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Cellular and Molecular Exercise Physiology
www.cellularandmolecularexercisephysiology.com 1 Aug 2012 ׀ Volume 1 ׀ Issue 1 ׀ e1
Sports genomics: Current state of knowledge and
future directions
Ildus I. Ahmetov1,2,3* and Olga N. Fedotovskaya2
1 Laboratory of Molecular Genetics, Kazan State Medical University, Kazan, Russia. 2 Sports Genetics Laboratory, St Petersburg Research Institute of Physical Culture, St Petersburg,
Russia. 3 Sport Technology Education Research Laboratory, Volga Region State Academy of Physical Culture, Sport and Tourism, Kazan, Russia.
Abstract
Athletic performance is a heritable trait influenced by both environmental and genetic factors. Sports genomics is a relatively new
scientific discipline focusing on the organization and functioning of the genome of elite athletes. With genotyping becoming widely
available, a large number of genetic case-control studies evaluating candidate gene variants have been published with largely
unconfirmed associations with elite athlete status. This review summarizes the evidence and mechanistic insights on the
associations between DNA polymorphisms and athletic performance. A literature search (period: 1997-2012; number of articles: 133)
revealed that at least 79 genetic markers are linked to elite athlete status (59 endurance-related genetic markers and 20
power/strength-related genetic markers). Importantly, we have identified 20 genetic markers (25.3%) that have shown positive
associations with athlete status in at least two studies (14 endurance-related genetic markers: ACE I, ACTN3 577X, ADRB2 16Arg,
AMPD1 Gln12, BDKRB2 –9, COL5A1 rs12722 T, GABPB1 rs7181866 G and rs12594956 A, HFE 63Asp, KCNJ11 Glu23, PPARA
rs4253778 G, PPARD rs2016520 C, PPARGC1A Gly482, UCP3 rs1800849 T; and 6 power/strength-related genetic markers: ACE
D, ACTN3 Arg577, AMPD1 Gln12, HIF1A 582Ser, NOS3 rs2070744 T, PPARA rs4253778 C). However, sports genomics is still in
the discovery phase and abundant replication studies are needed before these largely pioneering findings can be extended to
practice in sport. Future research including genome-wide association studies, whole-genome sequencing, epigenetic, transcriptomic
and proteomic profiling will allow a better understanding of genetic make-up and molecular physiology of elite athletes.
Citation: Ahmetov II, Fedotovskaya ON. (2012) Sports genomics: Current state of knowledge and future directions. 1(1): e1. doi:10.7457/cmep.v1i1.e1
Editor: Adam P Sharples
Received: Received Mar 27, 2012; Accepted Aug 23, 2012; Published Early View Oct 4, 2012; Published Final Version Oct 19, 2012.
Copyright: © 2012 Ahmetov II, Fedotovskaya ON. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits
unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Competing Interests: The authors have declared that no competing interests exist.
* E-mail: genoterra@mail.ru.
*Tel: +79655867625
* Current address: Laboratory of Molecular Genetics, Kazan State Medical University, Kazan, Russia.
Introduction
A wide variety of factors determines athletic success: genetics,
epigenetics, training, nutrition, motivation, advances in
equipment and other environmental factors. Genetics has a
great influence over components of the athletic performance
such as strength, power, endurance, muscle fibre size and
composition, flexibility, neuromuscular coordination,
temperament and other phenotypes. Accordingly, athlete status
is a heritable trait: Around 66% of the variance in athlete status
is explained by additive genetic factors. The remaining variance
is due to non-shared environmental factors (De Moor et al.,
2007). Despite a relatively high heritability of athlete status, the
search for genetic variants contributing to predisposition to
success in certain types of sport has been a challenging task.
Sports genomics is a relatively new scientific discipline focusing
on the organization and functioning of the genome of elite
athletes. The era of sports genomics began in the early 2000s
after deciphering the human DNA structure and discovery of first
genetic markers associated with athletic performance (e.g. ACE,
ACTN3 and AMPD1 gene variations). With genotyping
becoming widely available, a large number of genetic case-
control studies evaluating candidate gene variants have been
published with largely unconfirmed associations with elite
athlete status. Case-control studies remain the most common
study design in sports genomics and generally involve
determining whether one allele of a DNA sequence (gene or
non-coding region of DNA) is more common in a group of elite
athletes than it is in the general population, thus implying that
the allele boosts performance. Cross-sectional association
studies are another type of study design in sports genomics and
examine whether individuals with one genotype (or allele) of a
particular DNA sequence show different measures of a trait (e.g.
VO2max, strength measures etc.) compared to the rest of the
sample. A large body of evidence suggests that genetic markers
may explain, in part, an inter-individual variability of physical
performance characteristics in response to endurance or
strength training (reviewed in Ahmetov and Rogozkin, 2009;
Bray et al., 2009). DNA variations (with the frequency in the
population of 1% or greater) and rare DNA mutations generally
can be classified as genetic markers associated with endurance
or power/strength athlete status, or both with endurance and
strength/power athlete status. The significance of a particular
sport-related genetic marker is based on several criteria, such
as the type of the polymorphism (missense, nonsense, intronic
etc.), its frequency in a given population, number of case-control
and cross-sectional studies with positive or negative
(controversial) results, total number of studied athletes, etc.
Figure 1 presents the cumulative number of published articles
containing genotyping data of athletes from 1997 to 2012. By
the end of June 2012 the total number of articles in relation to
sports genomics was 133. As the figure shows, most of these
articles (73.7%) were published in the last six years (2007-2012),
indicating a growing interest in the field of sports genomics. The
Genes for athletic performance
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search for relevant publications was primarily based on the
journals indexed in PubMed and Google Scholar using a
combination of key words (e.g., athletes, sport, exercise,
physical performance, endurance, power, strength, training,
gene, genetics, genotype, polymorphism, mutation). However,
not all articles were included in the current review due to
language limitations, i.e., there were many more papers
published in Chinese, German, Lithuanian, Russian, Spanish,
Ukrainian and other languages. It should be noted that to date,
the research in relation to sports genomics was done by
laboratories located in at least 27 countries (Australia, Belarus,
Brazil, China, Finland, Germany, Greece, India, Israel, Italy,
Japan, Lithuania, Netherlands, Poland, Portugal, Republic of
Korea, Russia, Singapore, Slovenia, South Africa, Spain,
Sweden, Taiwan, Turkey, UK, Ukraine and USA). Furthermore,
articles describing performance-associated polymorphisms
investigated in the non-athletic cohorts were excluded from the
current review. For example, variation in the candidate gene
insulin-like growth factor-I (IGF1) has been associated with the
quadriceps-muscle strength gains in a 10-wk unilateral strength-
training study (Kostek et al., 2005). Since this gene variant was
analyzed in 67 older inactive Caucasian men and women, IGF1
was not included in our review.
Figure 1. Growth in the number of published articles in relation to sports genomics each year from 1997 to 2012 (June)
A literature search revealed that at least 79 genetic markers
(located within 40 autosomal genes, mitochondrial DNA and Y-
chromosome) are linked to elite athlete status (listed below).
These include 59 endurance-related genetic markers and 20
power/strength-related genetic markers (Tables 1-2).
Importantly, we have identified 20 genetic markers (25.3%) that
have shown positive associations with athlete status in at least
two studies (14 endurance-related genetic markers: ACE I,
ACTN3 577X, ADRB2 16Arg, AMPD1 Gln12, BDKRB2 –9,
COL5A1 rs12722 T, GABPB1 rs7181866 G and rs12594956 A,
HFE 63Asp, KCNJ11 Glu23, PPARA rs4253778 G, PPARD
rs2016520 C, PPARGC1A Gly482, UCP3 rs1800849 T; and 6
power/strength-related genetic markers: ACE D, ACTN3 Arg577,
AMPD1 Gln12, HIF1A 582Ser, NOS3 rs2070744 T, PPARA
rs4253778 C). Interestingly, almost all chromosomes (except for
13, 16, 18, 20 and X chromosomes) include sport-related
genetic markers.
Gene variants for endurance athlete status
ACE I allele
Circulating angiotensin I converting enzyme (ACE) exerts a
tonic regulatory function in circulatory homeostasis, through the
synthesis of vasoconstrictor angiotensin II, which also drives
aldosterone synthesis, and the degradation of vasodilator kinins.
A polymorphism in intron 16 of the human ACE gene (location:
17q23.3) has been identified in which the presence (insertion, I
allele) rather than the absence (deletion, D allele) of a 287 bp
Alu-sequence insertion fragment is associated with lower serum
and tissue ACE activity (reviewed in Puthucheary et al., 2011).
