JNN452890.indd


 © 2016 S. Karger AG, Basel
1661–6499/16/0096–0254$39.50/0 

 Original Paper 

 J Nutrigenet Nutrigenomics 2016;9:254–264 

 The  CAPN2/CAPN8  Locus on Chromosome 
1q Is Associated with Variation in Serum 
Alpha-Carotene Concentrations 

 Christopher R. D’Adamo    a     Valerie J. Dawson    b     Kathleen A. Ryan    c     
Laura M. Yerges-Armstrong    c     Richard D. Semba    d     Nanette I. Steinle    c, f     
Braxton D. Mitchell    c, e     Alan R. Shuldiner    c     Patrick F. McArdle    c   

  a    Department of Family & Community Medicine, University of Maryland School of 
Medicine,  b    University of Maryland School of Medicine,  c    Department of Medicine, 
University of Maryland School of Medicine,  d    Wilmer Eye Institute, Johns Hopkins 
University School of Medicine,  e    Geriatrics Research and Education Clinical Center, 
Baltimore Veterans Administration Medical Center, and  f    Baltimore Veterans Affairs 
Medical Center,  Baltimore, MD , USA

 

 Keywords 
 Alpha-carotene · Carotenoids · Genome-wide association study ·  CAPN2  ·  CAPN8  ·  PRKCE  · 
Old Order Amish 

 Abstract 
  Background/Aims:  Alpha-carotene is a provitamin A carotenoid present in fruits and vege-
tables. Higher serum concentrations of α-carotene have been associated with lower risk of 
cancer and all-cause mortality. Previous studies have suggested that genetic variants influ-
ence serum concentrations of provitamin A carotenoids, but to date no variants have been 
robustly associated with serum α-carotene concentrations. The aim of this study was to iden-
tify genetic associations with serum α-carotene concentrations using the genome-wide as-
sociation study (GWAS) approach.  Methods:  A GWAS of serum α-carotene concentrations was 
conducted in 433 Old Order Amish adults who had consumed a 6-day controlled diet. Linear 
regression models adjusting for age, gender, and family structure were utilized to evaluate 
associations between genetic variants and serum α-carotene concentrations.  Results:  Ge-
nome-wide significant associations with α-carotene concentrations were observed for loci on 
chromosome 1q41 between the genes  CAPN2  and  CAPN8  (rs12137025,  p  = 3.55 × 10 –8 ), chro-
mosome 2p21 in  PRKCE  (rs2594495,  p  = 1.01 × 10 –8 ), and chromosome 4q34 (rs17830069,
 p  = 2.89 × 10 –8 ).  Conclusions:  We identified 3 novel loci associated with serum α-carotene 
concentrations among a population that consumed a controlled diet. While replication is nec-
essary, the  CAPN2/CAPN8  locus provides compelling evidence for an association with serum 
α-carotene concentrations and may suggest a relationship with the development and pro-
gression of cancers.  © 2016 S. Karger AG, Basel 

 Received: October 10, 2015 
 Accepted: October 27, 2016 
 Published online: December 22, 2016 

 Christopher R. D’Adamo, PhD 
 University of Maryland School of Medicine 
 520 West Lombard St., East Hall 
 Baltimore, MD 21201 (USA) 
 E-Mail cdadamo   @   som.umaryland.edu 

www.karger.com/jnn

 DOI: 10.1159/000452890 



255J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

 Introduction 

 The carotenoids are a class of pigments synthesized by plants and bacteria  [1, 2] . Carot-
enoids are not produced endogenously in humans and other animals and are obtained from 
the diet  [1] . Only 40 of the 600 identified carotenoids are contained in foods, the most 
abundant carotenoid-containing foods being fruits and vegetables  [3] . Approximately half of 
the dietary carotenoids can be found in human serum and tissues, with α-carotene, β-carotene, 
lycopene, lutein, zeaxanthin, and β-cryptoxanthin representing 90% of all the carotenoids in 
the human body  [4] . Provitamin A carotenoids can be converted to retinol in the body and 
include β-carotene, α-carotene, and β-cryptoxanthin. Αlpha-carotene is obtained through
the diet mainly from yellow-orange fruits and vegetables, especially carrots, pumpkin, and 
squash  [2] .

