bioRxiv preprint doi: https://doi.org/10.1101/043000. this version posted March 9, 2016. The copyright holder for this preprint (which was not
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Molecular genetic contributions to social deprivation and household income in
UK Biobank (n = 112,151)
W David Hill PhD1,2#*, Saskia P Hagenaars MSc1,2,3#, Riccardo E Marioni PhD1,4,5, Sarah E Harris PhD1,4, David
CM Liewald BSc 1,2, Gail Davies PhD1,2, International Consortium for Blood Pressure, Andrew M McIntosh
MD3, Catharine R Gale PhD1,2,6†, Ian J Deary PhD1,2†*
1
Centre for Cognitive Ageing and Cognitive Epidemiology, University of Edinburgh, 7 George Square,
Edinburgh EH8 9JZ, UK
2
Department of Psychology, University of Edinburgh, 7 George Square, Edinburgh, EH8 9JZ, UK
3
Division of Psychiatry, University of Edinburgh, Edinburgh, EH10 5HF, UK
4
Medical Genetics Section, University of Edinburgh Centre for Genomics and Experimental Medicine and
MRC Institute of Genetics and Molecular Medicine, Western General Hospital, Crewe Road, Edinburgh, EH4
2XU, UK
5
Queensland Brain Institute, The University of Queensland, Brisbane, 4072, QLD, Australia
6
MRC Lifecourse Epidemiology Unit, University of Southampton, SO16 6YD, UK
†These authors contributed equally
#
These authors contributed equally to the work
*
Corresponding author,
W. David Hill or Ian J. Deary
Centre for Cognitive Ageing and Cognitive Epidemiology
Department of Psychology
University of Edinburgh
7 George Square
Edinburgh, EH8 9JZ
Scotland, UK
Telephone: +44 131 650 3452
Fax: +44 131 651 1771
ian.deary@ed.ac.uk
David.Hill@ed.ac.uk
1
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Summary
Individuals with lower socio-economic status (SES) are at increased risk of physical and mental
illnesses and tend to die at an earlier age [1-3]. Explanations for the association between SES and
health typically focus on factors that are environmental in origin [4]. However, common single
nucleotide polymorphisms (SNPs) have been found collectively to explain around 18% (SE = 5%) of
the phenotypic variance of an area-based social deprivation measure of SES [5]. Molecular genetic
studies have also shown that physical and psychiatric diseases are at least partly heritable [6]. It is
possible, therefore, that phenotypic associations between SES and health arise partly due to a shared
genetic etiology. We conducted a genome-wide association study (GWAS) on social deprivation and
on household income using the 112,151 participants of UK Biobank. We find that common SNPs
explain 21% (SE = 0.5%) of the variation in social deprivation and 11% (SE = 0.7%) in household
income. Two independent SNPs attained genome-wide significance for household income,
rs187848990 on chromosome 2, and rs8100891 on chromosome 19. Genes in the regions of these
SNPs have been associated with intellectual disabilities, schizophrenia, and synaptic plasticity.
Extensive genetic correlations were found between both measures of socioeconomic status and
illnesses, anthropometric variables, psychiatric disorders, and cognitive ability. These findings show
that some SNPs associated with SES are involved in the brain and central nervous system. The genetic
associations with SES are probably mediated via other partly-heritable variables, including cognitive
ability, education, personality, and health.
2
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Results and Discussion
Using GCTA-GREML [7], we first estimated the heritability of each of the SES variables and
found that a total of 21% (SE = 0.5%) of phenotypic variation in social deprivation and 11% (SE=
0.7%) of household income was explained by the additive effects of common SNPs. Next, genomewide association analyses for social deprivation and household income were performed using an
imputed dataset that combined the UK10K haplotype and 1000 Genomes Phase 3 reference panels;
details can be found at http://biobank.ctsu.ox.ac.uk/crystal/refer.cgi?id=157020. We found no
genome-wide significant findings associated with social deprivation (See Figure 1 and Figure S1). For
household income, four SNPs attained genome-wide significance (P < 5 x 10-8), rs187848990 on
chromosome 2, and rs7252896 rs7255223 and rs8100891 on chromosome 19 (See Figure 2, Figure S1
and Table S1).
The “clump” function in PLINK [8] was used to identify patterns of linkage disequilibrium in
the data set and showed that these four SNPs were located in two independent regions (Figure S2).