An excess of the I allele has been associated with some
aspects of endurance performance, being identified in 34 elite
British ≥5,000 m distance runners (Myerson et al., 1999) and 25
elite mountaineers (Montgomery et al., 1998). In addition, a
greater frequency of the I allele was present in elite Australian
(n = 64) (Gayagay et al., 1998), Croatian (n = 40) (Jelakovic et
al., 2000) and Russian (n = 107) (Ahmetov et al., 2008e) rowers
as well as Spanish elite athletes (25 cyclists, 20 long-distance
runners, 15 handball players) (Alvarez et al., 2000). ACE I allele
was also over-represented among 100 fastest Ironman
triathletes (Collins et al., 2004), 27 elite Spanish runners (Lucia
et al., 2005b), successful marathon runners (finishing in places
between 1st to 150th) (Hruskovicová et al., 2006), 35 outstanding
Russian middle-distance athletes (24 swimmers, 7 track-and-
field endurance athletes, 4 cross-country skiers) (Nazarov et al.,
2001), 33 Italian Olympic endurance athletes (10 road cyclists, 7
track-and-field runners, 16 cross-country skiers) (Scanavini et
al., 2002), 80 Turkish endurance and power/endurance athletes
(17 middle-distance runners, 10 basketball, 18 handball, 35
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football players) (Turgut et al., 2004), 16 long-distance (25 km)
swimmers from different nationalities (Tsianos et al., 2004), 55
elite Polish rowers (Cieszczyk et al., 2009), 108 Japanese
university long distance runners (Min et al., 2009) and 29 Indian
Army triathletes (Shenoy et al., 2010). An excess frequency of
the ACE I allele or II genotype in endurance-oriented athletes
may be partly explained by a genotype-dependent improvement
in skeletal muscle mechanical efficiency with training (Williams
et al., 2000), association of the ACE II genotype with an
increased percentage of slow-twitch type I fibres in human
skeletal muscle (Zhang et al., 2003), higher VO2max in athletes
and non-athletes (Goh et al., 2009; Hagberg et al., 1998), higher
aerobic work efficiency (Zhang et al., 2008), improved fatigue
resistance (Montgomery et al., 1998), higher peripheral tissue
oxygenation during exercise (Kanazawa et al., 2002), greater
aerobic power response to training (Defoor et al., 2006),
improved hypoxic ventilatory response (Patel et al., 2003),
adherence to exercise training (Thompson et al., 2006) and
greater cardiac output and maximal power output in athletes
(Ahmetov et al., 2008e, Hagberg et al., 2002). It should be
noted that several studies have demonstrated no association
between the ACE I/D polymorphism and endurance athlete
status (Ash et al., 2011; Tobina et al., 2010; Ahmetov et al.,
2009b; Papadimitriou et al., 2009; Scott et al., 2005; Rankinen
et al., 2000b; Taylor et al., 1999) or prevalence of the D allele
(or low proportion of the II genotype) in endurance-oriented
athletes in comparison with controls (Ginevičienė et al., 2010;
Muniesa et al., 2010; Amir et al., 2007; Lucia et al., 2005b).
Furthermore, Tobina et al. (2010) had shown that average
running speed was significantly higher for those Japanese
endurance runners with the combined DD/ID genotypes than for
those with the II genotype.
ADRA2A 6.7-kb allele
The α-2A-adrenergic receptor (ADRA2A) plays a central role in
the regulation of systemic sympathetic activity and hence
cardiovascular responses such as heart rate and blood pressure.
The restriction enzyme DraI identifies a restriction fragment
length polymorphism in the 3’-untranslated region (3’-UTR)
(6.7/6.3 kb polymorphism) of the ADRA2A gene (location:
10q24-q26). Wolfarth et al. (2000) have observed a significant
difference in genotype distributions between elite endurance
athletes (148 Caucasian male subjects) and sedentary controls
(149 unrelated sedentary male subjects). A higher frequency of
the 6.7-kb allele was found in athletes compared with the
sedentary controls group. It was concluded that genetic
variation in the ADRA2A gene or a locus in close proximity may
play a role in being able to sustain the endurance training
regimen necessary to attain a high level of maximal aerobic
power (Wolfarth et al., 2000).
ADRB2 16Arg allele
The β-2 adrenergic receptor (encoded by ADRB2; location:
5q31-q32) is a member of the G protein-coupled receptor
superfamily, expressed in many cell types throughout the body
and plays a pivotal role in the regulation of the cardiac,
pulmonary, vascular, endocrine and central nervous system.
The Gly16Arg single nucleotide polymorphism (SNP)
(rs1042713 G/A) of the ADRB2 gene and its association with
several phenotypes has been described. Specifically, the 16Arg
allele was associated with lower receptor density and resting
cardiac output (Snyder et al., 2006). Wolfarth et al. (2007b)
reported that the 16Arg allele was over-represented in 313 white
male elite endurance athletes compared to 297 white male
sedentary controls, suggesting a positive association between
the tested Gly16Arg polymorphism and endurance performance.
Furthermore, in a study of 316 Mount Olympus marathon
runners Tsianos et al. (2010) had shown an association
between the 16Arg allele and the fastest time of athletes. The
results of these studies were in agreement with the previous
work in which an association of the 16Arg allele with higher
peak VO2 in heart failure patients was reported (Wagoner et al.,
2000).
ADRB3 64Arg allele
The β-3 adrenoreceptor (ADRB3) belongs to the family of
adrenergic receptors, which are involved in adenylate cyclase
activation through the action of G proteins. Molecular studies
had shown that ADRB3 is mainly expressed in adipocytes,
though in vitro studies with ADRB3 agonists have demonstrated
the presence of its activity in skeletal muscle and myocardium
(Chamberlain et al., 1999; Lipworth, 1996). The β-3
adrenoreceptor was also found in the human heart (Skeberdis
et al., 2008; Gauthier et al., 1996). ADRB3 is involved in the
regulation of lipolysis and thermogenesis in adipose tissue
(Lowell and Bachman, 2003) and cardiac contractility
(Skeberdis et al., 2008; Gauthier et al., 1996). The human
ADRB3 gene has been localized to chromosome 8 (8p12-
8p11.1). The Adrb3 gene knockout mice showed marked
reductions in lipolysis stimulated by β-3 agonists (Susulic et al.,
1995). Trp64Arg (rs4994 T/C) variant in the ADRB3 gene was
reported to influence the receptor's affinity to norepinephrine
and its interaction with G protein in adipocytes (Walston et al.,
1995). Studies on isolated adipocytes showed that the ADRB3
gene Trp64Arg polymorphism results in a lower lipolytic activity
(Umekawa et al., 1999). This missense polymorphism was
shown to be associated with hypertension (Ringel et al., 2000),
early onset of type 2 diabetes mellitus, lower metabolic rate
(Walson et al., 1995), obesity and BMI (Chou et al., 2012; Malik
et al., 2011; Kurokawa et al., 2008; Kim et al., 2006; Hao et al.,
2004; Clement et al., 1995), pathogenesis of gout (Wang et al.,
2011) and hyperuricemia (Morcillo et al., 2010). In a study of 36
Japanese middle-aged males, the ADRB3 gene Trp64Arg
polymorphism was shown to influence metabolic syndrome
improvement rate by exercise-based intervention program
(Tahara et al., 2011). Recently, Kim et al. (2010b) have
demonstrated a significant association between the ADRB3
gene Trp64Arg polymorphism and some cardiovascular
parameters (serum HDL-cholesterol and glucose levels) in a
study of 81 Korean athletes from different sporting disciplines.
However, there were no significant differences in allelic
frequency between athletes and controls (n = 33). Santiago et al.
(2011) compared genotype frequencies of the ADRB3 Trp64Arg
variation in 153 elite Caucasian Spanish athletes (100 world-
class endurance athletes; runners and cyclists, and 53 power
athletes; sprinters, jumpers and throwers) and 100 non-athletic
controls. Endurance athletes had a higher 64Arg allele
frequency comparing with controls (14.0% vs. 4.0%, P = 0.001).
There was higher percentage of 64Arg allele carriers (carriers of
Trp/Arg and Arg/Arg genotypes) among endurance athletes in
comparison with non-athletic controls (27.0% vs. 8.0%, P <
0.001). It was concluded that heterozygosity for the ADRB3
Trp64Arg polymorphism seems to be associated with elite
endurance performance in Spanish athletes.
