This Article  • Abstract  • PDF  • Reply to article  • Send to a friend  • Save in My Folder  • Save to citation manager  • Permissions  Citing Articles  • Citation map  • Citing articles on HighWire  • Citing articles on ISI (16)  • Contact me when this article is cited  Related Content  • Similar articles in this journal  Topic Collections  • Alzheimer Disease  • Neurogenetics  • Alert me on articles by topic  Social Bookmarking   What's this?

Hao Li, PhD; Sally Wetten, MSc; Li Li, PhD; Pamela L. St. Jean, PhD; Ruchi Upmanyu, MSc; Linda Surh, MD, PhD; David Hosford, MD, PhD; Michael R. Barnes, PhD; James David Briley, BSc; Michael Borrie, MB, ChB, FRCPC; Natalie Coletta, MBiotech; Richard Delisle, MD; Daniella Dhalla, MBiotech; Margaret G. Ehm, PhD; Howard H. Feldman, MD; Luis Fornazzari, MD; Serge Gauthier, MD; Neil Goodgame, BSc; Danilo Guzman, MD; Sandra Hammond, HNC; Paul Hollingworth, PhD; Ging-Yuek Hsiung, MD; Joan Johnson, BSc, MEA; Devon D. Kelly, MSc; Ron Keren, MD; Andrew Kertesz, MD; Karen S. King, BSc; Simon Lovestone, PhD, MRCPsych; Inge Loy-English, MD; Paul M. Matthews, MD, PhD; Michael J. Owen, PhD, FRCPsych, FMedSci; Mary Plumpton, PhD; William Pryse-Phillips, MD, FRCP; Rab K. Prinjha, PhD; Jill C. Richardson, PhD; Ann Saunders, PhD; Andrew J. Slater, BSc; Peter H. St. George-Hyslop, MD, FRCPC; Sandra W. Stinnett, MSc; Jina E. Swartz, MD, PhD; Rachel L. Taylor, BSc; John Wherrett, MD; Julie Williams, PhD; David P. Yarnall, PhD; Rachel A. Gibson, PhD; Michael C. Irizarry, MD, MPH; Lefkos T. Middleton, MD; Allen D. Roses, MD

Arch Neurol. 2008;65(1):45-53. Published online November 12, 2007 (doi:10.1001/archneurol.2007.3).

ABSTRACT
Objective  To identify single-nucleotide polymorphisms (SNPs) associated with risk and age at onset of Alzheimer disease (AD) in a genomewide association study of 469 438 SNPs.

Design  Case-control study with replication.

Setting  Memory referral clinics in Canada and the United Kingdom.

Participants  The hypothesis-generating data set consisted of 753 individuals with AD by National Institute of Neurological and Communicative Diseases and Stroke/Alzheimer's Disease and Related Disorders Association criteria recruited from 9 memory referral clinics in Canada and 736 ethnically matched control subjects; control subjects were recruited from nonbiological relatives, friends, or spouses of the patients and did not exhibit cognitive impairment by history or cognitive testing. The follow-up data set consisted of 418 AD cases and 249 nondemented control cases from the United Kingdom Medical Research Council Genetic Resource for Late-Onset AD recruited from clinics at Cardiff University, Cardiff, Wales, and King's College London, London, England.

Main Outcome Measures  Odds ratios and 95% confidence intervals for association of SNPs with AD by logistic regression adjusted for age, sex, education, study site, and French Canadian ancestry (for the Canadian data set). Hazard ratios and 95% confidence intervals from Cox proportional hazards regression for age at onset with similar covariate adjustments.

Results  Unadjusted, SNP RS4420638 within APOC1 was strongly associated with AD due entirely to linkage disequilibrium with APOE. In the multivariable adjusted analyses, 3 SNPs within the top 120 by P value in the logistic analysis and 1 in the Cox analysis of the Canadian data set provided additional evidence for association at P < .05 within the United Kingdom Medical Research Council data set: RS7019241 (GOLPH2), RS10868366 (GOLPH2), RS9886784 (chromosome 9), and RS10519262 (intergenic between ATP8B4 and SLC27A2).

Conclusions  Our genomewide association analysis again identified the APOE linkage disequilibrium region as the strongest genetic risk factor for AD. This could be a consequence of the coevolution of more than 1 susceptibility allele, such as APOC1, in this region. We also provide new evidence for additional candidate genetic risk factors for AD that can be tested in further studies.

INTRODUCTION

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

Alzheimer disease (AD), the most prevalent form of dementia, is a neurodegenerative disorder that affects more than 5% of individuals aged 65 years and older.¹ The discovery of the association between the apolipoprotein E (APOE [Entrez GeneID NM_000041) 4 allele and AD confirmed the prominent role of specific genetic polymorphisms as risk factors for late-onset AD.^2-3 Besides APOE, a meta-analysis of AD genetic association studies as of February 1, 2007, reported 29 potential AD susceptibility genes (http://www.alzgene.org).⁴ Additional independent data are needed to further test these associations and to provide evidence for genes and gene interactions (especially with APOE) that contribute to the development and progression of AD.

