系中选择EGR3基因座位上的5个SNPs位点(rs1996147、rs1877670、rs3750192、rs35201266和rs7009708)进行基因分型和传递不平衡检验(Transmission disequilibrium test,TDT)。结果表明遗传标记rs1996147和rs3750192分别显示出显著的传递不平衡(2>4.40,P<0.05)。在连锁不平衡分析中,由2个(rs3750192和rs35201266)、3个(rs1877670、rs3750192和rs7009708)以及4个(rs1996147、rs1877670、rs3750192和rs7009708)SNPs位点构建的单倍型均显示与精神分裂症显著性关联(2>7.10,整体P<0.05)。总之,EGR3基因与中国汉族人群精神分裂症遗传易感性相关,后续关于EGR3基因进一步的功能研究将会更好的帮助我们了解该基因在疾病病理学机制中的作用。     

TGF-β/BMPs、Wnt和MAPK信号通路在间充质干细胞向成骨细胞分化中的作用

间充质干细胞(mesenchymal stem cells,MSCs)是一种多潜能成体干细胞,具有向成骨细胞分化的能力.在MSCs向成骨细胞分化中,受到多种信号通路调控,其中TGF-β/BMPs、Wnt、MAPK信号通路发挥了重要作用.而且,通过对Smad1蛋白酶体的调节,Wnt和MAPK信号可以对TGF-β/BMPs通路进行调控.在相关信号通路的共同作用下,MSCs向成骨细胞分化.现对MSCs分化过程中TGF-β/BMPs、Wnt、MAPK这三条通路进行了简要综述.     

基于核心家系的EGR3基因与精神分裂症的关联研究

研究表明位于染色体8p21.3区域的EGR3(Early growth response 3)是精神分裂症(Schizophrenia)的重要易感基因, 然而, 仍有两个病例-对照研究未能验证上述发现。为了研究EGR3基因在我国患者中是否与疾病关联, 文章在中国汉族的核心家系中选择EGR3基因座位上的5个SNPs位点(rs1996147、rs1877670、rs3750192、rs35201266和rs7009708)进行基因分型和传递不平衡检验(Transmission disequilibrium test, TDT)。结果表明遗传标记rs1996147和rs3750192分别显示出显著的传递不平衡(c²>4.40, P<0.05)。在连锁不平衡分析中, 由2个(rs3750192和rs35201266)、3个(rs1877670、rs3750192和rs7009708)以及4个(rs1996147、rs1877670、rs3750192和rs7009708)SNPs位点构建的单倍型均显示与精神分裂症显著性关联(c²>7.10, 整体P<0.05)。总之, EGR3基因与中国汉族人群精神分裂症遗传易感性相关, 后续关于EGR3基因进一步的功能研究将会更好的帮助我们了解该基因在疾病病理学机制中的作用。     

Identification of a role for the ARHGEF3 gene in postmenopausal osteoporosis

Osteoporosis is a common and debilitating bone disease characterized by low bone mineral density (BMD), a highly heritable and polygenic trait. Genome-wide linkage studies have identified 3p14-p21 as a quantitative trait locus for BMD. The ARHGEF3 gene is situated within this region and was identified as a strong positional candidate. The aim of this study was to evaluate the role of variation in ARHGEF3 on bone density in women. Sequence variation within ARHGEF3 was analyzed with 17 single-nucleotide polymorphisms (SNPs) in a discovery cohort of 769 female sibs. Significant associations were found with family-based association tests between five SNPs and various measures of age-adjusted BMD (p = 0.0007-0.041) with rs7646054 showing maximal association. Analysis of the data with QPDTPHASE suggested that the more common G allele at rs7646054 is associated with decreased age-adjusted BMD. Significant associations were also demonstrated between 3-SNP haplotypes and age-adjusted spine and femoral-neck BMD (p = 0.002 and 0.003, respectively). rs7646054 was then genotyped in a replication cohort, and significant associations with hip and spine BMD were confirmed (p = 0.003-0.038), as well as an association with fracture rate (p = 0.02). Again, the G allele was associated with a decrease in age-adjusted BMD at each site studied. In conclusion, genetic variation in ARHGEF3 plays a role in the determination of bone density in Caucasian women. This data implicates the RhoGTPase-RhoGEF pathway in osteoporosis.     