AQP1 rs1049305 C allele
Aquaporins are a family of small integral membrane proteins
related to the major intrinsic protein (MIP or AQP0). The
Aquaporin-1 (AQP1) is the best known and most studied of this
family. AQP1 gene (location: 7p14) encodes for a protein
responsible for transporting large amounts of water across cell
membranes (Verkman, 2005). AQP1 has been identified in
various tissues, including red blood cells, endothelial cells, as
well as smooth, skeletal and cardiac muscle (Butler et al., 2006;
Au et al., 2004). During osmotic stress, such as occurs during
intense exercise, AQP1 facilitates the transfer of water from the
blood into the muscle (Frigeri et al., 2004), provides osmotic
protection, and promotes water reabsorption. Recently,
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Martínez et al. (2009a) have examined the association between
AQP1 gene rs1049305 C/G polymorphism (in the 3’
untranslated region) and athletic performance in 784 Hispanic
international level marathon runners. Athletes were divided into
two groups: 1) Cases (n = 396), finished in the top 3rd tertile for
their age and gender; 2) controls (n = 388), finished in the
lowest 3rd tertile. The frequency of the rare C allele was
significantly higher in cases than in controls (36.0% vs. 30.0%;
P = 0.005). In a following study of 91 international 10 km
runners, the same group of authors have demonstrated that
carriers of the AQP1 rs1049305 C allele had a significantly
greater body fluid loss (3.7 ± 0.9 kg) than non-carriers (1.5±1.1
kg) (P < 0.05) (Rivera et al., 2011).
AMPD1 Gln12 allele
Adenosine monophosphate deaminase 1 (AMPD1) catalyzes
the deamination of adenosine monophosphate to inosine
monophosphate in skeletal muscle. Deficiency of the AMPD1 is
apparently a common cause of exercise-induced myopathy and
probably the most common cause of metabolic myopathy in the
human. In the overwhelming majority of cases, AMPD1
deficiency is due to a 34C/T transition in exon 2 (rs1760272934
C/T) of the AMPD1 gene (location: 1p13), which creates a
nonsense codon (Gln12X) that prematurely terminates
translation. AMPD1 deficiency individuals exhibit a low AMP
deaminase activity and reduced submaximal aerobic capacity
(VO2 at the ventilatory threshold) (Rubio et al., 2008). In a study
of Rico-Sanz et al. (2003), subjects with the AMPD1 XX
genotype had diminished exercise capacity and
cardiorespiratory responses to exercise in the sedentary state.
Furthermore, the training response of ventilatory phenotypes
during maximal exercise was more limited in XX (Rico-Sanz et
al., 2003). In a study of 935 coronary artery disease patients the
carriers of the X allele had a significantly lower relative increase
in peakVO2 after three months of aerobic training (Thomaes et
al., 2011). Finally, two studies reported low frequency of the
mutant X allele in a group of top-level Spanish male endurance
athletes (cyclists and runners, n = 104) (Rubio et al., 2005) and
127 Polish rowers (Cieszczyk et al., 2011c) compared with
controls.
BDKRB2 –9 and rs1799722 T alleles
Bradykinin is a potent endothelium-dependent vasodilator and
acts via the bradykinin B2 receptor (encoded by BDKRB2;
location: 14q32.1-q32.2). The absence (–9), rather than the
presence (+9), of a 9 bp repeat sequence in exon 1 has
previously been shown to be associated with increased gene
transcription and higher BDKRB2 mRNA expression. Williams et
al. (2004) had shown that the –9 allele of the BDKRB2 gene
was associated with higher efficiency of muscular contraction
(i.e. the energy used per unit of power output during exercise or
delta efficiency). In 81 elite British runners, analysis revealed a
linear trend of increasing –9 allele frequency with distance
running. The proportion of –9 alleles increased from 0.382 to
0.412 to 0.569 for those athletes running ≤200 m, 400–3,000 m,
and ≥5,000 m, respectively (Williams et al., 2004). The –9/–9
genotype of the BDKRB2 gene was also over-represented in
male Caucasian triathletes (n = 443) of the 2000 and 2001
South African Ironman Triathlons compared to male controls (n
= 203) (Saunders et al., 2006). Additionally, when divided into
tertiles according to their finishing times, the –9/–9 genotype
was only over-represented in the fastest tertile. However, Eynon
et al. (2011a) found no significant differences in the frequencies
of the –9 allele and –9/–9 genotype between 74 Israeli
endurance athletes and 240 controls. Furthermore, Tsianos et al.
(2010) have reported an excess of the TT genotype of the
BDKRB2 gene rs1799722 C/T polymorphism in 316 male Mount
Olympus marathon runners.
Calcineurin/NFAT-related genetic markers (NFATC4 Gly160,
PPP3CA rs3804358 C, PPP3CB rs3763679 C and PPP3R1 5I
alleles)
Calcineurin (also known as protein phosphatase 3) is a Ca2+-
and calmodulin-dependent serine/threonine protein
phosphatase. It is found in all tissues in mammals and even at
relatively low levels participates in a variety of cellular processes,
Ca2+-dependent signal transduction pathways and contributes to
genetic programs in muscle (Rusnak and Mertz, 2000;
Aramburu et al., 2001). Activated calcineurin dephosphorylates
the NFATs, leading to their nuclear translocation and
subsequent transcriptional activation of NFAT target genes
(Hogan et al., 2003; Klee et al., 1998). Calcineurin-NFAT
signaling pathway has been proposed to regulate skeletal
muscle differentiation and hypertrophy, and fibre type
composition, which leads to different cardiac and skeletal
muscle phenotypes (Sakuma and Yamaguchi, 2010).
Calcineurin is a heterodimer of a calmodulin-binding catalytic
subunit, calcineurin A, tightly bound in the presence of elevated,
but physiological concentrations of Ca2+ to a regulatory, Ca2+-
binding regulatory subunit, calcineurin B (Klee et al., 1998). In
humans three isoforms of calcineurin A (Aα, Aβ, Aγ) and two
isoforms of calcineurin B (B1, B2) are expressed from separate
genes – PPP3CA (location: 4q24), PPP3CB (location: 10q22.2),
PPP3CC (location: 8p21.3), PPP3R1 (location: 2p15) and
PPP3R2 (location: 9q31.1), respectively (Hogan et al., 2005).
He et al. (2010a,b) conducted two association studies of 55
polymorphisms in 5 genes encoding the calcineurin protein
subunits in a group of 102 healthy young Chinese men of Han
origin with VO2max, running economy and echocardiographic
variables measured before and after 18-week endurance
training program. Results showed significant association
between the PPP3CB gene rs3763679 C/T polymorphism with
resting heart rate and PPP3CA gene rs2850965 G/T and
rs3804423 A/G polymorphisms with baseline VO2max. As for
genotype associations with endurance trainability, there were
significant associations between a) PPP3CC gene rs1879793
C/T, rs1075534 A/G, rs7430 C/G, rs2461483 C/T, and
rs10108011 A/G polymorphisms and cardiac output/stroke
volume after exercise, b) PPP3R2 gene rs1407877 A/G
polymorphism and ejection fraction at 50 W, c) training
responsiveness of VO2max and PPP3CA gene rs3804358 C/G
polymorphism and PPP3R1 gene rs4671887 A/C polymorphism;
d) training responsiveness of running economy and PPP3R2
gene rs3739723 A/T polymorphism (He et al., 2010a). In
another study of the same 55 calcineurin gene polymorphisms
in 123 elite runners (62 men and 61 women) and 125 healthy
Han Chinese non-athletes (69 men and 56 women) the
PPP3CA gene rs3804358 C/G and rs3763679 C/T
polymorphisms were shown to be associated with elite
endurance athlete status. Athletes had higher PPP3CA
rs3804358 C (17 vs. 8%; P = 0.003) and PPP3CB rs3763679 C
(77.0 vs. 63.0%; P = 0.001) allele frequencies comparing with
non-athletes (He et al., 2010b). However, these associations
were not replicated in a study of Caucasian (Spanish) elite male
endurance athletes (n = 100) and non-athletic male controls (n =
175) (He et al., 2011). It should be noted that the luciferase
reporter constructs containing C alleles of the rs3804358 and
rs3763679 polymorphisms produced significantly greater
luciferase activity than that of the G or T alleles, respectively
(He et al., 2011). Tang et al. (2005) had shown that the 5-bp
deletion (5D) allele of 5I/5D polymorphism within the PPP3R1
promoter region may cause excessive left ventricular (LV)
growth beyond the level appropriate for cardiac workload when
exposed to severe hypertension. In a study of Russian rowers,
5D allele of the PPP3R1 gene has been reported to be
associated with greater LV mass index both in males and
females, and with lower values of maximal power output and
VO2max (Ahmetov et al., 2008c). In addition, the frequency of the
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5I allele was found to be significantly higher in 694 Russian
endurance-oriented athletes in comparison with 1,132 controls
(Ahmetov et al., 2009b). Nuclear factor of activated T-cell,
calcineurin-dependent 4 (NFATC4) is a transcription factor that
regulates cardiac hypertrophy, muscle fibre composition,
glucose and lipid homeostasis, mitochondrial biogenesis and
hippocampal neuronal signaling (Molkentin 2000; Xia et al.,
2000; Moore et al., 2001; Hogan et al., 2003; Benedito et al.,
2005; Yang et al., 2006; Ahmetov et al., 2012b). NFATC4 gene
(also known as NFAT3; location: 14q11.2) Gly160Ala
polymorphism (rs2229309 G/C) was shown to be associated
with indexes of cardiac hypertrophy (Poirier et al., 2003).