The region on chromosome 2 spanned 583kb and the most significant SNP was rs187848990, P =
2.325x10-8. This region contains five genes: AFF3, CHST10, LONRF2, NMS, and PDCL3. The AFF3
gene has previously been associated with intellectual disability [9], and CHST10 is involved with
synaptic plasticity [10]. The region on chromosome 19 spanned 18kb with the most significant SNP
being rs8100891, P = 3.423 x 10-8. This region contains the gene ZNF507 which has been implicated
in neurodevelopmental disorders including schizophrenia [11], a disorder affecting cognitive function,
that shows a strong genetic correlation with intelligence [12]. It is possible, therefore, that these
genetic associations with SES may be mediated, in part, through cognitive ability; it is well
established that an individual’s level of cognitive ability is predictive of their socioeconomic status
[13].
Using the GTEx database (http://www.broadinstitute.org/gtex/), cis-eQTL associations were
identified for the four household income genome-wide significant SNPs (Table S2). For this study,
data mining of regulatory elements was restricted to normal tissues. There was evidence of regulatory
elements associated with all four of the genome-wide significant SNPs (Table S2).
3
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Gene based association testing was conducted using MAGMA [14]. Following Bonferroni
correction for multiple testing (α = 2.768 x10-6), gene based association tests identified one gene
associated with social deprivation, ACCSL on chromosome 11. For household income 12 genes
showed a significant association: KANSL1, MST1, RNF123, MAPT, APEH, BSN, PLEKHM1, SGCD,
DAG1, CRHR1, AMT, and ZDHHC11 (Supplemental Experimental Procedures). The MAPT,
KANSL1, PLEKHM1, and CRHR1 genes have been associated with Alzheimer’s disease [15]. Tables
S3 and S4 show the top 20 genes and their level of association with social deprivation and household
income.
Partitioned heritability analysis was then conducted on both SES phenotypes [16]. The goal of
the partitioned heritability analysis was to determine if SNPs grouped together, according to a specific
biological function or role, make an enriched contribution to the total proportion of heritability for
each of the SES variables. The functional categories used here overlap considerably, meaning that the
heritability measured by all groups, when they are summed, can exceed 100%. Figures S3 and S4
show the results of the enrichment analysis for social deprivation and for household income. By
deriving a heritability estimate for functional classes of SNPs across the genome, a significant
enrichment was found for evolutionarily conserved regions of the genome. These evolutionarily
conserved regions accounted for 2.6% of the SNPs in both SES phenotypes and accounted for 44%
(SE = 12%) of the heritability of social deprivation and 53% (SE = 12%) of the heritability for
household income. The trend for an enrichment in heritability emanating from such regions is
consistent with the results from other quantitative traits and diseases [16] and, as such, further
highlights the importance of these genetic regions as sources of phenotypic variance across traits.
Under models of neutral selective pressure, these regions accumulate base-pair substitutions at a
lower rate, indicative of their being regions where mutation results in the production of phenotypic
variance susceptible to the effects of natural selection. Genetic variance within these regions may
highlight a role for disease-causing loci which in turn might account for some phenotypic variance in
SES. However, it is also possible that, as intelligence is phenotypically and genetically associated
with many health traits [17] and thought to be evolutionarily selected for [18], these regions may
show their association with SES partly through cognitive differences. These two explanations are not
4
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mutually exclusive because, after intelligence is included as a covariate, the associations between
adult SES and health outcomes, although attenuated, remain significant [1].
The functional category of H3K9ac also showed a statistically significant enrichment for
household income. This grouping contained 23% of the SNPs which collectively explained 64% (SE
= 11%) of its SNP-based heritability. This functional group corresponds to histone marks, which are
post-translational alterations of histones that operate either to facilitate or to repress the level of gene
expression. Specifically, H3K9ac pertains to the acetylation of histone H3 at lysine 9. The Enhancer
regions and DNase I hypersensitivity sites (DHS) also showed significant enrichment for household
income. Enhancer regions included 15% of the SNPs which collectively explained 48% (SE = 12%)
of the SNP-based heritability. The DHS functional category contained 50% of the SNPs collectively
accounting for 100% of the heritability estimate (SE = 17%).
A cell-specific analysis of 10 broad tissue types was conducted (See Supplementary
Experimental Information). Figures S5 and S6 show the results of cell specific enrichment for social
deprivation and household income. For social deprivation, significant enrichment was found in
variants exerting an effect within the central nervous system. Variants expressed in the central
nervous system accounted for 15% of the total number of SNPs, but accounted for 47% (SE = 11%)
of the heritability of social deprivation and 37% (SE = 9%) of the heritability of household income.
For household income, this did not survive multiple testing correction.