We performed a genomewide association analysis in a case-control study of 753 patients with AD and 736 nondemented control individuals with 3 main aims. The first was to obtain a ranking of single-nucleotide polymorphisms (SNPs) based on strength of statistical association with AD diagnosis or age at onset for novel target-specific drug development and validation and to prioritize SNPs for pharmacogenetics studies.⁵ Second, we used this as a hypothesis-generating data set; 120 SNPs with the numerically lowest multivariable P values for genetic association with AD were evaluated in a second data set to assess generalizability and to reduce false-positive associations.⁶ Finally, we hereby release on the GlaxoSmithKline Clinical Trials Registry (http://www.GSK.com) the P values and allele and genotype frequencies from all of the SNPs to serve as a publicly available resource for further studies.

METHODS

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

SUBJECTS

The study protocol was reviewed and approved by the appropriate ethics committee or investigational review board for each study site before patients were recruited. Informed consent was obtained from study participants in accordance with all applicable investigational review board, ethics committee, and regulatory requirements.

The primary Canadian data set was drawn from 875 patients with AD and 850 nondemented control subjects recruited from 9 memory referral clinics in Canada between June 4, 2002, and March 30, 2005. Seven hundred fifty-three AD cases and 736 control cases satisfied subject quality control (Figure 1) and constitute the Canadian data set (Table 1). The study was limited to white persons of northern European ancestry. Patients with AD satisfied NINCDS-ADRDA (National Institute of Neurological and Communicative Diseases and Stroke/Alzheimer's Disease and Related Disorders Association)⁷ and Diagnostic and Statistical Manual of Mental Disorders (Fourth Edition)⁸ criteria for probable AD, with a Global Deterioration Scale score of 3 to 7 (ranging from mild to very severe cognitive decline).⁹ Ethnically matched control subjects were recruited from nonbiological relatives, friends, or spouses of the cases. Control subjects had no history of symptoms of memory impairment. They had a Mini-Mental State Examination score higher than the appropriate cutoff for dementia taking into account age and education level,¹⁰ a Mattis Dementia Rating Scale score of 136 or higher,¹¹ a Clock Test score (11:10) without error,¹² and no impairment on the 7 instrumental activities of daily living questions from the Duke Older American Resources and Services Procedures caused by cognitive decline.¹³

View larger version (108K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Subject quality control. AD indicates Alzheimer disease; UK, United Kingdom; MRC, Medical Research Council; and SNP, single-nucleotide polymorphism.

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 1. Demographics

The 120 SNPs with the numerically lowest multivariable P values for statistical association with case-control status and with age at onset were examined in a second data set drawn from 453 AD cases and 472 nondemented control cases recruited from July 1, 2001, to June 10, 2004, at Cardiff University, Cardiff, Wales, and King's College London, London, England, sites of the United Kingdom (UK) Medical Research Council (MRC) Genetic Resource for Late-Onset AD. Four hundred eighteen AD cases and 249 control cases satisfied subject quality control (Figure 1) and constitute the UK MRC data set (Table 1). All of the individuals were of Caucasian origin. Patients with AD had a minimum age at onset of 60 years and a diagnosis of probable AD (by NINCDS-ADRDA criteria), whereas control subjects were ascertained at the age of 65 years or older and had no evidence of dementia (by a Mini-Mental State Examination score  28, Clinical Dementia Rating score of 0,¹⁴ and full neurological examination).

GENOTYPING METHODS

Genotypes from the 500 566 SNPs in the GeneChip Human Mapping 500K Array Set (Sty and Nsp chips) (Affymetrix, Santa Clara, California) were obtained according to the Affymetrix published protocol using the Bayesian robust linear model with Mahalanobis distance algorithm (Affymetrix Power Tools version 1.4.0).¹⁵ In the Canadian data set, a total of 469 438 SNPs (459 975 autosomal and 9463 X-linked) passed the prespecified genotype quality control process, which excluded SNPs that were monomorphic (23 379 SNPs), had low genotype efficiency (148 SNPs with genotypes in < 70% of individuals), deviated from Hardy-Weinberg equilibrium at P < 10^–7 (4824 SNPs), or had mapping issues (3863 SNPs). All of the SNP mapping was carried out prior to March 15, 2007.

An additional genotype quality control step for SNPs significant in both data sets involved visual assessment of genotype clusters from the 2-dimensional plots of the mean adjusted intensity for each allele probe. Plots without distinct separation of genotypes suggest a low-quality marker and possible genotypic misclassification.

STATISTICAL ANALYSIS

Fisher Exact Test for Genotypic Test of Association

The Fisher exact test was used to assess genotypic associations between AD and each of the SNPs without covariate adjustment (SAS statistical software version 8.2; SAS Institute, Inc, Cary, North Carolina). The test was applied to the 2 x 3 table of case-control status by SNP genotype.