Specifically, a lower mean of left ventricular mass and wall
thickness were observed in carriers of the NFATC4 160Ala
allele. In a study of 1,423 Russian athletes, the frequency of the
Gly160 allele of the NFATC4 gene was significantly higher in
endurance-oriented athletes (n = 694) than in the control group
(n = 1,132) (Ahmetov et al., 2009b). Furthermore, NFATC4 Gly
allele was associated with high values of aerobic performance
(VO2max and AT in % of VO2max values) both in male and female
Russian rowers (Popov et al., 2008).
CKM rs8111989 A allele
The muscle isoform of creatine kinase (CKM) is a key enzyme
of energy supply for muscle. In contracting muscles ADP
formation triggers the creatine kinase mechanism of anaerobic
ATP resynthesis which provides rephosphorylation between
creatine phosphate and ADP. CKM is encoded by the CKM
gene (also known as CKMM; location: 19q13.2–13.3). Ckm
knockout mice have an enhanced aerobic performance and a
lower fatigability after long term physical activity (Van Deursen
et al., 1993). The rs8111989 A/G CKM gene polymorphism in
the 3’UTR was shown to be associated with physical
performance. In a study of 160 Caucasian parents and 80 adult
offspring of the HERITAGE Family Study, the aerobic
performance was associated with CKM genotype (Rivera et al.,
1997a). VO2max was measured during cycle ergometry tests
before and after 20 wk of endurance training. CKM genotype in
parents was significantly associated with VO2max. A significantly
lower VO2max response to endurance training program was
detected in parents and offspring with CKM GG genotype. In a
following study, Rivera et al. (1999) have confirmed these
results in 277 full sib pairs from 98 Caucasian families. The
association study of 102 male volunteers from northern China
revealed significant association between the A/G CKM gene
polymorphism and running economy response to endurance
training (Zhou et al., 2006). AG genotype carriers showed larger
running economy response than those with AA and GG
genotypes. Furthermore, Heled et al. (2007) have demonstrated
association between the A/G CKM gene polymorphism and
susceptibility to exertional rhabdomyolysis. However, VO2max at
baseline and VO2max response to physical training were not
different across the CKM genotypes among 927 biologically
unrelated Caucasian patients with coronary artery disease
(Defoor et al., 2005). The first case-control study of 124
Caucasian male elite endurance athletes and 115 unrelated
Caucasian sedentary male controls found no association of A/G
CKM gene polymorphism with elite endurance athlete status
(Rivera et al., 1997b). The study of 380 Hispanic marathon
runners also revealed that the A/G CKM gene variation was not
a determinant of endurance performance (Martínez et al.,
2009b). The same lack of association between the CKM
genotype and athletic status was found in a study of 50 top-level
professional cyclists, 27 elite runners and 119 sedentary
controls from Spain (Lucia et al., 2005b). However results of
case-control study of 384 Russian athletes and 1116 non-
athletic controls showed that CKM A allele and AA genotype
carriers were more frequent among endurance athletes (n = 176)
than in controls (P = 0.0003), while GG genotype was more
prevalent in weightlifters (n = 74) compared to control subjects
(31.1% vs. 13.4%; P = 0.0001). Furthermore, the CKM AA
genotype was associated with higher values of VO2max (n = 85,
P = 0.0097) in a group of rowers (Fedotovskaya et al., 2012b). It
should be noted that Döring et al. (2011) by studying other CKM
gene polymorphisms (rs344816, rs10410448, rs432979,
rs1133190, rs7260359, rs7260463 and rs4884) in 316 male
Caucasian elite endurance athletes and 304 sedentary controls
found no association with athlete status.
Collagen-related genetic markers (COL5A1 rs12722 T and
COL6A1 rs35796750 T alleles)
Collagens are a group of extracellular matrix proteins, and are
the most abundant proteins in mammals, making up about 25%
to 35% of the whole-body protein content. Collagens, in the form
of elongated fibrils, are mostly found in connective (fibrous)
tissues such as tendon, ligament and skin, and are also
abundant in cornea, cartilage, bone, blood vessels, the gut, and
intervertebral disc. Collagens have a triple-helical domain as
their common structural element. The COL5A1 gene (location:
9q34.2-q34.3) encodes the pro-α1 chain of type V collagen, the
rate-limiting component of the of type V collagen trimer
assembly. Heterotypic collagen I/V interactions are believed to
regulate the fibril diameter and fibril number in vitro (Wenstrup
et al., 2004). The COL5A1 gene rs12722 C/T polymorphism has
recently been shown to be associated with passive straight leg
raise and/or a sit-and-reach measurement (the carriers of the
rs12722 T allele were more inflexible) (Brown et al., 2011b;
Collins et al., 2009). Since data suggest that inflexibility
improves running performance, possibly through enhancing the
storage and return of energy and minimizing the need for
muscle-stabilizing activity (Craib et al., 1996), it was
hypothesized that the rs12722 T allele would associate with
improved running performance. Indeed, in a study of 313
Caucasian Ironman triathletes Posthumus et al. (2011) haв
shown that participants with a TT genotype completed the
running component (42.2-km) of the race significantly faster
than individuals with a CC genotype (TT: 294.2 ± 52.1 min, CC:
307.4 ± 48.6 min; P = 0.019). These results were then replicated
in a second association study with 72 ultra-marathon runners
(56-km): Participants with a TT genotype completed the ultra-
marathon significantly faster than participants with TC and CC
genotypes (TT: 341 ± 41 min, TC+CC: 365 ± 39 min; P = 0.014).
Furthermore, when the cohort was divided into performance and
flexibility quadrants, the rs12722 T allele was significantly over-
represented within the fast and inflexible quadrant (Brown et al.,
2011a). The function of type VI collagen remains largely
unknown; however, it is believed to play a role at the basement
membrane. Mutations within the gene which encodes the α1
chain of type VI collagen (COL6A1; location: 21q22.3) have
been shown to cause muscle diseases such as Bethlem
myopathy and Ullrich congenital muscular dystrophy. In addition,
Col6a1 knockout mice were shown to have impaired running
performance and reduced muscle strength (Bonaldo et al.,
1998). In a study with 661 Caucasian Ironman triathletes,
O'Connell et al. (2011) had shown that participants with the
COL6A1 TT genotype of the rs35796750 T/C polymorphism
were significantly faster during the bike and overall race. When
participants were grouped into fast, middle and slow bike
finishing time tertiles, there was a significant linear trend for the
TT genotype (fast: 35.7%; middle: 29.0%; slow: 23.8%; P =
0.008) (O'Connell et al., 2011).
EPAS1 rs1867785 G and rs11689011 T alleles
Endothelial PAS domain protein 1 (EPAS1) is a hypoxia-
inducible transcription factor and plays an important role in the
catecholamine and mitochondrial homeostasis, in the control of
cardiac output and erythropoietin regulation. Recently,
Henderson et al. (2005) have investigated the frequencies of the
EPAS1 (also known as HIF2A; hypoxia-inducible factor 2α;
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location: 2p21-p16) gene variants in elite endurance athletes.
The frequencies of the G (rs1867785 A/G) and T (rs11689011
C/T) alleles located within the large intron 1 of the EPAS1 gene
tended to be higher in short (event duration no less than 50 s),
middle (from 50 s to 10 min) and long (from ~2 to 10 h) distance
Australian endurance athletes in comparison with 444 controls.
They have also identified three EPAS1 haplotypes to be
significantly associated with elite endurance athletes classified
according to the power-time model of endurance. The presence
of one (haplotype G: A-T-G-G) and the absence of another
(haplotype F: G-C-C-G) at the same locus was observed in
athletes involved in high intensity maximal exercise of a duration
between 50 s and 10 min. In addition, athletes involved in a
sustained steady-state effort (from ~2 to 10 h) demonstrated the
increased presence of a third (haplotype H: A-T-G-A)
(Henderson et al., 2005).
GABPB1 rs12594956 A, rs8031031 T and rs7181866 G
alleles
The GA binding protein transcription factor, β subunit 1
(GABPB1; also known as NRF2; nuclear respiratory factor 2)
protein is a transcriptional regulator of genes involved in
activation of cytochrome oxidase expression and nuclear control
of mitochondrial function. There was evidence that increase in
NRF2 represented key regulatory component of the stimulation
of mitochondrial biogenesis by exercise (Baar et al., 2002).