  Although observational studies have consistently associated eating of carotenoid-
containing fruits and vegetables with lower risk of a variety of chronic diseases, interven-
tions with carotenoid-rich diets and supplementation have not shown consistent health 
benefits  [5–7] . In fact, β-carotene supplementation has been associated with an increase in 
mortality among smokers, although it should be noted that a high daily dose of synthetic 
β-carotene was utilized in that study  [8] . The discrepancy between observational and 
clinical studies may be due in part to genetic differences in how circulating carotenoid 
concentrations and their physiological effects respond to carotenoid intake. Alpha-carotene 
has not been studied as extensively as β-carotene, but it is believed to have numerous bene-
ficial health effects. Alpha-carotene is a potent antioxidant that prevents lipid oxidation, 
scavenges free radicals, and enhances gap junction communication  [9] . In vivo studies 
suggest that the ability of α-carotene to inhibit proliferation of cancer cells is approximately 
10 times more potent than that of β-carotene  [10] . In addition, α-carotene has been asso-
ciated in observational and animal studies with a decreased risk for gastric cancers, liver 
and lung cancers, and other chronic diseases, including diabetes, cardiovascular disease, 
and chronic lower respiratory diseases  [2, 11, 12] . Due in part to its antioxidant properties, 
low levels of α-carotene have also been associated with diseases that are worsened by 
excessive oxidative stress, such as glaucoma and atrophic gastritis  [13, 14] . Furthermore, 
data from the National Health and Nutrition Examination Surveys revealed an inverse asso-
ciation between serum α-carotene concentrations and the risk of all-cause mortality as well 
as mortality from cardiovascular disease, cancer, and all other causes not related to cardio-
vascular disease or cancer  [2] . Therefore, a greater understanding of genetic associations 
with circulating α-carotene concentrations in humans may have important public health 
implications.

  There is one previously reported genome-wide association study (GWAS) of α-carotene 
concentrations. In a meta-analysis that combined results across 3 diverse study populations 
( n  = 3,881 subjects total), a single locus was found to be associated with provitamin A carot-
enoids at a genome-wide threshold for statistical significance. In this study, single nucleotide 
polymorphisms (SNPs) in the gene  BCO1  were associated with significantly higher circulating 
concentrations of β-carotene, and the same locus was associated to a lesser extent with 
α-carotene concentrations  [15] .  BCO1  catalyzes the first step of provitamin A carotenoids to 
vitamin A (retinol) in the small intestine.  BCO1  is a 15-15 ′  dioxygenase that performs a 15-15 ′  
central cleavage that generates one molecule of retinol from each molecule of α-carotene. The 
association between SNPs in  BCO1  and α-carotene was weak ( p  = 0.001), relative to its asso-
ciation with β-carotene ( p  = 1.6 × 10 –24 ), and did not have convincing evidence of consistency 
in the original report ( p  = 0.057 in the replication cohort). Little else is known about genetic 
variants that may influence serum α-carotene concentrations, and no robustly associated 
genetic associations with this important micronutrient have been identified to date.



256J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

  The goal of this study was to identify novel genetic associations with serum α-carotene 
concentrations. We studied a relatively genetically homogenous population of Old Order 
Amish men and women living in Lancaster County, Pennsylvania. The study participants were 
administered a 6-day controlled diet, which helped reduce variability in serum α-carotene 
concentrations associated with varying intake of α-carotene and fat as well as other dietary 
factors that influence its absorption. We hypothesized that the controlled diet would enable 
us to more closely isolate the genetic influences of serum α-carotene concentrations. While 
relatively brief, the controlled diet helped reduce potential confounding of the relationship 
between genetic variants and circulating α-carotene concentrations introduced by varying 
dietary intake.

  Methods 

 Study Population 
 The study sample was composed of the 433 participants from the Heredity and Phenotype Intervention 

(HAPI) Heart Study who completed a controlled diet and had frozen blood samples obtained during a clinic 
visit on the final day of the controlled diet. The design of the HAPI Heart Study has been described previously 
 [16] . Briefly, the initial aim of the HAPI Heart Study was to identify genetic and environmental determinants 
of the responses to intervention affecting cardiovascular risk factors. Of the 868 Old Order Amish adults 
recruited into the HAPI Heart study, 469 were administered the controlled dietary intervention and subse-
quently provided a blood sample at the conclusion of the 6-day diet. There were 27 samples of insufficient 
quality to measure serum α-carotene concentrations and 8 participants with incomplete genotype data who 
were excluded from analysis. The study was approved by the Institutional Review Board of the University of 
Maryland School of Medicine, and all participants provided written informed consent.