Logistic Regression for Genotypic Test of Association

In the Canadian data set, logistic regression was used to examine the effect of each SNP on the logarithmic odds of AD status adjusted for sex, education (ordinal categories of < 5, 5-10, 11-15, and > 15 years), age, number of APOE 4 alleles, study site, and ancestry (French Canadian vs not) (SAS statistical software version 8.2). The SNPs with minor allele homozygote counts of 14 or more were tested as dominant, additive, and recessive coding in separate logistic regression models; the optimal genetic model for each SNP was selected by Schwarz-Bayesian information criterion (BIC)¹⁶ with the respective minimum Wald test P value. The minimum Wald P value for each SNP was multiplied by 3 as a Bonferroni adjustment for the 3 genetic models tested, yielding the adjusted minimum P value.¹⁷ For SNPs with minor allele homozygote counts less than 14 and the counts of minor allele homozygotes and heterozygotes that were more than 14, only the dominant genetic model could be tested with adequate cell counts with no further adjustment of the P value. The significance of an SNP x APOE interaction was also tested for each SNP in the optimal genetic model.

For nonautosomal SNPs, the analysis was performed stratified by sex. In women, dominant, additive, and recessive models were tested for SNPs with appropriate genotype frequencies. In men, only the dominant model (equal to the allelic model) was evaluated.

The top 120 SNPs by adjusted minimum P values were examined in the UK MRC data set under the same genetic model that was optimal for that SNP in the Canadian data set. For a dominant risk model, the UK MRC data set had an optimal power of approximately 80% to detect a genotypic odds ratio of 1.6 at P < .05 for a risk SNP with a minor allele frequency of 0.25 assuming disease prevalence of 5%.¹⁸ Given the smaller sample size from the UK MRC collection, we report those SNPs among the Canadian top 120 that were nominally significant at P < .05 in the UK MRC data set.

Cox Proportional Hazards for Age at Onset

In the Canadian data set, Cox proportional hazards regression assessed the effect of each SNP genotype on age at onset of AD (SAS statistical software version 8.2). Controls were censored at the age individuals entered the study. Covariates were sex, ethnicity, number of APOE 4 alleles, and study site. Education did not satisfy the proportional hazards assumption (by interaction terms with age); therefore, the analysis was stratified for education (collapsed into 3 categories:  10, 11-15, and > 15 years). Genetic models were compared by BIC, and adjusted minimum P values were reported as for the logistic regression model. The top 120 SNPs by adjusted minimum P values were examined in the UK MRC data set under the same genetic model that was optimal for that SNP in the Canadian data set. The SNP x APOE interaction was not tested in the Cox model.

Covariate-Adjusted Gene-Based Permutation Test

To determine the statistical evidence for association of selected genes in the literature reported to be associated with AD and to exploit linkage disequilibrium (LD), we performed a gene-based permutation test incorporating covariate strata for SNPs within these genes. The permutation test determined the significance of the BIC test statistic for the most significant SNP in a gene, adjusted for the number of SNPs analyzed, the number of tests conducted, and the correlation between SNPs within each gene. Gene-based SNPs were defined by those within the most 5' and 3' exons of the longest gene transcripts.

For each permutation, disease status was shuffled among the AD cases and control cases within covariate strata, maintaining the overall number of AD cases and number of control cases in the observed data. The genetic data and covariates for each subject were not altered. For each permutation, all of the SNPs within a gene were analyzed using the same analytical tests applied to the true observed data. The minimum BIC (among all of the tests for each gene) for the best-fit test was captured for each permutation. The permutations were repeated up to 2000 times such that up to 2000 minimum BICs were captured. Once the permutations were completed, the minimum observed BIC for the most significant SNP in the gene was compared against the permutation distribution of minimum BIC. The proportion of minimum BICs that were less than the minimum observed BICs yielded the empirical permutation P value for that gene.

RESULTS

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

POPULATION STRATIFICATION

The genomic control variance inflation factor between AD and control cases by allelic and genotypic Fisher exact tests of 2889 uncorrelated markers were between 1.00 and 1.06 within each data set.¹⁹ This suggests minimal confounding by population stratification.

COVARIATES

Within the Canadian data set, age (P < .001), sex (P = .005), education (P < .001), and number of APOE 4 alleles (P < .001; odds ratio, 4.9 per additional 4 allele) were independently associated with case-control status by logistic regression; site (P < .001) and APOE 4 (P < .001; hazard ratio, 2.6) were independently associated with age at onset by Cox proportional hazards regression. French Canadian ethnicity was not significantly associated with age at onset or diagnosis. In the UK MRC data set, age (P < .001), education (P < .001), and APOE 4 (P < .001; odds ratio, 4.6) were independently associated with case-control status, and APOE 4 (P < .001; hazard ratio, 2.0) was associated with age at onset.

FISHER EXACT TEST

One SNP was associated with AD by genotypic Fisher exact test after genomewide Bonferroni adjustment: RS4420638 with nominal P = 2.3 x 10^–44 within the APOC1 gene (NM_001645), which was in strong LD with APOE on chromosome 19. This SNP was no longer significant after adjustment for the number of APOE 4 alleles in the logistic and Cox regression analyses (adjusted minimum P > .32).

LOGISTIC REGRESSION

The 120 most significant SNPs by adjusted minimum P value in the Canadian data set were evaluated in the UK MRC data set. In the UK MRC data set, 3 of these SNPs had the following: (1) allele frequencies sufficient to allow multivariable analysis; (2) nominal significance at P < .05; (3) a risk genotype consistent with the Canadian data set; and (4) reliable genotyping by intensity plots: RS7019241 and RS10868366 (both within the same LD block in GOLPH2 [NM_016548] on chromosome 9), and RS9886784 (within a copy number deletion polymorphism on chromosome 9). Results and genomic contexts for these SNPs are in Table 2 and Figure 2A and B.

