Polymorphisms in genes involved in the NF-κB signalling pathway are associated with bone mineral density, geometry and turnover in men.
Journal: 2012/April - PLoS ONE
ISSN: 1932-6203
Abstract:
BACKGROUND
In this study, we aimed to investigate the association between single nucleotide polymorphisms (SNPs) within two genes involved in the NF-κB cascade (GPR177 and MAP3K14) and bone mineral density (BMD) assessed at different skeletal sites, radial geometric parameters and bone turnover.
METHODS
Ten GPR177 SNPs previously associated with BMD with genome-wide significance and twelve tag SNPs (r(2)≥0.8) within MAP3K14 (±10 kb) were genotyped in 2359 men aged 40-79 years recruited from 8 centres for participation in the European Male Aging Study (EMAS). Measurement of bone turnover markers (PINP and CTX-I) in the serum and quantitative ultrasound (QUS) at the calcaneus were performed in all centres. Dual energy X-ray absorptiometry (DXA), at the lumbar spine and hip, and peripheral quantitative computed tomography (pQCT), at the distal and midshaft radius, were performed in a subsample (2 centres). Linear regression was used to test for association between the SNPs and bone measures under an additive genetic model adjusting for study centre.
RESULTS
We validated the associations between SNPs in GPR177 and BMD(a) previously reported and also observed evidence of pleiotrophic effects on density and geometry. Rs2772300 in GPR177 was associated with increased total hip and LS BMD(a), increased total and cortical vBMD at the radius and increased cortical area, thickness and stress strain index. We also found evidence of association with BMD(a), vBMD, geometric parameters and CTX-I for SNPs in MAP3K14. None of the GPR177 and MAP3K14 SNPs were associated with calcaneal estimated BMD measured by QUS.
CONCLUSIONS
Our findings suggest that SNPs in GPR177 and MAP3K14 involved in the NF-κB signalling pathway influence bone mineral density, geometry and turnover in a population-based cohort of middle aged and elderly men. This adds to the understanding of the role of genetic variation in this pathway in determining bone health.
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PLoS ONE. Dec/31/2010; 6(11)
Published online Nov/20/2011

Polymorphisms in Genes Involved in the NF-κB Signalling Pathway Are Associated with Bone Mineral Density, Geometry and Turnover in Men

+15 authors

Abstract

Introduction

In this study, we aimed to investigate the association between single nucleotide polymorphisms (SNPs) within two genes involved in the NF-κB cascade (GPR177 and MAP3K14) and bone mineral density (BMD) assessed at different skeletal sites, radial geometric parameters and bone turnover.

Methods

Ten GPR177 SNPs previously associated with BMD with genome-wide significance and twelve tag SNPs (r2≥0.8) within MAP3K14 (±10 kb) were genotyped in 2359 men aged 40–79 years recruited from 8 centres for participation in the European Male Aging Study (EMAS). Measurement of bone turnover markers (PINP and CTX-I) in the serum and quantitative ultrasound (QUS) at the calcaneus were performed in all centres. Dual energy X-ray absorptiometry (DXA), at the lumbar spine and hip, and peripheral quantitative computed tomography (pQCT), at the distal and midshaft radius, were performed in a subsample (2 centres). Linear regression was used to test for association between the SNPs and bone measures under an additive genetic model adjusting for study centre.

Results

We validated the associations between SNPs in GPR177 and BMDa previously reported and also observed evidence of pleiotrophic effects on density and geometry. Rs2772300 in GPR177 was associated with increased total hip and LS BMDa, increased total and cortical vBMD at the radius and increased cortical area, thickness and stress strain index. We also found evidence of association with BMDa, vBMD, geometric parameters and CTX-I for SNPs in MAP3K14. None of the GPR177 and MAP3K14 SNPs were associated with calcaneal estimated BMD measured by QUS.

Conclusion

Our findings suggest that SNPs in GPR177 and MAP3K14 involved in the NF-κB signalling pathway influence bone mineral density, geometry and turnover in a population-based cohort of middle aged and elderly men. This adds to the understanding of the role of genetic variation in this pathway in determining bone health.

Introduction

Osteoporosis is characterized by reduced bone mass and deterioration in bone micro-architecture leading to bone fragility and increased risk of fracture [1]. It is a major health problem with the lifetime risk of fracture estimated to be about 50% and 20% at age 50 years in women and men, respectively [2]. Prospective studies suggest that there is a strong relationship between levels of bone mineral density (BMD) and subsequent risk of fracture in both men [3] and women [4], [5].

Genetic factors are important determinants of bone mass. Family and twin studies suggest that up to 80% of areal BMD (BMDa) at the lumbar spine (LS) and hip is determined by genetic factors [6][8]. Genome-wide association studies (GWAS) have identified a number of loci associated with LS and hip BMDa reaching genome-wide significance (GWS), including the genes involved in the RANKL/RANK/OPG signalling pathway [9][12], which have also been associated with markers of bone turnover [13]. The RANKL/RANK/OPG signalling pathway has an important role in bone turnover. Interaction of RANKL (receptor activator of NF-κB ligand) with its receptor RANK (receptor activator of NF-κB) on the surface of osteoclast precursors [14] activates both canonical and non-canonical pathways of NF-κB. Subsequently, active NF-κB dimers move into the nucleus, bind to the DNA and cause gene transcription and osteoclast differentiation [15]. OPG acts as a decoy receptor for RANKL and can block its effects [14].