We next derived genetic correlations, using linkage disequilibrium score regression (LDS
regression)[19], between both measures of SES and a set of 32 phenotypes that have all been shown
to be phenotypically associated with SES. Table S5 provides a reference describing the phenotypic
associations between measures of SES and broadly-conceived health variables. Full details of the
GWAS that provided summary statistics for each of the 32 phenotypes, along with links to the data,
are provided in Table S6. The direction of effect for the genetic correlations and polygenic profile
scores examining Townsend scores was reversed to facilitate a comparison with the household income
variable.
Following false discovery rate (FDR) correction for multiple comparisons, 16 of the 34
genetic correlations were statistically significant for the Townsend social deprivation measure (See
5
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Figure 3 & Tables S7), and 24 of the 34 were significant for household income (Figure 4 & Table S8).
The large number of genetic correlations found indicates that the molecular genetic associations with
SES overlap with many other phenotypes. A large degree of overlap was found for variables that are
cognitive in nature. Significant genetic correlations were observed, for example, between both
measures of SES and childhood cognitive ability (social deprivation, rg = 0.500, income, rg = 0.668),
and also with longevity (social deprivation, rg = 0.301, household income, rg = 0.303). The direction
of effect in each instance indicates that more affluent SES is associated with longer life and higher
childhood intelligence. The average age of the participants in the GWAS for childhood intelligence
was 11 years, whereas the measurements of SES from UK Biobank were taken at a mean age of 57
years. The finding of a genetic correlation between these two traits may indicate that a set of genetic
variants contribute to higher intelligence, which in turn contributes to a higher SES in midlife.
Significant genetic correlations were found between household income and intracranial volume and
infant head circumference (rg = 0.533, rg = 0.239, respectively), indicating that the variants associated
with brain size may also be associated with the amount of money brought into a household. The
genetic correlation of 0.34, (SE = 0.07) between verbal numerical reasoning and the Townsend social
deprivation index in UK Biobank was reported by us elsewhere (Marioni et al., in preparation).
A noteworthy feature of our findings is that the pattern of genetic correlations between our
two measures of SES--one area-based and one individual-based--was very similar and the genetic
correlation between the two measures of SES was 0.871, (SE = 0.064). The Townsend social
deprivation score is widely used as a proxy indicator of adult socioeconomic status, usually in the
absence of an individual measure. It has been shown to be predictive of cancer incidence, all-cause
mortality and other health outcomes [20]. Such area-level effects may comprise both compositional
effects, i.e. effects that can be explained in terms of the characteristics of the residents of those areas,
and contextual effects, i.e. effects that can be explained in terms of the characteristics of the areas.
Although ecological correlations cannot be used to make causal inferences about individuals—the
ecological fallacy—it has been argued that they arise largely from associations at the individual level
[21]. There is evidence that area-based Townsend scores correlate highly with a similar measure of
deprivation calculated at the individual level [22]. In our UK Biobank sample, where the individual6
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level measure of SES was based on household income alone, its correlation with Townsend score was
small to moderate in size (r = 0.24); however, despite this, the pattern of genetic correlations between
these two measures was very similar.
There are at least two explanations for the genetic SES-health correlations found using the
LDS regression method. The first is that the genetic correlations might have been found as a result of
the same genetic variants being directly involved in two phenotypes. The second is the notion of
mediated pleiotropy, which describes situations where a phenotype is causally related to another;
therefore, if a genetic variant is associated with the first phenotype it will be indirectly associated with
the second [23]. Should multiple variants be used to establish pleiotropy, such as when using the LDS
regression method, both of these forms of pleiotropy may apply, at different loci. However, because
SES has no clear biological analog—it describes the environment of an individual or their
achievements in it—mediated pleiotropy thorough intelligence or personality traits such as
conscientiousness, for example, would appear to be a much more likely interpretation than biological
pleiotropy.
The associations between rs187848990 and rs8100891 with household income, along with the
heritability estimates for both measures of SES, are also most likely to be the result of mediation
through other phenotypes. As genetic differences will not directly result in individual differences in
SES, they may be contributing to differences in intelligence, personality, resistance to diseases, and
other factors which, in turn, can contribute to differences in SES.
The effect sizes found for each individual SNP were small; however, as for any other
polygenic trait, it is the combined effect of multiple SNPs that gives rise to observable phenotypic
variance. Polygenic profile scores were created for 28 health-related phenotypes using published
GWAS in all participants with genome-wide SNP data. When predicting into social deprivation based
on the Townsend score, a total of 10 polygenic profile scores derived from GWAS summary data
could predict a significant proportion of phenotypic variance (Table S9 for the most predictive model
and Table S10 for results across P value thresholds). When predicting into household income, 27 out
of 28 demonstrated statistical significance (Table S11 for the most predictive model and Table S12 for
results across P value thresholds). Polygenic profile scores explained only a very small proportion of
7
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variance, but they illustrate that genetic risk for a range of diseases and cognitive ability can predict
variance in these two SES measures.