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 2. Single-Nucleotide Polymorphisms Among the Top 120 in the Canadian Data Set With Further Support in the United Kingdom Medical Research Council Data Set

View larger version (158K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. Linkage disequilibrium (LD) graphical displays for the Alzheimer disease–associated loci identified by logistic regression (A and B) and Cox proportional hazards regression (C), including RS7019241 and RS10868366 (A), RS9886784 (B), and RS10519262 (C). The x-axis indicates chromosomal position. Transcriptional units with gene names are marked by the lines with arrows above the x-axis. The –log10 adjusted minimum P value from the logistic regression (A and B) or Cox proportional hazards regression (C) is plotted for each single-nucleotide polymorphism (SNP). Symbols of the same shape and color denote SNPs that are in the same LD cluster (r2 > 0.7). Open black circles indicate SNPs not correlated with any other. If SNPs have different symbols, then correlation between them is small, or limited at most. Below the association plots is an LD matrix with increasing LD denoted by a darker color. White areas indicate little to no LD, whereas black areas indicate strong to complete LD. The most significant SNP in the Canadian collection is the largest symbol; *P value for the corresponding SNP in the United Kingdom Medical Research Council data set. bp indicates base pairs; kb, kilobases.

SNP x APOE INTERACTION

We examined whether the number of APOE 4 alleles significantly and reproducibly modified the association of SNPs with AD. No top 25 SNPs by SNP x APOE interaction P value had significant interaction P values in the UK MRC data set, although power for the interaction test was low.

COX PROPORTIONAL HAZARDS REGRESSION

The 120 most significant SNPs by adjusted minimum P value in the Canadian data set were evaluated in the UK MRC data set. One SNP was further supported in the UK MRC data set (according to the same conditions listed in the logistic regression results stated earlier): RS10519262 (intergenic on chromosome 15 between ATP8B4 [NM_024837] and SLC27A2 [NM_003645]). Results, genomic context, and Kaplan-Meier curves for RS10519262 in the Canadian and UK MRC data sets are shown in Table 2, Figure 2C, and Figure 3.

View larger version (24K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. Kaplan-Meier curves of Alzheimer disease (AD) onset by age and single-nucleotide polymorphism genotype for RS10519262 in the Canadian (A) and United Kingdom Medical Research Council (B) data sets. CI indicates confidence interval.

GENE-BASED PERMUTATION TEST

We examined SNPs within 26 genes with reported associations to AD by meta-analysis in the literature (Table 3).⁴ Six genes contained SNPs with an adjusted minimum P < .05 by logistic regression, of which only PRNP (NM_000311) (RS6017516, permutation P = .02) remained significant after the gene-based permutation test. Six genes contained SNPs with adjusted minimum P < .05 by Cox proportional hazards regression, of which only PSEN1 (NM_000021) (RS3025787, permutation P = .03) and SORCS1 (NM_001013031) (RS601883, permutation P = .02) remained significant after gene-based permutation (Table 3).

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 3. Single-Nucleotide Polymorphisms Within Candidate Genes Associated With Alzheimer Diseasea

COMMENT

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

The availability of microarray platforms for genotyping thousands of SNPs across the genome provides an unprecedented opportunity to understand the genetic contributions to complex diseases. At least 2 high-density genomewide association studies are published in AD.^20-22 The association of RS4420638 within APOC1 with AD was also identified by Coon et al.²⁰ The SNP is in strong LD with APOE, and its effects are eliminated by adjusting for the number of APOE 4 alleles in the logistic and Cox regression analyses.

While there has been a tacit assumption that the association of APOE with AD is entirely explained by APOE 4, other polymorphisms and regulatory elements within this LD block may influence AD pathogenesis, mitochondrial function, and drug response.²³ The apolipoprotein E4 protein, and in particular a proteolytic E4 (1-272) fragment, binds to mitochondria and disrupts mitochondrial intracellular transport and synaptogenesis.^23-25 Translocase of outer mitochondrial membrane 40 (TOMM40), also within the APOE LD region, forms mitochondrial import channels that accumulate amyloid precursor protein and result in mitochondrial dysfunction, potentially triggering the caspase apoptotic cascade.²⁶ We have previously reported that SNPs near the peroxisome proliferator-activated receptor regulatory region in APOE (RS439401) further array response to rosiglitazone maleate therapy in AD within APOE genotypes.^27-28 This is being examined in 3 large, ongoing, registration clinical trials scheduled to conclude in late 2008. The fact that TOMM40 (NM_006114) and the peroxisome proliferator-activated receptor response element are in LD with the APOE locus has led to an extensive long-range sequencing study to define evolutionary haplotypes within the APOE 2, 3, and 4 backbones. Thus, other genetic variations may be mapped in an evolutionary context for contributing to the worsening effect of APOE 4 or the beneficial effect of APOE 2 and including differential effects of APOE 3.