Rivadeneira et al. performed a meta-analysis of five GWAS of LS and femoral neck (FN) BMDa in approximately 20,000 subjects [10]. They strengthened the association of RANKL, RANK and OPG with BMDa; and also identified two new loci including genes involved in the NF-κB pathway. GPR177 is located on chromosome 1p31.3 and single nucleotide polymorphisms (SNPs) within this gene were associated with LS and FN BMDa at the GWS level [10]. GPR177 which is also known as WNTLESS homolog is an activator of the NF-κB pathway [16]. It also induces osteoblast differentiation through the Wnt signalling pathway [17]. A single SNP on chromosome 17q12, rs9303521, which is located about 400 kb upstream of MAP3K14, was also associated with LS BMDa at the GWS level in the meta-analysis [10]. MAP3K14 encodes NIK (NF-κB inducing kinase) which induces production of active NF-κB dimers in the non-canonical pathway [15].

In this study, we aimed to validate GPR177 SNP associations with BMDa and to determine if SNPs in MAP3K14 are associated with BMDa utilizing an independent population of middle-aged and elderly men recruited in the European Male Aging Study (EMAS) [18]. We also explored the influence of GPR177 and MAP3K14 SNPs on bone geometry, another important determinant of bone strength. As both genes investigated here are involved in bone turnover related pathways, one would expect that their effects on bone density and geometry would, at least partly, be through altering bone turnover. Therefore, we sought to test this hypothesis. We also investigated the combined effect of strongly associated SNPs in RANKL, RANK, OPG, GPR177 and MAP3K14 on BMDa.

Methods

Ethics statement

Ethical approval for the study was obtained in accordance with local institutional requirements in each centre: Florence (Ethical Committee of the Azienda Ospedaliera Careggi & University of Florence), Leuven (Commissie Medische Ethiek UZ Gasthuisberg & KU Leuven), Lodz (Bioethical Committee of Medical University of Lodz for Human Studies), Malmö (Ethical Committee of Lund University), Manchester (North West Multi Centre Ethical Research Committee, University of Manchester & CMMCUH), Santiago de Compostela (Comité Ético de Investigación Clínica de Galicia & Universidad de Santiago de Compostela), Szeged (Human Investigation Review Board, University of Szeged) and Tartu (Ethical Committee, Medical University of Tartu). All subjects provided written informed consent. Approval for the genetic analysis described here was obtained for seven of the eight centres. Therefore, analysis was restricted to subjects from these seven centres (all centres except for Malmö, Sweden).

Study Participants

Men aged 40–79 years were recruited from population registers in 8 European centres (Manchester, UK; Leuven, Belgium; Tartu, Estonia; Lodz, Poland; Szeged, Hungary; Florence, Italy; Santiago de Compostela, Spain; Malmö, Sweden) into the European Male Ageing Study, for further details see Lee at al. (2008) [19]. Blood samples were collected for genetic analysis. Quantitative ultrasound (QUS) at the calcaneus was performed in subjects at all centres. Dual energy X-ray absorptiometry (DXA) and peripheral quantitative computed tomography (pQCT) were performed in a subsample of subjects in two centres (Manchester, UK and Leuven, Belgium). Participants were excluded from this analysis if they reported that at least one of their parents or grandparents was born outside Europe or North America, or if they reported use of anti-osteoporotic medications or systemic glucocorticoids.

Bone Assessments

DXA

DXA scans were performed in Manchester and Leuven centres using a DXA QDR 4500A device (Hologic, Inc, Waltham, MA, USA). BMDa (g/cm2) was measured at LS (L1 to L4) and total hip (TH). All scans and measurements were performed by trained and experienced DXA technicians. The Hologic Spine Phantom was scanned daily to monitor the device performance and long-term stability. The precision of these measurements in the LS and TH were 0.57% and 0.56% in Leuven, and 0.97% and 0.97% in Manchester, respectively. Both devices were cross-calibrated with the European Spine Phantom [20].

pQCT

Peripheral QCT measurements were performed in the non-dominant radius using XCT-2000 scanners (Stratec, Pforzheim, Germany) in Manchester and Leuven centres following the manufacturer's standard quality assurance procedures. Total and trabecular vBMD (mg/mm3), and bone cross-sectional area (mm2) were measured at the distal radius (4%) (voxel size 0.4 mm). Cortical vBMD (mg/mm3); total, cortical and medullary area (mm2); cortical thickness (mm) and stress strain index (SSI) (mm3) were measured at the midshaft radius (50%) (voxel size 0.6 mm). The detailed methodology for these measurements has been described previously [21].

The European Forearm Phantom (EFP) was measured for cross-calibration between the two centres; 10 repeat measurements were taken in slices 1–4. The differences were less than precision error for total, trabecular and cortical vBMD, and cortical area. Therefore, no cross-calibration was performed between the two centres. The short term precision of 2 repeat measurements with repositioning were: 2.1% and 1.3% for total vBMD; 1.27% and 1.42% for trabecular vBMD; 0.77% and 0.71% for cortical vBMD; and 2.4% and 1.3% for cortical area; in Manchester (n = 22) and Leuven (n = 40), respectively.