Mitochondrial transcription factor A (TFAM), cytochrome c and
heme biosynthesis proteins were shown to be regulated by
NRF2 (Gleyzer et al., 2005). It was shown that polymorphisms
of the GABPB1 gene (location: 15q21.2) may explain variance
in endurance capacity and affect elite endurance performance.
More specifically, He et al. (2007) examined the association
between the GABPB1 genotypes and endurance capacity
(running economy and VO2max) measured prior to and after
endurance training program in young Chinese men. At baseline
there was an association between the VO2max and GABPB1
rs12594956 A/C polymorphism. Training response of VO2 at
running economy was associated with GABPB1 rs12594956
A/C, rs8031031 C/T and rs7181866 A/G polymorphisms, and
individuals carrying the A-T-G haplotype had 57.5 % elevated
running economy in response to 18-wk endurance training than
non-carriers. In two studies involving 155 Israeli athletes and
240 non-athletes Eynon et al. (2009d; 2010b) have analyzed the
distribution of three GABPB1 SNPs (rs12594956 A/C,
rs8031031 C/T and rs7181866 A/G). The frequencies of the
rs12594956 AA, rs8031031 CT and rs7181866 AG genotypes
were significantly higher in endurance-oriented athletes (n = 74)
than in sprinters (n = 81) or controls. In a following study, Eynon
et al. (2012) had shown that the frequency of the AA genotype
of the rs12594956 A/C polymorphism was significantly higher in
89 Spanish world-class endurance athletes compared with 38
power athletes (P < 0.01) and 110 controls (P < 0.01) (48% vs.
13% and 21%, respectively). However, the frequencies of the
rs8031031 and rs7181866 polymorphisms did not differ
between endurance athletes and controls. Furthermore,
Maciejewska-Karlowska et al. (2012) confirmed the association
between the rs7181866 A/G polymorphism and endurance
athlete status, that is the proportion of the AG genotype was
significantly higher in 55 Polish male rowers in comparison with
130 controls (10.9% vs. 2.3%; P = 0.012).
GNB3 rs5443 T allele
Heterotrimeric guanine nucleotide-binding proteins (G proteins)
transduce binding of numerous ligands such as hormones,
neurotransmitters, chemokines, local mediators, and sensory
stimuli to G protein-coupled receptors into intracellular
responses, which underlie physiological responses of tissues
and organisms (Hamm, 1998). By integrating signals between
receptors and effector proteins, G proteins play important roles
in determining the specificity of the cellular responses to signals.
G proteins consist of alpha, beta, and gamma subunits, which
are encoded by families of related genes. The GNB3 gene
(location: 2p13) encodes guanine nucleotide-binding protein
subunit beta 3.The C825T polymorphism in exon 10 (rs5443
C/T) of the GNB3 gene was shown to be associated with
essential hypertension and body fatness (Bray, 2008; Danoviz
et al., 2006; Zhu et al., 2006; Hegele et al., 1999; Siffert et al.,
1998). The T allele was associated with the occurrence of a
biologically active GNB3 splice variant with deleted nucleotides
498−620 of exon 9, which causes loss of 41 amino acids in beta
subunit of G protein and enhances G protein activation (Siffert
et al., 1998). In a study of 95 healthy African American
university students significant association of the rs5443 T allele
with peak oxygen consumption was observed (Faruque et al.,
2009). The GNB3 C825T polymorphism plays a role in the heart
rate and body fatness regulation in African Americans and in
responsiveness of resting blood pressure to endurance training
in African Amercian women (Rankinen et al., 2002). Recently,
Eynon et al. (2009c) have determined the frequencies of GNB3
C825T genotypes among 155 elite Israeli athletes (119 men and
36 women; 74 long-distance runners and 81 sprinters) and 234
healthy non-athletic controls. There was a significant difference
in GNB3 genotype frequencies between endurance athletes and
sprinters (P = 0.045) as well as between endurance athletes
and controls (P = 0.046). The proportion of the TT genotype was
significantly higher in the group of endurance athletes (18.9%)
than in sprinters (4.9%, P = 0.014) and controls (8.5%, P =
0.026). These results were even more pronounced when the
subgroups of 20 top-level endurance athletes (50.0%) and 24
top-level sprinters (4.0%, P = 0.0009) were compared. However,
when cohorts of athletes and controls from Israeli and Spanish
populations were combined (155 Israeli and 153 Spanish
athletes; 240 Israeli and 100 Spanish controls), no significant
differences in genotypic and allelic frequencies between
countries or groups were observed (Ruiz et al., 2011).
HFE 63Asp allele
Hereditary hemochromatosis is an autosomal recessive disease
in which the body’s iron stores are increased (Bothwell and
MacPhail, 1998.). The hemochromatosis (HFE) gene (location:
6p21.3) plays a major role in hereditary hemochromatosis. The
HFE protein functions to regulate iron absorption by regulating
the interaction of the transferrin receptor with transferrin. Most
patients with the manifest of hereditary hemochromatosis are
homozygous for the Cys282Tyr mutation, and a small proportion
are heterozygous for both the Cys282Tyr and His63Asp
(rs1799945 C/G or H63D) mutation of the HFE gene. The HFE
gene His63Asp polymorphism was shown to be associated with
blood iron indices (subjects with one or more mutations show
higher blood iron concentrations and transferrin saturation than
subjects without mutations) (Burt et al., 1998). Furthermore,
Valenti et al. (2008) have demonstrated that HFE mutations
reduce the amount of recombinant human erythropoietin and
iron necessary to support erythropoiesis in hemodialysis.
Interestingly, Deugnier et al. (2002) had shown an increased
frequency of the 63Asp allele in 83 elite French road male
cyclists when compared to controls (P = 0.04). Consistently, in a
second study of 65 elite endurance-oriented Spanish athletes
(50 professional road cyclists and 15 Olympic class endurance
runners) Chicharro et al. (2004) had found that the frequency of
the His/Asp genotype was significantly higher in athletes in
comparison with 134 controls (41.5% vs. 24.6%; P = 0.01),
suggesting that 63Asp allele may confer some advantage in
endurance performance.
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HIF1A Pro582 allele
Hypoxia-inducible factor-1α (HIF-1α; encoded by HIF1A;
location: 14q23.2) is a transcription factor regulating several
genes in response to hypoxic stimuli. HIF-1α mRNA and protein
levels were found to be constitutively higher in the more
glycolytic muscles compared with the more oxidative muscles
(Pisani and Dechesne, 2005). A lower proportion of type IIA
fibres in the soleus muscles of HIF-1α knockout mice was
detected as well as a metabolic shift away from glycolysis
toward oxidation, and as a consequence, improved endurance
capacity (Mason et al., 2004). Lunde et al. (2011) had shown
that when HIF-1α was overexpressed for 14 days after somatic
gene transfer in adult rats, a slow-to-fast transformation was
observed. In humans, a missense polymorphism in the HIF1A
gene, Pro582Ser, is present in exon 12 (rs11549465 C/T). The
rare T allele is predicted to result in a proline to serine change in
the amino acid sequence of the protein. This substitution
increases HIF-1α protein stability and transcriptional activity
(Tanimoto et al., 2003), and therefore, may improve glucose
metabolism and lower the risk of type 2 diabetes (Nagy et al.,
2009). Prior et al. (2003) had shown that HIF1A Pro/Pro
homozygotes showed preservation of the ability to increase
VO2max through aerobic exercise training at each age (55, 60
and 65 yr) level evaluated. Contrary to this, subjects carrying
the 582Ser allele were able to increase VO2max to a similar
extent as Pro/Pro homozygotes at 55 yr of age, but showed
significantly less increase in VO2max to aerobic exercise training
than Pro/Pro homozygotes at 60 and 65 yr of age. However,
McPhee et al. (2011) had shown that the HIF1A 582Ser allele
was associated with greater gains in VO2max following endurance
training in young women who completed a 6-week laboratory-
based endurance training programme. Döring et al. (2010a) by
studying 316 Caucasian male elite endurance athletes from the
Genathlete cohort and 304 Caucasian male sedentary controls
have found that the Pro582 allele was associated with
endurance athlete status. Homozygotes of the Pro582 allele
were significantly more frequent in athletes than in controls
(84.0% vs. 75.0%, P = 0.006). These results were not supported
by more recent study of 265 Russian endurance athletes and
696 controls (P > 0.05) (Ahmetov et al., 2009b).