Four SNPs within the top 120 by P value from the multivariable adjusted analyses in the Canadian data set provided additional evidence for association within the UK MRC data set. RS7019241 and RS10868366 reside within introns of the GOLPH2 gene that encodes a type II Golgi transmembrane trafficking protein.²⁹ The GOLPH2 gene is within the chromosomal region 9.22 to 9.34 with suggestive linkage to AD in the literature.^30-31 Golgi phosphoprotein 2 is strongly expressed in the dentate gyrus and CA3 subfields of mouse hippocampus.³² The identified SNPs are in strong LD with SNPs within the GOLPH2 proximal promoter region and could potentially alter gene expression levels (Figure 2A).

RS10519262 is intergenic on chromosome 15 between ATP8B4 and SLC27A2. One polymorphism (RS7176805) in strong LD with this SNP extends into the ATP8B4 distal promoter region, potentially altering a CCAAT box transcription factor binding site (Figure 2C). ATP8B4 is an adenosine triphosphatase involved in phospholipid transport within the cell membrane, with low levels of expression in hippocampus, caudate, substantia nigra, and cerebellum.³³

Controlling type I error (false positives) while preserving sufficient power to detect true associations in genomewide association analyses is challenging. Genomewide Bonferroni correction tends to be overly conservative.^34-35 Instead, we used a 2-stage procedure to identify promising SNPs. Other analytic approaches may offer additional power (eg, joint analysis³⁶); however, large-scale replication is ultimately required to identify and confirm the modest effect sizes of genetic polymorphisms on common diseases.³⁵ Additional exploratory analyses (eg, based on haplotypes or pathway analyses) may generate further genetic hypotheses for testing.³⁷

Thus, apart from variations within the APOE LD regions, genetic associations with sporadic AD appear weak. One hypothesis is that AD is the common clinical and neuropathological response to a broad range of etiological genetic and environmental factors; many genes (potentially including those suggested by meta-analysis and supported by our data) and alleles (as reported for SORL1^38-39) would then be expected to differentially influence disease across diverse populations. It is also possible that the elusive other genetic effects may be located in the TOMM40-APOE-APOC1 LD region, perhaps with specific TOMM40 polymorphisms being important contributors to the overall genetic effect ascribed to APOE 4. The peroxisome proliferator-activated receptor response element within this LD region may further influence pathogenesis or response to drugs. To date, the magnitude of the association of this LD block with AD is uniquely consistent and reproducible and therefore should receive increased scientific scrutiny in light of the otherwise weak associations in the current generation of genomewide association studies.

AUTHOR INFORMATION

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

Correspondence: Rachel A. Gibson, PhD, GlaxoSmithKline, New Frontiers Science Park, Third Avenue, Harlow CM19 5AW, England (rachel.a.gibson{at}gsk.com).

Published Online: November 12, 2007 (doi:10.1001/archneurol.2007.3).

Accepted for Publication: September 4, 2007.

Author Contributions: Study concept and design: L. Li, St. Jean, Upmanyu, Surh, Hosford, Ehm, Feldman, Hammond, Keren, Loy-English, Richardson, Saunders, St. George-Hyslop, Swartz, Gibson, Irizarry, Middleton, and Roses. Acquisition of data: H. Li, L. Li, Briley, Borrie, Coletta, Delisle, Dhalla, Feldman, Fornazzari, Gauthier, Goodgame, Guzman, Hammond, Hollingworth, Hsiung, Johnson, Kelly, Keren, Kertesz, King, Lovestone, Loy-English, Matthews, Owen, Pryse-Phillips, Prinjha, Slater, St. George-Hyslop, Stinnett, Taylor, Wherrett, Williams, Yarnall, Gibson, Irizarry, and Middleton. Analysis and interpretation of data: H. Li, Wetten, L. Li, St. Jean, Upmanyu, Barnes, Feldman, Hollingworth, Hsiung, Matthews, Plumpton, Prinjha, Saunders, Gibson, and Irizarry. Drafting of the manuscript: H. Li, St. Jean, Upmanyu, Barnes, Matthews, Plumpton, Prinjha, Richardson, Gibson, and Irizarry. Critical revision of the manuscript for important intellectual content: Wetten, L. Li, St. Jean, Upmanyu, Surh, Hosford, Barnes, Briley, Borrie, Coletta, Delisle, Dhalla, Ehm, Feldman, Fornazzari, Gauthier, Goodgame, Guzman, Hammond, Hollingworth, Hsiung, Johnson, Kelly, Keren, Kertesz, King, Lovestone, Loy-English, Owen, Pryse-Phillips, Prinjha, Saunders, Slater, St. George-Hyslop, Stinnett, Swartz, Taylor, Wherrett, Williams, Yarnall, Gibson, Middleton, and Roses. Statistical analysis: H. Li, Wetten, L. Li, St. Jean, Upmanyu, Barnes, Ehm, Hollingworth, Saunders, and Irizarry. Obtained funding: Lovestone, Owen, Williams, and Roses. Administrative, technical, and material support: Hosford, Briley, Coletta, Dhalla, Feldman, Goodgame, Guzman, Hammond, Kelly, Kertesz, King, Loy-English, Matthews, Pryse-Phillips, Prinjha, Stinnett, Swartz, Taylor, Williams, Yarnall, and Gibson. Study supervision: Surh, Coletta, Dhalla, Ehm, Fornazzari, Hsiung, Kertesz, Lovestone, Matthews, Owen, Prinjha, Wherrett, Gibson, Irizarry, Middleton, and Roses.