QUS

BMD at the left calcaneus was estimated by QUS using the Sahara Clinical Sonometer (Hologic, Bedford, MA, USA) in all centres following a standardized protocol. Outputs included broadband ultrasound attenuation (BUA) (dB/MHz) and speed of sound (SOS) (m/s). Calcaneal eBMD was calculated (g/cm2) using the following formula: BMD = 0.002592×(BUA+SOS)−3.687. The CVs were 2.8%, 0.3% and 3.4% for BUA, SOS and BMD, respectively as described previously [13].

Bone Turnover Markers

Serum N-terminal propeptide of type I procollagen (PINP) (ng/ml) and C-terminal cross-linked telopeptide of type I collagen (CTX-I) (ng/ml) levels were measured in Leuven, using electrochemiluminescence immunoassay (ECLIA) (Roche Diagnostics) on samples from all centres. The detection limit of PINP assay was <5 ng/ml, and the intra-assay and inter-assay coefficients of variations (CVs) were 0.8–2.9 and 1.8–2.9%, respectively. The detection limit of CTX-I assay was 0.01 ng/ml, and the intra-assay and inter-assay CVs were 2.0–5.5% and 1.0–4.6%, respectively.

SNPs Selection

GPR177

The SNPs within GPR177 associated with LS or FN BMDa at the genome-wide significant level (p<5×10−8) in a previous GWAS meta-analysis [10] were selected for genotyping. Where SNPs were in high linkage disequilibrium (LD) (r2≥0.8) based on HapMap Phase II CEPH SNP data (http://www.hapmap.org), only one of them was genotyped.

MAP3K14

Pair-wise tag SNPs (r2≥0.8) were selected for SNPs in HapMap Phase II CEPH SNP data (http://www.hapmap.org) with a minor allele frequency (MAF) of greater than 5% within MAP3K14 and its 10 kb flanking regions using Tagger implemented in Haploview 4.0 [22].

Genotyping and Quality Control

SNPs were genotyped using SEQUENOM MassARRAY technology following the manufacturer's instructions (http://www.sequenom.com). Sample and assay quality control thresholds were set to 90%. The SNPs deviating from Hardy-Weinberg equilibrium (HWE), p≤0.05, were excluded from the analysis.

Statistical Analysis

The outcome variables were standardised, z = (x−μ)/σ where x = raw value of bone measure, μ = mean of bone measure and σ = standard deviation of bone measure.

The association between the SNPs and the standardised outcome variables (DXA: LS and TH BMDa, pQCT: radius vBMD and geometric parameters, QUS: calcaneal BMD, and bone turnover markers: PINP and CTX-I) was tested using linear regression under an additive genetic model using PLINK (1.05) [23]. The results were adjusted for study centre and also for study centre, age, height and weight. The results are presented as a percentage change (β) in a standard deviation (SD) with 95% confidence intervals for each copy of the minor allele. For significantly associated SNPs, the interaction between the SNP and centre was tested to see if the relationship between the SNP and the outcome differed across centres.

Pairs of SNPs associated with BMDa and located in different genes (RANKL, RANK, OPG, GPR177 and MAP3K14) at the same skeletal site with a p-value<0.01 were tested to determine if carrying the risk allele (allele associated with lower BMD) for both SNPs was associated with a greater effect on BMDa. For RANKL, RANK and OPG, data from previous analysis in the EMAS cohort was used [13]. In order to determine the combined effect of the two SNPs, a new combined genotype variable was defined based on the number of risk alleles each individual carried for either SNP. This new variable could have a value between 0 to 4; 0: having no copy of risk alleles for both SNPs, 1: having one copy of risk alleles for either SNPs, 2: having two copies of risk alleles for either SNPs, 3: having two copies of risk allele for one SNP and one copy of risk allele for the other one, and 4: having 2 copies of risk alleles for both SNPs. Subsequently, linear regression was used for testing the association between BMDa and this new variable adjusting for centre in STATA (9.2).

Results

Subject Characteristics

Of the 2658 men who consented to participate in the genetic analysis, 299 were excluded: 180 failed sample quality control, 21 reported at least one of their parents or grandparents was born outside Europe or North America, and 98 reported use of anti-osteoporotic medications or systemic glucocorticoids. In total, 2359 men, mean (±SD) age 60±11 years, were included in the analysis. Bone turnover markers and ultrasound BMD were measured in almost all men (N = 2244 and 2314, respectively). DXA and pQCT were performed in a subsample of men from 2 centres (N = 588 and 560, respectively). Mean values of the bone turnover markers, QUS, DXA and pQCT parameters are presented in Table 1.

10.1371/journal.pone.0028031.t001Table 1
Mean (SD) of bone turnover markers, DXA, pQCT and QUS parameters.
NMeanSD
Bone turnover markers
PINP (ng/ml)224442.9121.72
CTX-I (ng/ml)2242357.72181.37
DXA BMDa
Lumbar spine (g/cm2)5881.060.18
Total hip (g/cm2)5871.020.14
Femoral neck (g/cm2)5870.810.13
pQCT
4% radius
Total vBMD (mg/mm3)560400.6671.21
Trabecular vBMD (mg/mm3)560203.8242.72
Cross-sectional area (mm2)560374.6266.31
50% site
Cortical vBMD (mg/mm3)5601214.4729.68
Cortical thickness (mm)5603.240.42
Total area (mm2)560149.3120.72
Cortical area (mm2)560106.4413.63
Medullary area (mm2)56042.8715.71
SSI (mm3)560337.5663.87
QUS
BMD at calcaneus (g/cm2)23140.540.14

PINP: N-terminal propeptide of type I procollagen, CTX-I: C-terminal cross-linked telopeptide of type I collagen, DXA: dual energy X-ray absorptiometry, BMDa: areal bone mineral density, pQCT: peripheral quantitative computed tomography, vBMD: volumetric bone mineral density, SSI: stress strain index, QUS: quantitative ultrasound.