  Controlled Diet 
 Research staff prepared the controlled diet for study participants. A registered dietitian visited several 

Old Order Amish households to obtain diet histories and observe meals and foods that were in their homes. 
All meals in the controlled diet were designed to be representative of the typical diets of Old Order Amish 
adults and were delivered to the homes of study participants during the 6-day controlled diet period. Study 
participants did not consume any prescribed or over-the-counter medications or dietary supplements during 
this 6-day period. The complete menus for the 6-day controlled diet that the study participants consumed 
are provided in the online supplementary material (see www.karger.com/doi/10.1159/000452890). The 
controlled diet contained an average of 3,277 kilocalories per day, with 49% from carbohydrate, 36% from 
fat, and 15% from protein. There was an average of 525 mg of cholesterol per day in the diet. The diet 
contained approximately 1,724 μg of α-carotene per day, coming primarily from carrots, green beans, and 
lettuce.

  Compliance with the controlled diet was assessed by comparing sodium, potassium, and creatinine 
levels from first morning urine samples obtained (1) prior to consuming the 6-day controlled diet, (2) on the 
final day of the 6-day controlled diet, and (3) on the final day of a second 6-day controlled diet that was low 
in salt and consumed after the blood draw that was used to conduct the GWAS. The compliance data have 
been reported in detail previously  [17] . In brief, while not a direct measure of carotenoid intake, the excreted 
sodium, potassium, and creatinine levels reflecting the varying salt content in the different diets suggest that 
compliance with the controlled diet in this study was excellent.

  Serum Micronutrient Measurement 
 Frozen blood samples taken on the final day of the 6-day controlled diet were assayed for serum concen-

trations of α-carotene, other key carotenoids (β-carotene, lycopene, lutein, zeaxanthin, cryptoxanthin), 
vitamin E (γ-tocopherol, α-tocopherol), and retinol (preformed vitamin A) at the Johns Hopkins University 
Nutritional Biochemistry Laboratory. Reverse-phase high-pressure liquid chromatography was utilized to 
assess serum α-carotene concentrations from each 200 μL frozen blood sample  [18] . The intra- and inter-
assay coefficients of variability for α-carotene were 8.2 and 19.4%, respectively.



257J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

  Genotyping 
 Genotypes were obtained using either the Affymetrix 500K or the Affymetrix 1M SNP chip v6.0 by the 

Genomics Core Laboratory at the University of Maryland. Genotyping calls were made separately for the 2 
chips using BRLMM (500K array) and Birdseed version 2 (1M array), which is part of the Birdsuite tools  [19, 
20] . Called genotypes were then synthesized and filtered by excluding markers with >5% missing and 
extreme Hardy-Weinberg equilibrium ( p  < 5 × 10 –6 ). A total of 397,704 SNPs passed quality control stan-
dards, were called per each calling algorithm, were in common on both arrays, and had a minor allele 
frequency (MAF)  ≥ 1%. These SNPs were then passed to the imputation phase. Imputation was conducted 
with MACH using the HapMap CEU reference sample  [21] . An imputation quality score of  ≥ 30% was used as 
a final quality control filter. Variants with an imputed MAF  ≥ 2% were used in association analyses for a final 
analyzed SNP count of 2,193,082.

  HaploReg version 4.1  [22]  was utilized to pull data from ENCODE and the Roadmap Epigenomic projects 
to annotate the functions of any variants associated with α-carotene concentrations in our analyses. The 
ENCODE and the Roadmap Epigenomic projects provide data across a variety of tissue and cell types. For 
each associated variant, we looked for its predicted chromatin state across multiple cell types, its effect on 
regulatory motifs, and potential enrichment of cell type-specific enhancers.