Financial Disclosure: Drs H. Li, L. Li, St. Jean, Surh, Hosford, Barnes, Ehm, Matthews, Plumpton, Pryse-Phillips, Prinjha, Richardson, Saunders, Swartz, Yarnall, Gibson, Irizarry, Middleton, and Roses, Mss Wetten, Upmanyu, Coletta, Dhalla, Hammond, Johnson, King, Stinnett, and Taylor, and Messrs Briley, Goodgame, Kelly, and Slater are stock- and option-holding employees of GlaxoSmithKline. Dr Feldman is a paid consultant for GlaxoSmithKline. GlaxoSmithKline has drug and biomarker development programs in Alzheimer disease. Dr Gauthier was a consultant for GlaxoSmithKline at the time of the study.

Funding/Support: The study was funded by GlaxoSmithKline.

Role of the Sponsor: The sponsor was involved in the design and conduct of the study; collection, management, analysis, and interpretation of the data; and preparation, review, and approval of the manuscript.

Additional Contributions: Kevin Canning, PhD, Lukasz Mis, MBiotech, David Krakovsky, BScPhm, PharmD, and Kevin Fehr, PhD, GlaxoSmithKline, Inc, Mississauga, Ontario, Canada, Zaheer Anwar, BSc, Jamie Logan, BSc, Sarah Flaskett, BSc, Tina Stapleton, Adam Whittaker, BSc, and Ramya Viknaraja, MSc, GlaxoSmithKline, Harlow and Greenford, England, Zaven Khachaturian, PhD, Khachaturian, Radebaugh and Associates, Inc, Potomac, Maryland, Jill Ratchford, BS-MT, and Stephanie Shouse, BS, GlaxoSmithKline, Research Triangle Park, North Carolina, Xin Yuan, PhD, GlaxoSmithKline, King of Prussia, Pennsylvania, and Nawab Qizilbash, MBChB, MRCP, DPhil, GlaxoSmithKline, Harlow, and Oxon Clinical Epidemiology, Ltd, London, England, provided administrative, technical, and material support. Kevin Canning, PhD, Lukasz Mis, MBiotech, and David Krakovsky, BScPhm, PharmD, GlaxoSmithKline, Inc, Mississauga, and Jamie Logan, BSc, and Sarah Flaskett, BSc, GlaxoSmithKline, Harlow and Greenford, acquired data. Julie Davidson, MPH, Nicholas Galwey, PhD, Thomas E. Nichols, PhD, and David Wille, PhD, GlaxoSmithKline, Harlow and Greenford, and Matthew R. Nelson, PhD, and Silviu-Alin Bacanu, PhD, GlaxoSmithKline, Research Triangle Park, provided genetic analysis advice.

Author Affiliations: GlaxoSmithKline, Research Triangle Park, North Carolina (Drs H. Li, L. Li, St. Jean, Hosford, Ehm, Saunders, Yarnall, Irizarry, and Roses, Messrs Briley, Kelly, and Slater, and Mss Johnson, King, and Stinnett); GlaxoSmithKline, Harlow, England (Mss Wetten, Upmanyu, Hammond, and Taylor, Drs Surh, Barnes, Plumpton, Prinjha, Richardson, Swartz, Gibson, and Middleton, and Mr Goodgame); Division of Geriatric Medicine, Parkwood Hospital (Dr Borrie) and Department of Cognitive Neurology, St Joseph's Hospital (Dr Kertesz), London, Ontario, Canada; GlaxoSmithKline Inc, Mississauga, Ontario, Canada (Mss Coletta and Dhalla and Dr Pryse-Phillips); Clinique de Neurologie, Trois-Rivières, Quebec, Canada (Dr Delisle); Division of Neurology, University of British Columbia, Vancouver Hospital and Health Sciences Center, Vancouver, British Columbia, Canada (Drs Feldman and Hsiung); Memory Clinic (Dr Fornazzari) and University Health Network (Drs Keren, St. George-Hyslop, and Wherrett), University of Toronto, Toronto, Ontario, Canada; McGill Centre for Studies in Aging, Verdun, Quebec, Canada (Dr Gauthier); Clinical Trials Unit, SCO Health Service, University of Ottawa, Ottawa, Ontario, Canada (Drs Guzman and Loy-English); Medical Research Council Neuropsychiatric Genetics Group, School of Medicine, Cardiff University, Cardiff, Wales (Drs Hollingworth, Owen, and Williams); and Medical Research Council Centre for Neurodegeneration Research, King's College London, Institute of Psychiatry (Dr Lovestone) and GlaxoSmithKline Research and Development, Clinical Imaging Centre, and Department of Clinical Neurosciences, Imperial College, Hammersmith Hospital (Dr Matthews), London, England.