Genotyping

GPR177

Thirteen SNPs within GPR177 were selected for genotyping. Of these, 10 SNPs were successfully genotyped and passed quality control. Rs919540, rs994082 and rs2772304 failed genotyping.

MAP3K14

Forty-three SNPs with a MAF>0.05 were identified in MAP3K14 and its 10 kb flanking regions. These SNPs were tagged by 13 SNPs. Of these, 12 SNPs were successfully genotyped and passed quality control covering 98% of the selected SNPs with a MAF of more than 5% in the region. Rs2867316 failed genotyping.

Genetic Association Analysis

For the bone turnover markers and ultrasound BMD, with α = 0.05, there was greater than 80% power to detect differences of 0.2 SD for SNPs with a MAF = 0.05 and 0.1 SD for SNPs with a MAF = 0.45 under an additive genetic model. For DXA and pQCT outcomes, with α = 0.05, there was greater than 80% power to detect differences of 0.4 SD for SNPs with a MAF = 0.05 and 0.2 SD for SNPs with a MAF = 0.45 under an additive genetic model. Statistical power was calculated using Quanto v1.2.3 software [24].

GPR177

Of the 10 SNPs successfully genotyped, 6 were associated with total hip BMDa. Rs1430742, which was the most significantly associated SNP in this locus in a GWAS meta-analysis of LS and FN BMDa[10], showed the largest effect with each allele resulting in a 0.18 SD (95%CI 0.04, 0.33) p = 0.015 increase in total hip BMDa. Of these 6 SNPs, 2 (rs2772300 and rs7554551) also showed a significant association with LS BMDa and 2 showed a non-significant effect in the same direction as total hip BMDa but of a lesser magnitude (Table 2). Three of the SNPs, associated with total hip BMDa, also showed a significant association with total vBMD at the distal radius, with rs1430742 again showing the largest effect (0.15 SD (95%CI 0.02, 0.28) p = 0.024 per allele). rs2772300, which is in moderate LD with rs1430742 (r2 = 0.67) (Figure 1) was also significantly associated with increased cortical vBMD at the mid-shaft radius (0.18 SD (0.05, 0.32) p = 0.007 per allele). Other SNPs showed a change in cortical vBMD but did not attain statistical significance. Rs891257 was also significantly associated with increased cortical vBMD, but was not associated with LS or TH BMDa or total vBMD (Table 3). There was no association between any of the SNPs and trabecular vBMD. The results were broadly similar when applying further adjustment for age, height and weight (Tables 2 and 3).

10.1371/journal.pone.0028031.g001Figure 1

The pair-wise LD between GPR177 SNPs associated with bone health parameters.

(black r2 = 1, white r2 = 0).

10.1371/journal.pone.0028031.t002Table 2

Genetic association between GPR177 SNPs and BMDa.

Total Hip BMDaLS BMDa
SNPAllelesMAFβ(SD) (95% CI)apaβ(SD) (95% CI)apbβ(SD) (95% CI)apaβ(SD) (95% CI)apb
rs2566784G>T0.250.13 (−0.01, 0.26)0.0630.18 (0.06, 0.29)0.0030.11 (−0.01, 0.24)0.0770.14 (0.03, 0.26)0.018
rs3762371G>A0.4−0.07 (−0.19, 0.05)0.261−0.03 (−0.14, 0.07)0.565−0.02 (−0.14, 0.09)0.676−0.02 (−0.12, 0.09)0.74
rs2566759A>G0.5−0.12 (−0.24, 0.00)0.049−0.09 (−0.20, 0.01)0.088−0.04 (−0.15, 0.07)0.495−0.04 (−0.15, 0.06)0.439
rs2566758T>C0.46−0.13 (−0.24, −0.01)0.039−0.10 (−0.21, 0.00)0.053−0.06 (−0.17, 0.06)0.316−0.07 (−0.18, 0.03)0.187
rs1367447C>T0.190.15 (−0.01, 0.30)0.0620.09 (−0.05, 0.23)0.2080.07 (−0.08, 0.22)0.3770.04 (−0.10, 0.18)0.567
rs1430742T>C0.230.18 (0.04, 0.33)0.0150.17 (0.04, 0.30)0.0110.13 (−0.01, 0.27)0.0770.14 (0.01, 0.27)0.036
rs2195682C>T0.39−0.16 (−0.28, −0.04)0.007−0.14 (−0.24, −0.03)0.011−0.11 (−0.22, 0.01)0.063−0.11 (−0.21, 0.00)0.052
rs891527A>T0.420.05 (−0.07, 0.17)0.4110.06 (−0.04, 0.17)0.2420.02 (−0.10, 0.13)0.7510.04 (−0.07, 0.15)0.446
rs2772300G>A0.280.15 (0.02, 0.29)0.0260.18 (0.06, 0.30)0.0030.16 (0.03, 0.29)0.0130.20 (0.08, 0.32)0.001
rs7554551T>C0.330.17 (0.05, 0.30)0.0050.19 (0.08, 0.29)0.0010.14 (0.03, 0.26)0.0160.17 (0.06, 0.28)0.003

aadjusted for study centre;

badjusted for study centre, age, height and weight.