IL15RA rs2228059 A
The IL-15 receptor α (IL-15Rα) is a part of the trimeric plasma
membrane receptor for the pleiotropic cytokine IL-15 (Giri et al.,
1995) that affects parameters associated with skeletal muscle
fibre hypertrophy (Quinn et al., 1995). There was evidence that
IL-15 and IL-15Rα interactions in vivo were more complex than
simple ligand-receptor binding. It was assumed that IL-15Rα is
an integral binding partner that can control IL-15 signaling
capacity (Bergamaschi et al., 2008; Bulanova et al., 2007;
Budagian et al., 2006; Dubois et al., 2002). Skeletal muscle
tissue contains an abundance of IL15 and IL15RA mRNAs that
are responsive to atrophic stimuli (Pistilli et al., 2007), muscle
contraction (Nielsen et al., 2007), age-associated muscle
wasting (Marzetti et al., 2010; Pistilli et al., 2007; Quinn et al.,
2004) and muscle wasting during cancer cachexia (Figueras et
al., 2004). IL15RA has a role in defining the phenotype of fast
skeletal muscles in vivo. Il15ra knockout mice have an
increased exercise capacity and altered muscle contractile
properties (Pistilli et al., 2011). Several SNPs in the IL15RA
gene (location: 10p15.1) and their association with predictors of
metabolic syndrome, skeletal muscle and bone phenotypes
have been described. The presence of the A allele in the exon 3
of the IL15RA gene (Asn146Thr, rs2228059 A/C) was
associated with greater whole muscle volume and greater
baseline cortical bone volumes. The C allele in the 3’UTR of the
IL15RA gene (rs2296135 C/A) was associated with greater
improvements in post-training isometric strength, while A allele
was associated with a greater baseline total bone volume
(Pistilli et al., 2008). In a study of 76 men and 77 women who
completed 10-week total body high activity resistance training,
the carriage of the A allele (rs2296135 C/A) was strongly
associated with muscle hypertrophy, although those with the
greatest hypertrophy had lower muscle strength and muscle
quality increases (Riechman et al., 2004). There was evidence
that SNP rs2228059 A/C was associated with ossification of the
posterior longitudinal ligament in Koreans (Kim et al., 2011).
Recently, Pistilli et al. (2011) have assessed the genotype and
allelic frequency of rs2228059 polymorphism of the IL15RA in
308 athletes of European descent participating in 11 different
sports and in 258 controls. Although there were no significant
differences in genotype distributions between elite endurance
athletes and sprint athletes, it was shown that this SNP was
associated with endurance athlete status in specific sports, such
as cycling(n = 73) had a greater percentage of the A allele,
while triathletes (n = 13) and elite rowers (n = 26) had a greater
percentage of the C allele compared to controls.
KCNJ11 Glu23 allele
Potassium channels are present in most mammalian cells,
where they participate in a wide range of physiologic responses.
The potassium inwardly-rectifying channel, subfamily J, member
11 (encoded by KCNJ11; location: 11p15.1) is an integral
membrane protein and inward-rectifier type potassium channel.
The encoded protein, which has a greater tendency to allow
potassium to flow into a cell rather than out of a cell, is
controlled by G-proteins (Smith et al., 2007). The KCNJ11 gene
is expressed in several tissues, including cardiac and skeletal
muscle, where it is involved in the coupling of cell metabolism to
cell electrical activity. Among several potentially functional
genetic variants identified in the KCNJ11 gene, the Glu23Lys
(E23K or rs5219 C/T) variant has been the most extensively
studied and has been found to be associated with various
glucose, insulin and cardiovascular phenotypes and type 2
diabetes risk (Laukkanen et al., 2004). Yi et al. (2008) had
shown that the Glu/Glu genotype was associated with the
highest values of VO2max and maximal minute ventilation in
women in untrained state than in Glu/Lys heterozygotes.
Furthermore, two independent case-control studies have
demonstrated that the KCNJ11 Glu23 was significantly over-
represented in endurance-oriented athletes compared to
controls in mixed Caucasian (184 male endurance-oriented
athletes with VO2max ≥ 75 ml/kg/min; 61.0% vs. 50.0%, P = 0.01)
(González et al., 2003) and Spanish (98 marathon runners; 68.0%
vs. 53.0%, P = 0.04) (Ortiz et al., 2005) cohorts.
MtDNA markers
Mitochondria are essential to all higher organisms for sustaining
life, and are extremely important in energy metabolism,
providing 36 molecules of ATP per glucose molecule in contrast
to the two ATP molecules produced by glycolysis. Although
most DNA is packaged in chromosomes within the nucleus,
mitochondria also possess their own circular DNA:
mitochondrial DNA (mtDNA). The 16569-bp human mtDNA
contains 13 genes for mitochondrial oxidative phosphorylation
(OXPHOS), as well as two ribosomal RNA and 22 transfer RNA
genes that are necessary for protein synthesis within
mitochondria. Unlike nuclear DNA, mtDNA is inherited
maternally. Patients with mutations in mitochondrial DNA
(mtDNA) commonly present with exercise intolerance, muscle
weakness and increased production of lactic acid (Niemi and
Majamaa, 2005). An association has been found between
several mtDNA control region polymorphisms and endurance
capacity in sedentary men (Murakami et al., 2002), and between
morph variants of MTND5 and the level of maximum oxygen
uptake (Dionne et al., 2001), suggesting that certain mtDNA
lineages may contribute to good aerobic performance. At least 9
studies reported association between the mtDNA polymorphism
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and athlete status (Deason et al., 2012; Kim et al., 2012; Mikami
et al., 2012; Mikami et al., 2011; Nogales-Gadea et al., 2011;
Tamura et al., 2010; Scott et al., 2009; Castro et al., 2007;
Niemi and Majamaa, 2005). In a study of Finnish elite
endurance athletes (n = 52), an excess of mtDNA haplogroup H
and the absence of haplogroup K and subhaplogroup J2
compared to 1,060 controls and 89 sprinters was reported
(Niemi and Majamaa, 2005). Haplogroup T was significantly
less frequent among 95 Spanish elite endurance athletes in
comparison with 250 healthy male population controls (Castro et
al., 2007). Recently, Scott et al. (2009) had shown a greater
proportion of L0 haplogroups and lower proportion of L3*
haplogroups in 70 Kenyan elite endurance athletes compared to
controls (Kenyan population, n = 85). In addition, Tamura et al.
(2010) have demonstrated a significantly higher frequency of
the m.5178C genotype (71.2%) of the m.5178CA polymorphism
in male elite Japanese endurance runners (n=66) than in control
subjects (52.7%). Mikami et al. (2011) analysed mtDNA
polymorphism in 139 Olympic athletes (79 endurance/middle-
power athletes, 60 sprint/power athletes) and 672 controls.
Endurance/middle-power athletes showed an excess of
haplogroup G1 (8.9% vs. 3.7%; P = 0.032), whereas
sprint/power athletes displayed a greater proportion of
haplogroup F (15.0% vs. 6.0%; P = 0.007). In a following study
of 185 elite Japanese athletes and 672 controls,
endurance/middle-power athletes (n = 100) displayed excess of
three polymorphisms (m.152T>C, m.514(CA)(n) repeat (n≥5),
and poly-C stretch at m.568-573 (C≥7)) compared with controls.
On the other hand, 85 sprint/power athletes showed greater
frequency of the m.204T>C polymorphism compared with
controls (Mikami et al., 2012). Moreover, Nogales-Gadea et al.
(2011) have observed that the V haplogroup was
overrepresented in 102 Spanish elite endurance athletes
(professional road cyclists, endurance runners) compared with
478 controls (15.7% vs. 7.5%). Deason et al. (2012) revealed a
high level of overrepresentation of the non-African component of
MtDNA (non-L/U6 paragroup) in elite African-American sprinters
(n = 119) compared to African-American controls (n = 1148).
Finally, Kim et al. (2012) have found that 75 Korean
endurance/middle-power athletes had an excess of haplogroups
M* and N9, but a dearth of haplogroup B compared with 265
non-athletic controls.