Comprehensive analysis of the association of EGFR,CALM3 and SMARCD1 gene polymorphisms with BMD in Caucasian women

Summary

Three genes, including EGFR (epidermal growth factor receptor), CALM3 (calmodulin 3, calcium-modulated protein 3) and SMARCD1 (SWI/SNF-related matrix-associated actin-dependent regulator of chromatin subfamily d member 1), play different roles in bone and/or fat metabolism in Caucasian women. In this population-based investigation of 870 unrelated postmenopausal Caucasian women, CALM3 polymorphisms were significantly associated with femoral neck bone mineral density (FNK BMD), hip BMD and spine BMD. Age and tobacco status also affected BMD levels and were therefore corrected for in our statistical analysis.

Introduction

EGFR, CALM3 and SMARCD1 play roles in bone and/or fat metabolism. However, the correlations between the polymorphisms of these three genes and body composition levels, including BMD, remain to be determined.

Materials and Methods

A population-based investigation of 870 white women was conducted. Forty-four SNPs (single nucleotide polymorphisms) in EGFR, CALM3 and SMARCD1 were chosen by the software, including those of potential functional importance. The candidate SNPs were genotyped by the KASPar assay for an association analysis with body composition levels. The correlation analysis was assessed by the Pearson''s product-moment correlation coefficient and Spearman rank-order correlation tests, and the family-wise error was corrected using the Wald test implemented in PLINK.

Results

The SNP rs12461917 in the 3′-flanking region of the CALM3 gene was significantly associated with FNK BMD (P = 0.001), hip BMD (P<0.001) and spine BMD (P = 0.001); rs11083838 in the 5′-flanking region of CALM3 gene was associated with spine BMD (P = 0.009). After adjusting for multiple comparisons, rs12461917 remained significant (P-adjusted  = 0.033 for FNK BMD, P-adjusted  = 0.006 for hip BMD and P-adjusted  = 0.018 for spine BMD).

Conclusions

Our data show that polymorphisms of the CALM3 gene in Caucasian women may contribute to variations in the BMD of the hip, spine and femoral neck.     

Genetic Analysis Identifies DDR2 as a Novel Gene Affecting Bone Mineral Density and Osteoporotic Fractures in Chinese Population

DDR2 gene, playing an essential role in regulating osteoblast differentiation and chondrocyte maturation, may influence bone mineral density (BMD) and osteoporosis, but the genetic variations actually leading to the association remain to be elucidated. Therefore, the aim of this study was to investigate whether the genetic variants in DDR2 are associated with BMD and fracture risk. This study was performed in three samples from two ethnicities, including 1,300 Chinese Han subjects, 700 Chinese Han subjects (350 with osteoporotic hip fractures and 350 healthy controls) and 2,286 US white subjects. Twenty-eight SNPs in DDR2 were genotyped and tested for associations with hip BMD and fractures. We identified 3 SNPs in DDR2 significantly associated with hip BMD in the Chinese population after multiple testing adjustments, which were rs7521233 (P = 1.06×10⁻⁴, β: −0.018 for allele C), rs7553831 (P = 1.30×10⁻⁴, β: −0.018 for allele T), and rs6697469 (P = 1.59×10⁻³, β: −0.015 for allele C), separately. These three SNPs were in high linkage disequilibrium. Haplotype analyses detected two significantly associated haplotypes, including one haplotype in block 2 (P = 9.54×10⁻⁴, β: −0.016) where these three SNPs located. SNP rs6697469 was also associated with hip fractures (P = 0.043, OR: 1.42) in the Chinese population. The effect on fracture risk was consistent with its association with lower BMD. However, in the white population, we didn’t observe significant associations with hip BMD. eQTL analyses revealed that SNPs associated with BMD also affected DDR2 mRNA expression levels in Chinese. Our findings, together with the prior biological evidence, suggest that DDR2 could be a new candidate for osteoporosis in Chinese population. Our results also reveal an ethnic difference, which highlights the need for further genetic studies in each ethnic group.     