10.1371/journal.pone.0028031.t003Table 3

Genetic association between GPR177 SNPs and BMDv.

Total vBMD (4%)Cortical vBMD (50%)
SNPAllelesMAFβ(SD) (95% CI)apaβ(SD) (95% CI)apbβ(SD) (95% CI)apaβ(SD) (95% CI)apb
rs2566784G>T0.250.08 (−0.04, 0.19)0.1780.09 (−0.02, 0.20)0.0990.04 (−0.09, 0.18)0.520.06 (−0.07, 0.19)0.365
rs3762371G>A0.40−0.02 (−0.13, 0.08)0.6390.01 (−0.09, 0.11)0.887−0.03 (−0.15, 0.09)0.641−0.01 (−0.12, 0.11)0.904
rs2566759A>G0.50−0.05 (−0.16, 0.05)0.308−0.02 (−0.12, 0.08)0.664−0.08 (−0.20, 0.04)0.17−0.06 (−0.17, 0.06)0.331
rs2566758T>C0.46−0.10 (−0.21, 0.00)0.053−0.06 (−0.16, 0.04)0.222−0.09 (−0.21, 0.03)0.133−0.06 (−0.18, 0.05)0.291
rs1367447C>T0.190.12 (−0.02, 0.25)0.0930.09 (−0.04, 0.22)0.1960.11 (−0.05, 0.27)0.1700.07 (−0.08, 0.23)0.362
rs1430742T>C0.230.15 (0.02, 0.28)0.0240.12 (0.00, 0.25)0.0570.11 (−0.04, 0.26)0.1580.06 (−0.09, 0.21)0.427
rs2195682C>T0.39−0.10 (−0.21, 0.00)0.053−0.07 (−0.17, 0.03)0.164−0.10 (−0.22, 0.02)0.094−0.10 (−0.21, 0.02)0.108
rs891527A>T0.420.04 (−0.07, 0.14)0.5040.02 (−0.08, 0.12)0.720.16 (0.04, 0.28)0.0110.14 (0.02, 0.25)0.023
rs2772300G>A0.280.13 (0.01, 0.23)0.0360.10 (−0.01, 0.22)0.0740.18 (0.05, 0.32)0.0070.15 (0.01, 0.28)0.031
rs7554551T>C0.330.12 (0.01, 0.23)0.0280.10 (0.00, 0.21)0.0470.03 (−0.09, 0.15)0.6410.01 (−0.11, 0.13)0.914

aadjusted for study centre;

badjusted for study centre, age, height and weight.

SNPs in GPR177 which were associated with BMD also showed evidence of association with geometric parameters of bone (Table 4). Two SNPs (rs2566759 and rs2195682 were associated with cross-sectional area at the distal radius. Rs277230 and rs1430742 were associated with increased cortical area at the mid-shaft radius and rs2772300 was also associated with increased cortical thickness and SSI. Rs7554551 was associated with cortical thickness at the midshaft radius. There was no association between SNPs in GPR177 and bone turnover markers or ultrasound eBMD.

10.1371/journal.pone.0028031.t004Table 4

GPR177 SNP associations with radius geometric parameters.

SNPAllelesMAFPhenotypeSkeletal Siteβ(SD) (95% CI)apaβ(SD) (95% CI)bpb
rs2566759A>G0.5Cross-sectional area4% radius0.11 (0.01, 0.21)0.0370.10 (0.00, 0.20)0.045
rs2566758T>C0.46Cross-sectional area4% radius0.11 (0.01, 0.22)0.0300.09 (0.00, 0.19)0.060
rs1430742T>C0.23Cortical area50% radius0.17 (0.02, 0.32)0.0310.14 (0.00, 0.27)0.053
rs2772300G>A0.28Cortical area50% radius0.17 (0.03, 0.30)0.0150.18 (0.05, 0.30)0.005
Cortical Thickness50% radius0.17 (0.04, 0.31)0.0120.17 (0.04, 0.30)0.011
SSI50% radius0.15 (0.01, 0.28)0.0300.16 (0.03, 0.28)0.013
rs7554551T>C0.33Cortical Thickness50% radius0.15 (0.03, 0.27)0.0180.15 (0.03, 0.27)0.015

SSI: stress strain index;

aadjusted for study centre;

badjusted for study centre, age, height and weight.

MAP3K14

Two SNPs showed evidence of association with BMD. Rs8065345 was significantly associated with a 0.25 SD (95%CI 0.10, 0.41) p = 0.002 per allele increase in LS BMDa and was also associated with increased cortical area and cortical thickness. Rs7215764 was significantly associated with increased total hip BMDa and cortical vBMD at the mid-shaft radius. Three further SNPs were associated with geometric parameters, rs11651968 was associated with decreased cortical area at the mid-shaft radius and rs1785379 was associated with decreased medullary area and increased cortical thickness at the mid-shaft radius. Rs16939948 was associated with total area at the mid-shaft radius; however, this association became non-significant after further adjustment for age, height and weight (Table 5). Further adjusting the associations between MAP3K14 SNPs and bone health parameters for age, height and weight gave broadly similar results with effect estimates of similar magnitude. LD between the associated SNPs was weak, r2≤0.13. The results for all MAP3K14 SNPs with LS and total hip BMDa and total and cortical vBMD are given in Tables S1 & S2 respectively.

10.1371/journal.pone.0028031.t005Table 5

MAP3K14 SNP associations with bone mineral density and radius geometric parameters.