REFERENCES

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

1. Canadian Study of Health and Aging Working Group. Canadian Study of Health and Aging: study methods and prevalence of dementia. CMAJ. 1994;150(6):899-913. ABSTRACT 2. Saunders AM, Strittmatter WJ, Schmechel D; et al. Association of apolipoprotein E allele epsilon 4 with late-onset familial and sporadic Alzheimer's disease. Neurology. 1993;43(8):1467-1472. FREE FULL TEXT 3. Poirier J, Davignon J, Bouthillier D, Kogan S, Bertrand P, Gauthier S. Apolipoprotein E polymorphism and Alzheimer's disease. Lancet. 1993;342(8873):697-699. FULL TEXT | ISI | PUBMED 4. Bertram L, McQueen MB, Mullin K, Blacker D, Tanzi RE. Systematic meta-analyses of Alzheimer disease genetic association studies: the AlzGene database. Nat Genet. 2007;39(1):17-23. FULL TEXT | ISI | PUBMED 5. Roses AD, Burns DK, Chissoe S, Middleton L, St Jean P. Disease-specific target selection: a critical first step down the right road. Drug Discov Today. 2005;10(3):177-189. FULL TEXT | ISI | PUBMED 6. NCI-NHGRI Working Group on Replication in Association Studies. Replicating genotype-phenotype associations. Nature. 2007;447(7145):655-660. FULL TEXT | PUBMED 7. McKhann G, Drachman D, Folstein M, Katzman R, Price D, Stadlan EM. Clinical diagnosis of Alzheimer's disease: report of the NINCDS-ADRDA Work Group under the auspices of Department of Health and Human Services Task Force on Alzheimer's Disease. Neurology. 1984;34(7):939-944. FREE FULL TEXT 8. American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders. 4th ed. Washington, DC: American Psychiatric Association; 1994.9. Reisberg B, Ferris SH, de Leon MJ, Crook T. The Global Deterioration Scale for assessment of primary degenerative dementia. Am J Psychiatry. 1982;139(9):1136-1139. FREE FULL TEXT 10. Crum RM, Anthony JC, Bassett SS, Folstein MF. Population-based norms for the Mini-Mental State Examination by age and educational level. JAMA. 1993;269(18):2386-2391. FREE FULL TEXT 11. Schmidt R, Freidl W, Fazekas F; et al. The Mattis Dementia Rating Scale: normative data from 1001 healthy volunteers. Neurology. 1994;44(5):964-966. FREE FULL TEXT 12. Rouleau I, Salmon DP, Butters N, Kennedy C, McGuire K. Quantitative and qualitative analyses of clock drawings in Alzheimer's and Huntington's disease. Brain Cogn. 1992;18(1):70-87. FULL TEXT | ISI | PUBMED 13. Fillenbaum GG. Multidimensional Functional Assessment of Older Adults: The Duke Older Americans Resources and Services Procedures. Hillsdale, NJ: Lawrence Erlbaum Associates; 1988.14. Morris JC. The Clinical Dementia Rating (CDR): current version and scoring rules. Neurology. 1993;43(11):2412-2414. FREE FULL TEXT 15. Rabbee N, Speed TP. A genotype calling algorithm for affymetrix SNP arrays. Bioinformatics. 2006;22(1):7-12. FREE FULL TEXT 16. Kass RE, Raftery AE. Bayes factors. J Am Stat Assoc. 1995;90(430):773-795. FULL TEXT | ISI 17. Lettre G, Lange C, Hirschhorn JN. Genetic model testing and statistical power in population-based association studies of quantitative traits. Genet Epidemiol. 2007;31(4):358-362. FULL TEXT | ISI | PUBMED 18. Gordon D, Haynes C, Blumenfeld J, Finch SJ. PAWE-3D: visualizing power for association with error in case-control genetic studies of complex traits. Bioinformatics. 2005;21(20):3935-3937. FREE FULL TEXT 19. Devlin B, Roeder K. Genomic control for association studies. Biometrics. 1999;55(4):997-1004. FULL TEXT | ISI | PUBMED 20. Coon KD, Myers AJ, Craig DW; et al. A high-density whole-genome association study reveals that APOE is the major susceptibility gene for sporadic late-onset Alzheimer's disease. J Clin Psychiatry. 2007;68(4):613-618. PUBMED 21. Grupe A, Abraham R, Li Y; et al. Evidence for novel susceptibility genes for late-onset Alzheimer's disease from a genome-wide association study of putative functional variants. Hum Mol Genet. 2007;16(8):865-873. FREE FULL TEXT 22. Reiman EM, Webster JA, Myers AJ; et al. GAB2 alleles modify Alzheimer's risk in APOE epsilon4 carriers. Neuron. 2007;54(5):713-720. FULL TEXT | ISI | PUBMED 23. Roses AD, Saunders AM, Huang Y, Strum J, Weisgraber KH, Mahley RW. Complex disease-associated pharmacogenetics: drug efficacy, drug safety, and confirmation of a pathogenetic hypothesis (Alzheimer's disease). Pharmacogenomics J. 2007;7(1):10-28. FULL TEXT | ISI | PUBMED 24. Chang S, ran Ma T, Miranda RD, Balestra ME, Mahley RW, Huang Y. Lipid- and receptor-binding regions of apolipoprotein E4 fragments act in concert to cause mitochondrial dysfunction and neurotoxicity. Proc Natl Acad Sci U S A. 2005;102(51):18694-18699. FREE FULL TEXT 25. Li Z, Okamoto K, Hayashi Y, Sheng M. The importance of dendritic mitochondria in the morphogenesis and plasticity of spines and synapses. Cell. 2004;119(6):873-887. FULL TEXT | ISI | PUBMED 26. Devi L, Prabhu BM, Galati DF, Avadhani NG, Anandatheerthavarada HK. Accumulation of amyloid precursor protein in the mitochondrial import channels of human Alzheimer's disease brain is associated with mitochondrial dysfunction. J Neurosci. 2006;26(35):9057-9068. FREE FULL TEXT 27. Risner ME, Saunders AM, Altman JF; et al. Efficacy of rosiglitazone in a genetically defined population with mild-to-moderate Alzheimer's disease. Pharmacogenomics J. 2006;6(4):246-254. ISI | PUBMED 28. Roses AD, Ramamurthy L, Barnes M, Davies K, Saunders AM. Haplotypes within the APOE LD region may have pharmacogenetic effects predicting efficacy of Alzheimer's patients receiving rosiglitazone. Paper presented at: Human Genome Variation International Meeting 2007; September 6, 2007; Barcelona, Spain.29. Kladney RD, Bulla GA, Guo L; et al. GP73, a novel Golgi-localized protein upregulated by viral infection. Gene. 2000;249(1-2):53-65. FULL TEXT | ISI | PUBMED 30. Blacker D, Bertram L, Saunders AJ; et al. Results of a high-resolution genome screen of 437 Alzheimer's disease families. Hum Mol Genet. 2003;12(1):23-32. FREE FULL TEXT 31. Holmans P, Hamshere M, Hollingworth P; et al. Genome screen for loci influencing age at onset and rate of decline in late onset Alzheimer's disease. Am J Med Genet B Neuropsychiatr Genet. 2005;135(1):24-32. PUBMED 32. Lein ES, Hawrylycz MJ, Ao N; et al. Genome-wide atlas of gene expression in the adult mouse brain. Nature. 2007;445(7124):168-176. FULL TEXT | PUBMED 33. Nagase T, Kikuno R, Ohara O. Prediction of the coding sequences of unidentified human genes, XXII: the complete sequences of 50 new cDNA clones which code for large proteins. DNA Res. 2001;8(6):319-327. ABSTRACT 34. Hunter DJ, Kraft P. Drinking from the fire hose: statistical issues in genomewide association studies. N Engl J Med. 2007;357(5):436-439. FREE FULL TEXT 35. Wellcome Trust Case Control Consortium. Genome-wide association study of 14 000 cases of seven common diseases and 3000 shared controls. Nature. 2007;447(7145):661-678. FULL TEXT | ISI | PUBMED 36. Skol AD, Scott LJ, Abecasis GR, Boehnke M. Joint analysis is more efficient than replication-based analysis for two-stage genome-wide association studies. Nat Genet. 2006;38(2):209-213. FULL TEXT | ISI | PUBMED 37. Barnes MR. Navigating the HapMap. Brief Bioinform. 2006;7(3):211-224. FREE FULL TEXT 38. Lee JH, Cheng R, Schupf N; et al. The association between genetic variants in SORL1 and Alzheimer disease in an urban, multiethnic, community-based cohort. Arch Neurol. 2007;64(4):501-506. FREE FULL TEXT 39. Rogaeva E, Meng Y, Lee JH; et al. The neuronal sortilin-related receptor SORL1 is genetically associated with Alzheimer disease. Nat Genet. 2007;39(2):168-177. FULL TEXT | ISI | PUBMED