Why SNP rs227584 is associated with human BMD and fracture risk? A molecular and cellular study in bone cells

A large number of SNPs significant for osteoporosis (OP) had been identified by genome‐wide association studies. However, the underlying association mechanisms were largely unknown. From the perspective of protein phosphorylation, gene expression regulation, and bone cell activity, this study aims to illustrate association mechanisms for representative SNPs of interest. We utilized public databases and bioinformatics tool to identify OP‐associated SNPs which potentially influence protein phosphorylation (phosSNPs). Associations with hip/spine BMD, as well as fracture risk, in human populations for one significant phosSNP, that is, rs227584 (major/minor allele: C/A, EAS population) located in C17orf53 gene, were suggested in prior meta‐analyses. Specifically, carriers of allele C had significant higher BMD and lower risk of low‐trauma fractures than carriers of A. We pursued to test the molecular and cellular functions of rs227584 in bone through osteoblastic cell culture and multiple assays. We identified five phosSNPs significant for OP (P < 0.01). The osteoblastic cells, which was transfected with wild‐type C17orf53 (allele C at rs227584, P126), demonstrated specific interaction with NEK2 kinase, increased expression levels of osteoblastic genes significantly (OPN, OCN, COL1A1, P < 0.05), and promoted osteoblast growth and ALP activity, in contrast to those transfected with mutant C17orf53 (allele A at rs227584, T126). In the light of the consistent evidences between the present functional study in human bone cells and the prior association studies in human populations, we conclude that the SNP rs227584, via altering protein‐kinase interaction, regulates osteoblastic gene expression, influences osteoblast growth and activity, hence to affect BMD and fracture risk in humans.     

Pathway analysis of genome-wide association study for bone mineral density

The aim of this study was to identify the candidate causal single nucleotide polymorphisms (SNPs) and candidate causal mechanisms that contribute to bone mineral density (BMD) and to generate a SNP to gene to pathway hypothesis using an analytical pathway-based approach. We used hip BMD GWAS data of the genotypes of 301,019 SNPs in 5,715 Europeans. ICSNPathway (identify candidate causal SNPs and pathways) analysis was applied to the BMD GWAS dataset. The first stage involved the pre-selection of candidate causal SNPs by linkage disequilibrium analysis and the functional SNP annotation of the most significant SNPs found. The second stage involved the annotation of biological mechanisms for the pre-selected candidate causal SNPs using improved-gene set enrichment analysis. ICSNPathway analysis identified seven candidate SNPs, eight candidate pathways, and seven hypothetical biological mechanisms. Eight pathways are as follows; gamma-hexachlorocyclohexane degradation (nominal p-value < 0.001, false discovery rate (FDR) <0.001), regulation of the smoothened signaling pathway (nominal p-value < 0.001, FDR = 0.016), TACI and BCMA stimulation of B cell immune response (nominal p-value < 0.001, FDR = 0.021), endonuclease activity (nominal p-value = 0.001, FDR = 0,026), regulation of defense response to virus (nominal p-value = 0.001, FDR = 0.028), serine_type_endopeptidase_inhibitor_activity (nominal p-value = 0.001, FDR = 0.044), endoribonuclease activity (nominal p-value = 0.002, FDR = 0.045), and myeloid leukocyte differentiation (nominal p-value = 0.001, FDR = 0.050). The most significant causal pathway was gamma-hexachlorocyclohexane degradation. CYP3A5, PON2, PON3, CMBL, PON1, ALPL, CYP3A43, CYP3A7, ACP6, ACPP, and ALPI (p < 0.05) are involved in the pathway of gamma-hexachlorocyclohexane degradation. Further examination of the gene contents revealed that DBR1, DICER1, EXO1, FEN1, POP1, POP4, RPP30, and RPP38 were involved in 2 of the 8 pathways (p < 0.05). By applying ICSNPathway analysis to BMD GWAS data, we identified seven candidate SNPs and eight pathways involving gamma-hexachlorocyclohexane degradation, which may contribute to low BMD.     