  Statistical Methods 
 Descriptive statistics were computed to characterize the study sample at baseline and determine the 

mean serum α-carotene concentrations. We estimated the effect of genotype on α-carotene levels at each 
SNP, adjusting for the effects of age and sex by utilizing a general linear model. Genotype was coded as the 
number of copies of the reference allele (0, 1, or 2), thereby corresponding to an additive genetic model. 
GWAS analyses were performed using the MMAP software, which accounts for family structure  [23] . Statis-
tical analysis was performed using a variance component approach to account for relatedness among study 
participants. This approach has been shown to provide valid estimates of regression parameters  [24] . We 
estimated that our sample provided 80% power to detect SNPs accounting for 9–10% of trait variation at 
genome-wide thresholds for statistical significance ( p  < 5 × 10 –8 ).

  Our secondary aim of the statistical analysis was to perform replicative association testing of previously 
reported associations. Ferrucci et al.  [15]  previously reported associations with serum α-carotene, with one 
locus achieving genome-wide significance. We here report replicative association tests for rs6564851 at the 
 BCO1  locus.

 Table 1. Characteristics of our Old Order Amish study population from Lancaster County, PA after consuming 
a 6-day controlled diet

Characteristic All 
(n = 433)

Female 
(n = 181)

Male 
(n = 252)

p value1

Age, years 43.1 ± 12.3 45.6 ± 13.1 41.4 ± 12.5 <0.0001
BMI 26.4 ± 4.22 27.8 ± 5.06 25.4 ± 3.13 <0.0001
Lycopene, μmol/L 0.73 ± 0.37 0.71 ± 0.33 0.74 ± 0.40 0.2
Lutein, μmol/L 0.25 ± 0.10 0.24 ± 0.09 0.27 ± 0.10 0.004
Zeaxanthin, μmol/L 0.12 ± 0.06 0.11 ± 0.05 0.13 ± 0.06 0.01
Cryptoxanthin, μmol/L 0.16 ± 0.07 0.16 ± 0.07 0.16 ± 0.06 0.9
Αlpha-carotene, μmol/L 0.29 ± 0.23 0.32 ± 0.25 0.27 ± 0.21 0.04
Βeta-carotene, μmol/L 0.70 ± 0.50 0.78 ± 0.58 0.64 ± 0.42 0.006
Retinol, μmol/L 1.53 ± 0.37 1.51 ± 0.37 1.55 ± 0.36 0.3
Gamma-tocopherol, μmol/L 4.68 ± 1.68 4.71 ± 1.81 4.66 ± 1.58 0.6
Alpha-tocopherol, μmol/L 30.5 ± 7.79 31.4 ± 8.02 29.8 ± 7.57 0.07

 1 The Student t test was utilized to calculate p values for differences in all variables between females and 
males.



258J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

  Results 

 The baseline characteristics of the study sample are provided in  Table 1 . There were 252 
men and 181 women in the study. The participants had a mean age of 43.1 years and a mean 
BMI of 26.4; mean α-carotene concentrations were 0.29 μmol/L. The residual heritability of 
α-carotene concentrations after accounting for age and sex was estimated to be 0.23 ± 0.11.

  A Manhattan plot summarizing the results of the GWAS is provided in  Figure 1 . There was 
little evidence for genomic inflation (lambda = 1.00), as illustrated in  Figure 2 . Details of the 
genome-wide significant ( p  < 5 × 10 –8 ) associations are given in  Table 2 .

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Theoretical p values (–log10)

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  Fig. 1.  Manhattan plot for the genome-wide association study of serum α-carotene concentrations in the 
study population following a 6-day controlled diet. The  x  axis represents the chromosomal position along the 
genome. The  y  axis shows the  p  value for the association test at each locus on the log scale. 

  Fig. 2.  Quantile-quantile plot
of the genome-wide association 
study of serum α-carotene con-
centrations. The axes plot the ob-
served ( y  axis) versus theoretical 
( x  axis) association  p  values on 
the log scale for all single nucleo-
tide polymorphisms with a minor 
allele frequency >1%. The Old Or-
der Amish are a closed founder 
population with little admixture 
expected. The genomic control 
(GC) lambda is estimated to be 
1.00, indicating little bias due to 
population stratification. 

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259J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

  Three novel loci with genome-wide significant associations with α-carotene concentra-
tions were detected on chromosomes 1, 2, and 4. The strongest genetic evidence of an associ-
ation exists on chromosome 1q41.  Figure 3  provides a regional association plot of the genome-
wide significant association on chromosome 1. Several SNPs in linkage disequilibrium tag this 
association. The minor allele at the lead SNP (rs12137025,  p  = 3.55 × 10 –8 ) was associated with 
a 0.19 μmol/L increase in serum α-carotene, and this locus accounted for 7.1% of the variation 
in α-carotene levels. The minor allele at the locus C is present in the Old Order Amish (MAF = 
0.069) at frequencies similar to those of other populations (HapMap CEU = 0.062).