SNPAllelesMAFLocationPhenotypeSkeletal Siteβ(SD) (95% CI)apaβ(SD) (95% CI)bpb
rs8065345A>G0.153′ downstreamBMDaLumbar spine0.25 (0.10, 0.41)0.0020.21 (0.06, 0.35)0.006
Cortical area50% radius0.21 (0.05, 0.38)0.0110.16 (0.01, 0.31)0.041
Cortical thickness50% radius0.24 (0.07, 0.40)0.0040.22 (0.06, 0.38)0.006
rs11651968C>T0.483′ downstreamCortical area50% radius−0.13 (−0.25, −0.01)0.031−0.11, −0.22, 0.01)0.062
rs7215764C>G0.253′ downstreamBMDaTotal hip0.17 (0.03, 0.31)0.0210.10 (−0.03, 0.22)0.136
Cortical vBMD50% radius0.17 (0.03, 0.32)0.0200.17 (0.03, 0.31)0.016
rs17685379C>G0.14IntronicMedullary area50% radius−0.17 (−0.35, 0.00)0.048−0.19 (−0.36, −0.02)0.031
Cortical thickness50% radius0.18 (0.01, 0.35)0.0430.22 (0.05, 0.38)0.011
rs16939948T>C0.05IntronicTotal area50% radius0.29 (0.01, 0.57)0.0440.23 (−0.03, 0.50)0.089

BMDa: areal bone mineral density, vBMD: volumetric bone mineral density;

aadjusted for study centre;

badjusted for study centre, age, height and weight.

In contrast to GPR177, there were three MAP3K14 SNPs associated with CTX-I serum levels; rs4792847 (0.07 SD (95%CI 0.01, 0.12) p = 0.013), rs4792849 (0.06 SD (95%CI 0.00, 0.12) p = 0.042) and rs4328483 (0.08 SD (95%CI 0.03, 0.14) p = 0.003). None of the SNPs were associated with PINP serum levels. There was a moderate LD between these three SNPs (0.69<r2>0.39). There was no association between SNPs in MAP3K14 SNPs and ultrasound BMD.

The combined effect of BMD associated SNPs in different pathway genes

A single pair of SNPs, rs9594738 in RANKL and rs8065345 in MAP3K14, which were both associated with LS BMDa (p = 0.001) met the inclusion criteria for examining their combined effect. Five hundred seventy-eight subjects were included in the analysis: 5, 47, 188, 250 and 88 subjects had 0 to 4 copies of the risk alleles for either rs9594738 in RANKL or rs8065345 in MAP3K14, respectively. LS BMDa was reduced by 0.04 g/cm2 (95% CI −0.06, −0.02) per risk alleles carried (p = 4.6×10−6) (Figure 2).

10.1371/journal.pone.0028031.g002Figure 2

The decline in lumbar spine areal BMD by increasing number of carried risk alleles of rs9594738 (RANKL) and rs8065345 (MAP3K14).

Discussion

In this study, we investigated the association between SNPs within two genes involved in the NF-κB cascade (GPR177 and MAP3K14) and bone mineral density assessed at different skeletal sites, radial geometric parameters and bone turnover. Additionally, for the first time, we investigated the potential combined effect of two associated SNPs in MAP3K14 and RANKL (previously reported) on LS BMDa.

First, we attempted to validate the association between ten SNPs in GPR177 and BMDa reported in a GWAS meta-analysis [10], six of which showed significant association with total hip BMDa in the same direction in EMAS. Two of these SNPs were also significantly associated with LS BMDa and another 2 showed suggestive association (p<0.1) with LS BMDa. This weaker evidence of association with LS BMDa may have arisen due to the presence of concomitant disease such as osteoarthritis which can artificially raise BMD of the spine in an elderly cohort, making it harder to detect an association, particularly in a cohort of modest sample size. The results confirm the GWAS meta-analysis findings and show that SNPs in GPR177 influence BMDa at osteoporotic sites in a population of middle aged and elderly men at that their effects can be detected in a relatively modest sample size.

In addition, SNPs in GPR177 were also associated with total and cortical BMD at the radius, which is a novel finding, however despite testing in a larger sample size, there was no evidence of association with calcaneal eBMD as measured by ultrasound, a pattern which has been observed for other BMD susceptibility genes [13]. The findings reported here also suggest that these SNPs may have pleiotrophic effects on bone as SNPs associating with cortical vBMD were also associated with geometric parameters at the radius. Rs2772300, which was associated with increased BMDa at the hip and LS and total and cortical vBMD at the radius, was also associated with increased cortical area, thickness and stress strain index. It seems unlikely that these effects are mediated by bone turnover as no association was observed between these SNPs and the bone turnover markers CTX-I and PINP, in a larger sample size. Variation in the level of markers may be one explanation for this. We attempted to reduce variability in the bone turnover markers by taking fasting blood samples and measuring them in a single laboratory (to reduce technical variability). Further, the bone turnover markers selected here (PINP and CTX-I) both had low intra-assay and inter-assay CVs minimizing their analytical variability. Turnover marker levels, however, reflect current skeletal turnover and may not necessarily reflect previous levels, such misclassification may in part explain the absence of any observed significant associations.