Variation in genes involved in the RANKL/RANK/OPG bone remodeling pathway are associated with bone mineral density at different skeletal sites in men

In order to assess the contribution of polymorphisms in the RANKL (TNFSF11), RANK (TNFRSF11A) and OPG (TNFRSF11B) genes to variations in bone mineral density (BMD), a population-based cohort with 1,120 extreme low hip BMD cases or extreme high hip BMD controls was genotyped on five SNPs. We further explored the associations between these genetic variations and forearm BMDs by genotyping 266 offspring and 309 available parents from 160 nuclear families. A family-based association test was used. Significantly positive associations were found for A163G polymorphisms in the promoter regions of the OPG gene, a missense substitution in exon 7 (Ala192Val) of the RANK gene and rs9594782 SNP in the 5′ UTR of the RANKL gene with BMD in men only. Men with TC/CC genotypes of the rs9594782 SNP had a 2.1 times higher risk of extremely low hip BMD (P=0.004), and lower whole body BMD (P<0.001). Subjects with the TC genotype of the Ala192Val polymorphism had a 40% reduced risk of having extremely low hip BMD (P<0.01), and higher whole body BMD (P<0.01). Subjects with the GG genotype of the A163G polymorphism had a 70% reduced risk of having extremely low hip BMD (P<0.05), and higher whole body BMD (P<0.01). Significant gene–gene interactions were also observed among the OPG, RANK and RANKL genes. Our findings suggest that genetic variation in genes involved in the RANKL/RANK/OPG bone remodeling pathway are strongly associated with BMD at different skeletal sites in adult men, but not in women. Electronic Supplementary Material Supplementary material is available for this article at     

ADRA2A is involved in neuro‐endocrine regulation of bone resorption

Adrenergic stimulation is important for osteoclast differentiation and bone resorption. Previous research shows that this happens through β2‐adrenergic receptor (AR), but there are conflicting evidence on presence and role of α2A‐AR in bone. The aim of this study was to investigate the presence of α2A‐AR and its involvement in neuro‐endocrine signalling of bone remodelling in humans. Real‐time polymerase chain reaction (PCR) and immunohistochemistry were used to investigate α2A‐AR receptor presence and localization in bone cells. Functionality of rs553668 and rs1800544 single nucleotide polymorphism SNPs located in α2A‐AR gene was analysed by qPCR expression on bone samples and luciferase reporter assay in human osteosarcoma HOS cells. Using real‐time PCR, genetic association study between rs553668 A>G and rs1800544 C>G SNPs and major bone markers was performed on 661 Slovenian patients with osteoporosis. α2A‐AR is expressed in osteoblasts and lining cells but not in osteocytes. SNP rs553668 has a significant influence on α2A‐AR mRNA level in human bone samples through the stability of mRNA. α2A‐AR gene locus associates with important bone remodelling markers (BMD, CTX, Cathepsin K and pOC). The results of this study are providing comprehensive new evidence that α2A‐AR is involved in neuro‐endocrine signalling of bone turnover and development of osteoporosis. As shown by our results the neurological signalling is mediated through osteoblasts and result in bone resorption. Genetic study showed association of SNPs in α2A‐AR gene locus with bone remodelling markers, identifying the individuals with higher risk of development of osteoporosis.     

The fat mass and obesity associated gene, FTO, is also associated with osteoporosis phenotypes

Obesity and osteoporosis are closely correlated genetically. FTO gene has been consistently identified to be associated with obesity phenotypes. A recent study reported that the mice lacking Fto could result in lower bone mineral density (BMD). Thus, we hypothesize that the FTO gene might be also important for osteoporosis phenotypes. To test for such a hypothesis, we performed an association analyses to investigate the relationship between SNPs in FTO and BMD at both hip and spine. A total of 141 SNPs were tested in two independent Chinese populations (818 and 809 unrelated Han subjects, respectively) and a Caucasian population (2,286 unrelated subjects). Combining the two Chinese samples, we identified 6 SNPs in FTO to be significantly associated with hip BMD after multiple testing adjustments, with the combined P values ranged from 4.99×10⁻⁴–1.47×10⁻⁴. These 6 SNPs are all located at the intron 8 of FTO and in high linkage disequilibrium. Each copy of the minor allele of each SNP was associated with increased hip BMD values with the effect size (beta) of ∼0.025 and ∼0.015 in the Chinese sample 1 and 2, respectively. However, none of these 6 SNPs showed significant association signal in the Caucasian sample, by presenting some extent of ethnic difference. Our findings, together with the prior biological evidence, suggest that the FTO gene might be a new candidate for BMD variation and osteoporosis in Chinese populations.