The results here show that 21% of individual differences in area level social deprivation and
11% of household income can be explained by additive common genetic factors. Four genome-wide
significant SNPs were found for household income, leading to the identification of two independent
genomic regions containing genes with known associations with intellectual disabilities, synaptic
plasticity, and schizophrenia. Extensive genetic correlations were found between both measures of
SES and health-related traits, indicating a highly diffuse genetic architecture. These genetic
correlations might provide a partial explanation for the phenotypic association between SES and
health the majority of which, we think, is due to environmental factors.
Experimental Procedure
Data were used from UK Biobank (http://www.ukbiobank.ac.uk) [24] to examine two
measures of SES, the Townsend Social Deprivation Index [25], a measure of the social deprivation of
the area in which the participant lives, and household income. A total of 112,005 individuals had a
Townsend score, of whom 52.53% were female (Mean age = 56.91 years, SD = 7.93, range 40-73). A
total of 96,900 participants had data pertaining to household income of whom 50.64% were female
(Mean age = 56.53 years, SD = 7.95, range 40-73). Participants had undergone genome-wide SNP
genotyping.
We conducted separate analyses for the Townsend deprivation score and household income.
All analyses included only those individuals who described themselves as white British. All
phenotypes were adjusted for age, gender, assessment center, genotyping batch, genotyping array, and
10 principal components in order to correct for population stratification prior to all analyses. See
Supplemental Experimental Information for full description of genotyping, imputation, and the
phenotypes used.
8
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Figure legends
Figure 1. Manhattan plot of –log10 (P values) for social deprivation. The red line indicates genomewide significance (P < 5x10-8). The black line indicates values that were suggestive of statistical
significance (P < 1 x 10-5).
Figure 2. Manhattan plot of –log10 (P values) for household income. The red line indicates genome
wide significance (P < 5x10-8). The black line indicates values that were suggestive of statistical
significance (P < 1 x 10-5).
Figure 3. Genetic correlations between social deprivation (scores were reversed so that a higher
Townsend score indicates a higher SES) and health and anthropometric variables. The x-axis depicts
the magnitude of the genetic correlations and the y axis shows each trait. Statistical significance is
indicated by asterisk. Statistical significance at P = 0.01535.
Abbreviations: SSGAC, social science genetic associations consortium; HOMA B, homeostatic model
assessment beta-cells; HOMA IR, homeostatic model assessment insulin resistance; HBA1C, glycated
hemoglobin; ADHD, attention deficit hyperactivity disorder; MDD, major depressive disorder; BMI,
body mass index; ICV, intracranial volume.
Figure 4. Genetic correlations between household income (where higher scores represent higher
income) and health and anthropometric variables. The x-axis depicts the magnitude of the genetic
correlations and the y axis shows each trait. Statistical significance is indicated by asterisk. Statistical
significance at P = 0.032.
Abbreviations: SSGAC, social science genetic associations consortium; HOMA B, homeostatic model
assessment beta-cells; HOMA IR, homeostatic model assessment insulin resistance; HBA1C, glycated
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hemoglobin; ADHD, attention deficit hyperactivity disorder; MDD, major depressive disorder; BMI,
body mass index; ICV, intracranial volume.
Author contributions
Conceptualization, WDH, CRG, IJD.; Software DCML, GD.; Formal Analysis, WDH,SPH,REM.;
Investigation, WDH.; Resources, International Consortium for Blood Pressure.; Data curation, WDH,
SPH, SEH.; Writing – original draft, WDH. Writing Review and Editing, WDH, SPH, REM, SEH,
DCML, GD, International Consortium for Blood Pressure, AMM CRG, IJD.
Acknowledgements
This work was undertaken in The University of Edinburgh Centre for Cognitive Ageing and
Cognitive Epidemiology (CCACE), supported by the cross-council Lifelong Health and Wellbeing
initiative (MR/K026992/1). Funding from the Biotechnology and Biological Sciences Research
Council (BBSRC), the Medical Research Council (MRC), and the University of Edinburgh and
gratefully acknowledged. CCACE funding supports IJD.
WDH is supported by a grant from Age UK (Disconnected Mind Project).
We thank Stuart J Ritchie for comments on a draft of the manuscript.
Declaration of interests
IJD is a participant in UK Biobank.
12