CiteULike    Connotea    Del.icio.us    Digg    Reddit    Technorati     What's this?

THIS ARTICLE HAS BEEN CITED BY OTHER ARTICLES

Integrated associations of genotypes with multiple blood biomarkers linked to coronary heart disease risk
Drenos et al.
Hum Mol Genet 2009;18:2305-2316.
ABSTRACT | FULL TEXT  

Pathway and network-based analysis of genome-wide association studies in multiple sclerosis
Baranzini et al.
Hum Mol Genet 2009;18:2078-2090.
ABSTRACT | FULL TEXT  

Genetic analysis of coronary artery disease single-nucleotide polymorphisms in diabetic nephropathy
McKnight et al.
Nephrol Dial Transplant 2009;0:gfp015v1-gfp015.
ABSTRACT | FULL TEXT  

200 Years After Darwin
Rosenberg et al.
JAMA 2009;301:660-662.
FULL TEXT  

200 Years After Darwin
Rosenberg et al.
Arch Neurol 2009;66:153-155.
FULL TEXT  

GAB2 as an Alzheimer Disease Susceptibility Gene: Follow-up of Genomewide Association Results
Schjeide et al.
Arch Neurol 2009;66:250-254.
ABSTRACT | FULL TEXT  

How to Use an Article About Genetic Association: A: Background Concepts
Attia et al.
JAMA 2009;301:74-81.
ABSTRACT | FULL TEXT  

Neuromics and Neurological Disease
Rosenberg
Arch Neurol 2008;65:307-308.
FULL TEXT