NOS3 Glu298, 164-bp, 4B and rs2070744 T alleles
Endothelial nitric oxide synthase (NOS3) generates nitric oxide
(NO) in blood vessels and is involved with regulating vascular
function. In mammals, NO is an important cellular signaling
molecule involved in many physiological and pathological
processes. It is a powerful vasodilator with a short half-life of a
few seconds in the blood. Nitric oxide was also shown to
regulate activity-induced MHC-based faster-to-slower fibre type
transformations at the transcriptional level via inhibitory
glycogen synthase kinase-3β-induced facilitation of calcineurin–
NFATc1 nuclear accumulation in vivo (Martins et al., 2012). The
NOS3 gene (location: 7q36) contains a number of frequently
studied polymorphisms, such as Glu298Asp (E298D or G894T
or rs1799983) in exon 7, microsatellite (CA)n repeats in intron 13,
27 bp repeats in intron 4 (4B/4A) and promoter -786 T/C
(rs2070744) variations. Evidence suggests that the NOS3
298Asp allele was associated with reduced ecNOS activity,
reduced basal NO production and vascular disease in several
populations. Saunders et al. (2006) investigated NOS3
Glu298Asp polymorphism (in combination with the BDKRB2
polymorphism) in 443 male Caucasian Ironman triathletes and
203 healthy Caucasian male control subjects. There was a
tendency of the NOS3 Glu298 allele combined with a BDKRB2
–9/–9 genotype to be over-represented in the fastest finishing
triathletes (n = 40, 28.6%) compared with the control subjects (n
= 28, 17.3%; P = 0.028) (Saunders et al., 2006). In the
Genathlete study, Wolfarth et al. (2008) have examined the
contribution of three above-mentioned polymorphisms to
discriminate 316 elite endurance athletes from 299 sedentary
controls. The frequency of the most common 164-bp allele of
the (CA)n repeat was significantly higher in endurance athletes
in comparison with controls (P = 0.007). In a study of 168
Russian rowers (Ahmetov et al., 2008e), no difference was
found between the athletes and controls for the 27 bp repeat
polymorphism, although none of the highly elite rowers had the
NOS3 4A/4A genotype which has been reported to be
unfavourable for high-altitude adaptation (as well as NOS3
Glu/Glu genotype) (Ahsan et al., 2005). In addition, cross-
sectional study in 27 Russian rowers revealed the association of
NOS3 4B/4B genotype with higher aerobic capacity (Ahmetov et
al., 2008e). Recently, Drozdovska et al. (2009) have found
significant differences in the frequency of the NOS3 rs2070744
T (-786 T/C polymorphism) allele (75.4% vs. 65.0%; P = 0.029)
between 71 endurance-oriented Ukrainian athletes (30
underwater finswimmers, 41 rowers) and 147 controls. However,
Gómez-Gallego et al. (2009a) did not find any differences in the
frequency of the NOS3 rs2070744 T allele between 100
Spanish world-class endurance athletes and 100 controls.
PPARA rs4253778 G allele
Peroxisome proliferator-activated receptor α (PPARα) is a
transcription factor that regulates lipid, glucose, and energy
homeostasis and controls body weight and vascular
inflammation. PPARα is expressed at high levels in tissues that
catabolize fatty acids, notably the liver, skeletal and cardiac
muscle, and at lower levels in other tissues, including the
pancreas (Braissant et al., 1996). The level of expression of
PPARα is higher in type I (slow-twitch) than in type II (fast-twitch)
muscle fibres (Russel et al., 2003). Endurance training
increases the use of non-plasma fatty acids and may enhance
skeletal muscle oxidative capacity by PPARα regulation of gene
expression (Russel et al., 2003; Horowitz et al., 2000). PPARα
regulates the expression of genes encoding several key muscle
enzymes involved in fatty acid oxidation (Aoyama et al., 1998;
Gulick et al., 1994; Schmitt et al., 2003). Chronic electrical
stimulation of latissimus dorsi muscle in dogs increased muscle
PPARα content and medium-chain acyl-CoA dehydrogenase
gene expression (Cresci et al., 1996). These data suggest that
PPARα may be an important component of the adaptive
response to endurance training by transducing physiological
signals related to exercise training to the expression of nuclear
genes encoding for skeletal muscle mitochondrial fatty acid
oxidation enzymes. Catabolism of carbohydrates and fatty acids
provides the primary means for energy production in working
skeletal muscle, whereby selection of these substrates depends
primarily on exercise intensity (Brooks and Mercier, 1994) and
gene variants involved in regulation of muscle metabolism
(Lucia et al., 2005a; Ahmetov et al., 2009b, Bray et al., 2009).
Exercise-induced LV growth in healthy young men was strongly
associated with the intron 7 G/C (rs4253778) polymorphism of
the PPARA gene (location: 22q13.31) (Jamshidi et al., 2002).
Individuals homozygous for the C allele had a 3-fold greater and
heterozygotes had a 2-fold greater increase in LV mass than G
allele homozygotes, leading to the hypothesis that the
hypertrophic effect of the rare intron 7 C allele was due to
influences on cardiac substrate utilization. Recently, it was
demonstrated that the frequency of the PPARA rs4253778 GG
genotype and G allele was higher in 491 Russian endurance-
oriented athletes (P = 0.0001) (Ahmetov et al., 2006), 74 elite
Israeli endurance athletes (P = 0.051) (Eynon et al., 2010c), 55
elite Polish rowers (P = 0.009) (Maciejewska et al., 2011) and
Polish combat athletes (P = 0.01) (Cieszczyk et al., 2011d)
compared to controls and/or sprinters. In accordance with the
hypothesis, mean percentage of type I muscle fibre was higher
in GG homozygotes than in CC genotype subjects (in a study of
40 physically active healthy men) (Ahmetov et al., 2006).
Furthermore, GG genotype was shown to be correlated with
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high values of oxygen pulse (i.e. VO2max//heart rate) both in
male and female Russian rowers (Ahmetov et al., 2007b).
PPARD rs2016520 C allele
Peroxisome proliferator-activated receptor δ (PPARδ) is a
transcription factor involved in regulation of genes implicated in
fatty acid oxidation, cholesterol metabolism and thermogenesis.
Overexpression of a constitutively active PPARδ (VP16-PPARδ)
in skeletal muscles of transgenic mice preprograms an increase
in oxidative muscle fibres, enhancing running endurance by
nearly 100% in untrained adult mice (Wang et al., 2004). The
SNP located at the 5’-UTR region of the exon 4 (rs2016520,
referred as +294 T/C or +15 C/T or c.-87T/C) variant in PPARD
gene (location: 6p21.2) has been intensively studied. Skogsberg
et al. (2003) had shown that the rare C allele had higher
transcriptional activity than the common T allele. Furthermore,
the PPARD C allele has been reported to be significantly
associated with an increased muscle glucose uptake (Vänttinen
et al., 2005a), and a lower body mass index both in athletes and
non-athletes (Ahmetov et al., 2007b, Aberle et al., 2006). In
addition, a significantly higher frequency of the PPARD C allele
was observed in long endurance (n = 308, 19%), middle
endurance (n = 220, 17.5%) and short endurance (n = 81,
20.4%) Russian athletes compared to controls (n = 610, 12.1%)
(Ahmetov et al., 2007a). Furthermore, in a study of 155 Israeli
athletes Eynon et al. (2009b) have found that the frequency of
the combination PPARD CC + PPARGC1A Gly/Gly was
significantly higher in elite endurance-oriented athletes
compared with non-elite athletes. However, contrary to the
hypothesis that PPARD C allele may be advantageous for the
endurance performance, Hautala et al. (2007) in considering
only black (n = 264) subjects, have demonstrated in PPARD CC
homozygotes a smaller endurance training-induced increase in
maximal oxygen consumption and maximal power output
compared to T allele carriers.
PPARGC1A Gly482 allele
Peroxisome proliferator-activated receptor γ (PPARγ)
coactivator 1α (PGC1α, encoded by PPARGC1A), a
transcriptional coactivator of PPAR family, is involved in
mitochondrial biogenesis, fatty acid oxidation, glucose utilization,
thermogenesis, angiogenesis and muscle fibre-type conversion
toward slow-twitch type I fibres. The minor serine-encoding
allele of the common Gly482Ser polymorphism (rs8192678 G/A)
in PPARGC1A gene (location: 4p15.1) was associated with
reduced expression of PPARGC1A (Ling et al., 2004) and
obesity (Ridderstråle et al., 2006). Furthermore, the 482Ser
allele has been reported to be associated with a smaller
increase in individual anaerobic threshold after 9 months of
aerobic training (Stefan et al., 2007), lower aerobic capacity in
Russian rowers (Ahmetov et al., 2007b) and mixed group of
Spanish endurance athletes, fit, and unfit Caucasian controls
(Lucia et al., 2005a). In addition, in four case-control studies,
significantly lower frequency of 482Ser allele in Spanish (n =
104), Russian (n = 579), Israeli (n = 74) and Polish (n = 92) elite
endurance-oriented athletes has been reported (Maciejewska et
al., 2012; Ahmetov et al., 2009b; Eynon et al., 2009b; Lucia et
al., 2005a).