We also looked at the association of common SNPs (MAF≥0.05) in MAP3K14 with bone health parameters as this gene was previously highlighted as a good candidate, however there is no LD between the SNPs tested here in the MAP3K14 gene and the 17q12 SNP associated with BMDa[10]. There was evidence of association between MAP3K14 SNPs and BMDa, vBMD and radius geometric parameters, however unlike GPR177, there were no SNPs showing association with vBMD and geometric parameters, therefore the findings should be interpreted with caution. This is the first time that genetic variation in the MAP3K14 gene has been investigated with bone health parameters and in a modest sample size, therefore replication of these findings is required in larger cohorts.

Notably, we also found that individuals carrying risk alleles for SNPs in the MAP3K14 and RANKL genes had a significantly lower LS BMDa suggesting that, despite the modest effects of single SNPs, in individuals carrying multiple risk alleles for SNPs in the RANKL/RANK/OPG and Nf-κb signalling pathways they could have a profound effect on bone health. This finding also requires replication in independent cohorts.

Important potential limitations of this study are that false positive associations might have been produced due to population stratification and multiple testing. We tried to minimize the probability of population stratification by excluding subjects of non-European ancestry and did not observe any between centre heterogeneity. However, we were unable to explore population substructure using methods such as genomic control or principal component analysis as these require data on a large number of SNPs. Based on the method described by Li and Ji [25], 19 independent SNPs (GPR177: 8 and MAP3K14: 11 SNPs) were investigated in this study. The majority of the positive findings would not remain significant if Bonferroni correction (p<0.0026, 0.05/19) was applied to correct for multiple testing. On the other hand, we may have missed some genuine associations due to low statistical power. Lack of replication for association of some SNPs with BMDa may also be due to the relatively small number of subjects in our DXA subsample compared with the GWAS meta-analysis. In addition, EMAS is a male population whereas the GWAS meta-analysis data was based on studies of both men and women.

Assessment of cortical vBMD using pQCT is subject to the partial volume effect; the thinner the cortices the lower vBMD. In our analysis, we used a higher threshold (960 mg/cm3) for analysis of cortical vBMD rather than the traditional 710 mg/cm3 threshold [26] to reduce the likelihood of this effect. In addition, most of the SNPs associated with cortical vBMD were also associated with areal and/or volumetric BMD at other skeletal sites but they were not associated with cortical thickness suggesting that they are real findings rather than false positive results arising due to technical artefact.

In summary, our findings suggest that SNPs within GPR177 and MAP3K14 involved in the NF-κB pathway influence BMD at both axial (LS and Hip) and peripheral sites (radius) and they also influence radius geometry. We also found some evidence of association between SNPs within MAP3K14 and bone turnover. However, these findings require replication in independent populations. If confirmed, fine mapping and functional studies will be needed to identify the causal variants. In addition, combinations of SNPs from different genes in the NF-κB and RANKL/RANK/OPG pathways may have substantial effects on individuals carrying risk alleles of both SNPs highlighting the importance of these pathways in the genetic basis of bone health.

Supporting Information

Table S1

Genetic association between MAP3K14 SNPs and BMDa.

(DOC)

pone.0028031.s001.docClick here for additional data file.
Table S2

Genetic association between MAP3K14 SNPs and BMDv.

(DOC)

pone.0028031.s002.docClick here for additional data file.

Footnotes

Competing Interests: The authors have declared that no competing interests exist.

Funding: The European Male Ageing Study (EMAS) is funded by the Commission of the European Communities Fifth Framework Programme “Quality of Life and Management of Living Resources” Grant QLK6-CT-2001-00258 and supported by funding from the Arthritis Research UK. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Acknowledgments

The EMAS principal investigator is Professor Frederick Wu, MD, Dept of Endocrinology, Manchester Royal Infirmary, UK. The authors wish to thank the men who participated in the eight countries, the research/nursing staff in the eight centres: C Pott, Manchester, E Wouters, Leuven, M Nilsson, Malmö, M del Mar Fernandez, Santiago de Compostela, M Jedrzejowska, Lodz, H-M Tabo, Tartu, A Heredi, Szeged for their data collection and C Moseley, Manchester for data entry and project coordination. Dr. Vanderschueren is a senior clinical investigator supported by the Clinical Research Fund of the University Hospitals Leuven, Belgium. Dr. Boonen is a senior clinical investigator of the Fund for Scientific Research-Flanders, Belgium (F.W.O.-Vlaanderen). Dr. Boonen is holder of the Leuven University Chair in Metabolic Bone Diseases.

FCW Wu is the co-ordinator for the European Male Ageing Study (EMAS).

The EMAS Study Group: Florence (Gianni Forti, Luisa Petrone, Glovanni Corona); Leuven (Dirk Vanderschueren, Steven Boonen, Herman Borghs); Lodz (Krzysztof Kula, Jolanta Slowikowska-Hilczer, Renata Walczak-Jedrzejowska); London (Ilpo Huhtaniemi); Malmö (Aleksander Giwercman); Manchester (Frederick Wu, Alan Silman, Terence O'Neill, Joseph Finn, Philip Steer, Abdelouahid Tajar, David Lee, Stephen Pye); Santiago (Felipe F Casanueva, Mary Lage, Ana I Castro); Szeged (Gyorgy Bartfai, Imre Fö ldesi, Imre Fejes); Tartu (Margus Punab, Paul Korrovitz); Turku (Min Jiang).