  Two other genome-wide significant associations were identified, though there was little 
corroborating evidence from nearby SNPs at those loci. The strongest of the associations with 
α-carotene concentrations was a locus on chromosome 2p21 (SNP = rs2594495;  p  = 1.01 × 
10 –8 ). Each copy of the A allele was associated with a 0.37 μmol/L increase in serum α-carotene, 
and this locus accounted for 7.2% of the variation in α-carotene levels.  Figure 4  provides a 
regional association plot of the genome-wide significant association on chromosome 2. The 
MAF at the locus A is present in the Old Order Amish (MAF = 0.039), though it is more frequent 
in other populations (HapMap CEU = 0.11). The rs2594495 variant is situated in an intronic 
region of the  PRKCE  gene.

  Finally, we identified a genome-wide significant association with a locus on chromosome 
4q34 (lead SNP = rs17830069;  p  = 2.89 × 10 –8 ). Each copy of the G allele was associated with 
a 0.38 μmol/L increase in serum α-carotene, and this locus accounted for 7.5% of the vari-
ation in α-carotene levels. The minor allele at the locus G is present in the Old Order Amish 
(MAF = 0.023) as well as other populations (HapMap CEU = 0.050).  Figure 5  provides a 
regional association plot of the genome-wide significant association on chromosome 4; 
rs17830069 is in an intergenic region near the non-protein-coding RNA  LINC00290 . There 
are no obvious candidate genes in the region.

  We also performed look-ups for SNPs at the  BCO1  locus previously reported to be asso-
ciated with serum β-carotene levels in the GWAS meta-analysis reported by Ferrucci et al. 
 [15] . There was no evidence of an association between this locus and α-carotene concentra-
tions in our study population (lead SNP: rs6564851,  p  = 0.28).

  GWAS was also performed for the other carotenoids (β-carotene, lycopene, lutein, 
zeaxanthin, cryptoxanthin), vitamin E (α-tocopherol, γ-tocopherol), and retinol that were 
assayed. In brief, there were no meaningful associations noted between retinol, vitamin E, or 
any of the other carotenoids and any other genetic loci ( p  > 5 × 10 –8 , data not shown), with 
the exception of lycopene. Serum lycopene concentrations among our study population were 
associated ( p  = 3.41 × 10 –9 ) with the variant rs7680948 on chromosome 4, located in the 
intron region of the  SETD7  gene  [25] . In addition, our results offered nominal support ( p  = 
3.79 × 10 –4 ) for the association previously noted between  SCARB1  and serum lycopene levels, 
albeit with a different variant (rs11057841) in the region.

 Table 2. Genome-wide (p < 5 × 10 – 8) associations with serum α-carotene concentrations

SNP Chromo-
some

Position Gene MAF Coded 
allele

Beta (SE) p value

rs2594495 2 46262970 PRKCE 0.04 A 0.37 (0.06) 1.01 × 10 – 8
rs17830069 4 182415300 0.02 A –0.38 (0.07) 2.89 × 10 – 8
rs12137025 1 221938674 CAPN8, CAPN2 0.07 C 0.19 (0.03) 3.55 × 10 – 8

MAF, minor allele frequency; SE, standard error.



260J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

  Discussion 

 We report the results of a GWAS of serum α-carotene concentrations among a study 
sample that consumed a controlled diet. Three genome-wide significant associations were 
identified, though all three require further replication from independent studies and fine 
mapping to help determine the potential functional effects of these associations. The  CAPN2/
CAPN8  locus on chromosome 1 has the strongest evidence for association due to the associ-
ation being identified with relatively common genetic markers (MAF  ∼ 7%) and multiple 
SNPs. The other two loci, the  PRKCE  locus on chromosome 2 and the chromosome 4q34 locus, 
lack strong collaborating evidence from nearby SNPs. While having associated SNPs in strong 
linkage disequilibrium is not a requirement of a causal genetic determinant, it lends supporting 
statistical evidence for a meaningful association and lowers the probability of an association 
being identified due to genotype error. We were unable to replicate the association previ-
ously noted between a variant on  BCO1  and α-carotene concentrations. However, this is not 
surprising because this SNP was more strongly associated with β-carotene than α-carotene 
concentrations and did not have strong replicative evidence in the initial publication  [15] . 
GWAS performed on retinol, vitamin E (α-tocopherol, γ-tocopherol), and the other carot-

8

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Plotted SNPs

0.8

r2

0.6
0.4
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rs12137025

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SUSD4 CAPN8 CAPN2 FBXO28

DEGS1C1orf65 TP53BP2

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222.4222.2222.0221.8221.6
Position on chromosome 1 (Mb)

  Fig. 3.  Regional association plot of chromosome 1q41. The  x  axis represents the chromosomal position with 
the location of genes at the locus annotated. The left  y  axis shows the  p  value for association tests at each lo-
cus (dot) on the log scale. The right  y  axis provides recombination rates in centimorgans per megabase (cM/
Mb) in the chromosomal region identifying recombination hotspots in the region (blue line). The most sig-
nificantly associated variant in the region is indicated by a purple diamond. All other variants in the region 
are indicated with colored solid dots. The color reflects the linkage disequilibrium (measured in  r  2 ) between 
the variant and the top hit. Variants in high linkage disequilibrium ( r  2  > 0.8) are in red, variants in low link-
age disequilibrium are in dark blue ( r  2  < 0.2), with all other colors representing linkage disequilibrium in 
between (0.2  ≤   r  2   ≤  0.8), as described in the color legend in the upper left hand corner of the figure. 

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261J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

8

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Plotted SNPs

0.8

r2

0.6
0.4
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rs2594495

6

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PIGFEPAS1 LOC388946

RHOQ
CRIPT

PRKCE

ATP6V1E2

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46.646.446.246.045.8
Position on chromosome 2 (Mb)

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0.8

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rs17830069

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LINC00290

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182.4182.2182.0181.8
Position on chromosome 4 (Mb)

  Fig. 5.  Regional association plot of chromosome 4q34. See  Figure 3  for details. 

  Fig. 4.  Regional association plot of chromosome 2p2. See  Figure 3  for details. 

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262J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

enoids (β-carotene, lycopene, lutein, zeaxanthin, cryptoxanthin) assayed in this study revealed 
no other meaningful genetic associations, with the exception of lycopene  [25] .

  Our results introduce a potentially interesting relationship between  CAPN2/CAPN8 , 
α-carotene, and gastric cancer. Calpains are a group of calcium-sensitive cysteine proteases 
that are ubiquitously expressed in mammals. The calpain system has been shown to be 
dysregulated in cancer  [26] .  CAPN8  is a stomach-specific calpain whose expression is localized 
to gastric pit cells. Functioning  CAPN8  genes produce nCL-2, a cysteine protease essential for 
mucosal defense  [27] . Dysfunction of this protease and the pit cells in which they are expressed 
can lead to atrophic gastritis and metastatic gastric cancers  [28] . We determined that the 
genetic variant rs12137025, found near  CAPN8 , was associated with higher serum α-carotene 
concentrations. Higher levels of α-carotene have been shown to reduce the risk of atrophic 
gastritis, a precancerous condition associated with gastric cancer  [13] . Alpha-carotene 
protects the gastric mucosa by scavenging free radicals and preventing the initiation or prop-
agation of lipid peroxidation reactions  [29] . While our findings suggest that there could 
potentially be a relationship between dysfunction of  CAPN8 , lower circulating α-carotene 
concentrations, and gastric cancer mediated by reduced protection of the gastric mucosa 
from lipid peroxidation, this potential relationship will need to be evaluated in future studies.

  Interestingly, though the relationship noted between the  PRKCE  locus and α-carotene 
concentrations relies on a single SNP,  PRKCE  may also have implications in cancer as uncon-
trolled chronic activation of  PRKCE  has been shown to lead to malignant tumor development 
 [30] . Additional studies are clearly needed to confirm whether α-carotene concentrations 
play a role in mediating the oncogenic activity of these genes. The significant association on 
chromosome 4q34 is in a region with no obvious candidate genes. More work is required, and 
replication evidence needed, to verify this and all other associations reported here.