References

  • 1. 1993Consensus development conference: diagnosis, prophylaxis, and treatment of osteoporosis.Am J Med94646650[PubMed][Google Scholar]
  • 2. van StaaTPDennisonEMLeufkensHGCooperC2001Epidemiology of fractures in England and Wales.Bone29517522[PubMed][Google Scholar]
  • 3. CummingsSRCawthonPMEnsrudKECauleyJAFinkHA2006BMD and risk of hip and nonvertebral fractures in older men: a prospective study and comparison with older women.J Bone Miner Res2115501556[PubMed][Google Scholar]
  • 4. StoneKLSeeleyDGLuiLYCauleyJAEnsrudK2003BMD at multiple sites and risk of fracture of multiple types: long-term results from the Study of Osteoporotic Fractures.J Bone Miner Res1819471954[PubMed][Google Scholar]
  • 5. Dargent-MolinaPSchottAMHansDFavierFGrandjeanH1999Separate and combined value of bone mass and gait speed measurements in screening for hip fracture risk: results from the EPIDOS study. Epidemiologie de l'Osteoporose.Osteoporos Int9188192[PubMed][Google Scholar]
  • 6. VidemanTLevalahtiEBattieMCSimonenRVanninenE2007Heritability of BMD of femoral neck and lumbar spine: a multivariate twin study of Finnish men.J Bone Miner Res2214551462[PubMed][Google Scholar]
  • 7. KrallEAwson-HughesB1993Heritable and life-style determinants of bone mineral density.J Bone Miner Res819[PubMed][Google Scholar]
  • 8. FlickerLHopperJLRodgersLKaymakciBGreenRM1995Bone density determinants in elderly women: a twin study.J Bone Miner Res1016071613[PubMed][Google Scholar]
  • 9. RichardsJBRivadeneiraFInouyeMPastinenTMSoranzoN2008Bone mineral density, osteoporosis, and osteoporotic fractures: a genome-wide association study.Lancet37115051512[PubMed][Google Scholar]
  • 10. RivadeneiraFStyrkarsdottirUEstradaKHalldorssonBVHsuYH2009Twenty bone-mineral-density loci identified by large-scale meta-analysis of genome-wide association studies.Nat Genet4111991206[PubMed][Google Scholar]
  • 11. StyrkarsdottirUHalldorssonBVGretarsdottirSGudbjartssonDFWaltersGB2008Multiple genetic loci for bone mineral density and fractures.N Engl J Med35823552365[PubMed][Google Scholar]
  • 12. StyrkarsdottirUHalldorssonBVGretarsdottirSGudbjartssonDFWaltersGB2009New sequence variants associated with bone mineral density.Nat Genet411517[PubMed][Google Scholar]
  • 13. RoshandelDHollidayKLPyeSRBoonenSBorghsH2010Genetic variation in the RANKL/RANK/OPG signaling pathway is associated with bone turnover and bone mineral density in men.J Bone Miner Res2518301838[PubMed][Google Scholar]
  • 14. HadjidakisDJAndroulakisII2006Bone remodeling.Ann N Y Acad Sci1092385396[PubMed][Google Scholar]
  • 15. SoysaNSAllesN2009NF-kappaB functions in osteoclasts.Biochem Biophys Res Commun37815[PubMed][Google Scholar]
  • 16. MatsudaASuzukiYHondaGMuramatsuSMatsuzakiO2003Large-scale identification and characterization of human genes that activate NF-kappaB and MAPK signaling pathways.Oncogene2233073318[PubMed][Google Scholar]
  • 17. BanzigerCSoldiniDSchuttCZipperlenPHausmannG2006Wntless, a conserved membrane protein dedicated to the secretion of Wnt proteins from signaling cells.Cell125509522[PubMed][Google Scholar]
  • 18. LeeDO'NeillTPyeSSilmanAFinnJ2009The European Male Ageing Study (EMAS): design, methods and recruitment.Int J Androl321124[PubMed][Google Scholar]
  • 19. LeeDMO'NeillTWPyeSRSilmanAJFinnJD2009The European Male Ageing Study (EMAS): design, methods and recruitment.Int J Androl321124[PubMed][Google Scholar]
  • 20. ReidDMMackayIWilkinsonSMillerCSchuetteDG2006Cross-calibration of dual-energy X-ray densitometers for a large, multi-center genetic study of osteoporosis.Osteoporos Int17125132[PubMed][Google Scholar]
  • 21. WardKARobertsSAAdamsJEMughalMZ2005Bone geometry and density in the skeleton of pre-pubertal gymnasts and school children.Bone3610121018[PubMed][Google Scholar]
  • 22. BarrettJCFryBMallerJDalyMJ2005Haploview: analysis and visualization of LD and haplotype maps.Bioinformatics21263265[PubMed][Google Scholar]
  • 23. PurcellSNealeBTodd-BrownKThomasLFerreiraMA2007PLINK: a tool set for whole-genome association and population-based linkage analyses.Am J Hum Genet81559575[PubMed][Google Scholar]
  • 24. KraftPYenYCStramDOMorrisonJGaudermanWJ2007Exploiting gene-environment interaction to detect genetic associations.Hum Hered63111119[PubMed][Google Scholar]
  • 25. LiJJiL2005Adjusting multiple testing in multilocus analyses using the eigenvalues of a correlation matrix.Heredity95221227[PubMed][Google Scholar]
  • 26. WardKAAdamsJEHangartnerTN2005Recommendations for thresholds for cortical bone geometry and density measurement by peripheral quantitative computed tomography.Calcif Tissue Int77275280[PubMed][Google Scholar]
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