  There are several notable strengths of the study which may have resulted in successful 
identification of associated loci. This was the first GWAS aimed at identifying genetic associa-
tions with serum α-carotene concentrations that was conducted among participants who had 
consumed a controlled diet. While we did not assess serum micronutrient concentrations 
prior to the controlled diet, as determining the specific effects of this diet on α-carotene 
concentrations was beyond the scope of the current study, the controlled diet minimized the 
potential for confounding of the relationship between serum α-carotene and genetic variants 
due to differences in dietary intake among people consuming variable diets. The controlled 
diet enabled us to more closely isolate the genetic contributions to the variance in serum 
α-carotene. The diet was designed to be culturally appropriate, representative of the typical 
diet of our study population, and was delivered to study participants at their homes to support 
compliance. It should be noted that the controlled diet contained more α-carotene (1,724 μg), 
as is typical of the diet of our Old Order Amish study population, than that of the average adult 
population of the United States (451 μg), as expressed in the most recent publicly available 
National Health and Nutrition Examination Surveys data  [31] . Urinary excretion tests 
suggested that adherence to the controlled diet was excellent. The Old Order Amish study 
population also provided unique advantages in a study of this nature. The relationship 
structure of the Old Order Amish enabled us to perform the first estimate of the heritability 
of serum α-carotene concentrations in humans. The Old Order Amish are also a relatively 
homogenous population with respect to both genetics and lifestyle. The genetic homogeneity 
provided increased power to detect genetic variants associated with α-carotene, and the 
similar lifestyles further minimized potential sources of confounding of the study findings.

  There were also a number of key limitations to this study. The relatively small sample 
size ( n  = 433) provided power to detect associations of genetic variants with relatively large 
effect sizes only. Despite our relatively small sample size, our study was able to identify 3 
novel loci associated with serum α-carotene concentrations. We believe that these successes 



263J Nutrigenet Nutrigenomics 2016;9:254–264
 DOI: 10.1159/000452890 

 D’Adamo et al.: The  CAPN2/CAPN8  Locus on Chromosome 1q Is Associated with 
Variation in Serum Alpha-Carotene Concentrations 

www.karger.com/jnn
© 2016 S. Karger AG, Basel

may be attributable in part to the controlled diet administered to study participants prior to 
the blood draw and the relatively similar lifestyle habits of the Old Order Amish study popu-
lation which enabled us to more closely isolate the genetic contributions to serum α-carotene 
concentrations. While the novel association between a variant near  CAPN8  and serum 
α-carotene concentrations, both of which have been associated with gastritis and gastric 
cancer, may provide the rationale for further study into the specific mechanisms of this rela-
tionship, this study did not collect data on family history of gastric cancer or other markers 
of the disease, and thus no direct inference can be made. Bioinformatics analysis utilizing 
HaploReg demonstrated that some of the variants associated with α-carotene concentrations, 
or other variants in high linkage disequilibrium with them, have potential regulatory function 
by virtue of being associated with enhancer or promoter activity across multiple tissues. 
However, without more direct experimental evidence, it is not possible to ascribe a regulatory 
function of these SNPs to nearby genes (e.g.,  CAPN2  or  CAPN8 ), nor the nearby genes to regu-
lation of α-carotene concentrations.

  In summary, this was the first study to identify genome-wide significant associations 
with serum α-carotene concentrations. Three novel genome-wide associations were noted 
with serum α-carotene levels: the  CAPN2/CAPN8  locus,  PRKCE , and the chromosome 1q41 
locus. These findings suggest that genetics may influence serum concentrations of α-carotene. 
Further studies are needed to replicate these findings and to identify potential mechanisms 
underlying the relationships between the identified genetic loci, α-carotene concentrations, 
and clinical endpoints such as gastric cancer.

  Acknowledgments 

 This work was supported by the National Institutes of Health (U01 HL072515, P30 DK072488, R01 
AG27012, and T35 DK095737). The authors would also like to acknowledge the study participants for their 
partnership in research, the staff at the Amish Research Clinic for their collaboration, and Nga Hong Brereton, 
MS, RD, at Johns Hopkins University School of Medicine for designing the controlled diet in this study and 
evaluating its nutrient content.

  Disclosure Statement 

 The authors do not have any conflicts of interest to disclose.
 

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