PPARGC1B 203Pro and 292Ser alleles
PPARγ coactivator 1 β (PGC1β, encoded by PPARGC1B;
location: 5q32) is expressed predominantly in heart, skeletal
muscle, brown adipose tissue and the brain. Recently, Arany et
al. (2007) had shown that transgenic expression of PGC1β
caused a marked induction of mice IIX fibres, which are fast-
twitch oxidative. PGC1β transgenic muscle fibres are rich in
mitochondria and are highly oxidative. Consequently, these
transgenic animals can run for longer and at higher workloads
than wild-type animals (Arany et al., 2007). Interestingly, Olsson
et al. (2011) had shown that the expression of the PPARGC1B
was related positively with the MHCIIa (refers to fast-twitch
oxidative fibres in humans) expression and negatively with
MHCIIx/d expression in human skeletal muscle. Two missense
SNPs of the PPARGC1B gene in relation to human physical
performance have been described. The rare 203Pro allele of the
Ala203Pro (rs7732671 G/C) polymorphism has been reported to
be associated with reduced risk of obesity (Andersen et al.,
2005), enhanced insulin-stimulated glucose metabolism and
protection against an age-related decline in PGC1β expression
in muscle (Ling et al., 2007). In a study of Russian elite
endurance athletes (n = 578), the frequency of the 203Pro allele
has been shown higher than in controls (n = 1,132) (Ahmetov et
al., 2009b). The second polymorphism, Arg292Ser (rs11959820
C/A) seems to be functional as well. The frequency of the minor
292Ser allele was lower among type 2 diabetes mellitus patients
and higher in elite male endurance athletes from the Genathlete
study (n = 316) (Wolfarth et al., 2007a) compared to controls.
TFAM 12Thr allele
Mitochondria in skeletal muscle tissue can undergo rapid and
characteristic changes as a consequence of manipulations of
muscle use and environmental conditions. Endurance exercise
training leads to increases of mitochondrial volume of up to 50%
in training interventions of a few weeks in previously untrained
subjects (reviewed in Hoppeler and Fluck, 2003). The present
data indicate that transcriptional events largely contribute to
increases in mitochondrial density in human skeletal muscle
with endurance training. Expression of mitochondrial proteins
from the nuclear and mitochondrial genomes are coordinated
and involves the nuclear-encoded mitochondrial transcription
factor A (TFAM). TFAM (encoded by TFAM; location: 10q21) is
a protein critical for mtDNA transcription, replication and
maintenance (Kang et al., 2007). Different types of exercise
increase TFAM mRNA levels to enhance mtDNA replication
(Little et al., 2010; Psilander et al., 2010; Chow et al., 2007).
Furthermore, Norrbom et al. (2010) had shown that TFAM
protein expression was significantly higher in the elite athletes
than in the moderately active individuals. The rare 12Thr allele
of the TFAM Ser12Thr polymorphism (rs1937 G/C) was found to
be over-represented in 588 Russian elite endurance athletes
compared to 1,113 controls (Ahmetov et al., 2009b; 2010b).
UCP2 55Val allele
The uncoupling proteins 1, 2 and 3 (UCP1, UCP2, and UCP3)
are members of the super family of anion carrier proteins
located in the inner membrane of mitochondria. The UCP2
protein (encoded by UCP2) is involved in uncoupling oxidative
phosphorylation from ATP synthesis in certain tissues and
regulation of lipid metabolism and energy expenditure.
Endurance training leads to an increase in UCP2 mRNA and
protein content in skeletal muscles, pancreatic islets and heart
(Calegari et al., 2011; Bo et al., 2008; Ookawara et al., 2002). A
common Ala55Val polymorphism (rs660339 C/T) has been
described in the UCP2 gene (location: 11q13) and has been
variably associated with altered body mass index, physical
activity and changes in energy expenditure (Buemann et al.,
2001; Dalgaard et al., 2001; Astrup et al., 1999). More
specifically, the Val/Val genotype has been reported to be
associated with higher exercise efficiency (Buemann et al.,
2001), enhanced metabolic efficiency and physical activity
(Astrup et al., 1999) and higher VO2max in 27 male Russian
rowers (Ahmetov et al., 2008e). Recently, it has been shown
that the frequency of the 55Val allele was over-represented in
694 Russian elite endurance athletes (Ahmetov et al., 2009b)
compared to 1,132 controls. On the other hand, Sessa et al.
(2011) found an increased frequency of the Ala55 allele in 29
Italian power-oriented athletes.
Genes for athletic performance
www.cellularandmolecularexercisephysiology.com 10 Sept 2012 ׀ Volume 1 ׀ Issue 1 ׀ e1
UCP3 rs1800849 T allele
The expression of UCP3 mainly in skeletal muscle mitochondria
made UCP3 an attractive target for studies toward manipulation
of energy expenditure to fight disorders such as obesity and
type 2 diabetes. Overexpressing human UCP3 in mice resulted
in lean, hyperphagic mice (Clapham et al., 2000). In humans,
acute exercise induces up-regulation of UCP3, most likely
because of elevated plasma free fatty acid levels (Schrauwen et
al., 2002; Pilegaard et al., 2000). Several polymorphisms in the
UCP3 gene (location: 11q13.4) have been identified and related
to markers of energy metabolism, aerobic capacity and obesity
(Ahmetov et al., 2008e; Schrauwen and Hesselink, 2002;
Halsall et al., 2001). One of the early detected observations was
5’UTR -55 C/T polymorphism (rs1800849), of which the T allele
was reported to be associated with increased skeletal muscle
UCP3 mRNA expression (Schrauwen et al., 1999), reduced BMI
(Halsall et al., 2001) and increased aerobic capacity in Russian
female rowers (Ahmetov et al., 2008e). The frequency of the
UCP3 T allele was significantly higher in 694 Russian elite
endurance athletes compared to 1,132 controls (Ahmetov et al.,
2009b). In a Genathlete study the difference in UCP3 TT
genotype frequency between 183 endurance athletes and 121
controls almost reached significance level (12.0% vs. 6.0%; P =
0.076) (Echegaray et al., 2003). However, Hudson et al. (2004)
have found no association between the -55 C/T polymorphism
within the UCP3 gene and the ultra-endurance performance of
triathletes who completed either the 2000 or 2001 South African
Ironman triathlons.
VEGFA rs2010963 C allele
Angiogenesis is a critical phenomenon in the adaptation to
aerobic exercise training and mediated by a number of
angiogenic factors including vascular endothelial growth factor
(VEGF). VEGF mRNA was upregulated in human vastus
lateralis following 30-45 min of one-legged knee extension
exercise (Gustafsson et al., 2009; Richardson et al., 1999). The
G-634C SNP (rs2010963) in the promoter region of the VEGFA
gene (location: 6p12) has been associated with VEGF protein
expression in peripheral blood mononuclear cells (Watson et al.,
2000). Two studies revealed associations of VEGFA gene
polymorphisms with aerobic capacity in humans and endurance
athlete status. Prior et al. (2006) reported a promoter region
haplotype (which includes rs2010963 C allele) to be associated
with higher VEGFA expression in human myoblasts and the
maximal rate of oxygen uptake in non-athletes before and after
aerobic exercise training, whilst Ahmetov et al. (2009b; 2008b)
reported a positive association between a VEGFA rs2010963 C
allele and both elite endurance athlete status in Russians and
the maximal rate of oxygen uptake in rowers.
VEGFR2 472Gln allele
Vascular endothelial growth factor (VEGF) is a major growth
factor for endothelial cells and VEGF receptor 2 (VEGFR2; also
known as kinase insert domain receptor, KDR) is essential to
induce the full spectrum of VEGF angiogenic responses to
aerobic training. VEGFR2 mRNA expression was increased by
acute systemic exercise (Gavin et al., 2007; Gustafsson et al.,
2007; Gavin et al., 2004). One of the potential functional
polymorphisms of the VEGFR2 gene (location: 4q11-q12) is the
rs1870377 T/A variant, which determines a histidine (His) to
glutamine (Gln) substitution. Studies have reported that the
His472Gln polymorphism influences the efficiency of VEGF
binding to VEGFR2 (Wang et al., 2007; Zhang et al., 2007) and
was associated with clinical phenotypes such as coronary heart
disease, stroke, cancer and exceptional longevity (Sebastiani et
al., 2008; Ellis et al., 2007; Försti et al., 2007; Wang et al., 2007;
Zhang et al., 2007). In a study of 182 endurance-oriented
Russian athletes the significantly higher frequency of the
VEGFR2 472Gln allele compared to controls was reported
(Ahmetov et al., 2009a). Furthermore, the 472Gln allele was
also shown to be significantly associated with a higher
proportion of type I fibres of m. vastus lateralis (determined by
immunohistochemistry) in both athletes (all-round speed skaters,
n = 23; age 20.4 ± 0.5 years) and physically-active men (n = 45;
age 23.5 ± 0.4 years), and with a greater VO2max in female
rowers (Ahmetov et al., 2009a).
Y-chromosomal haplogroups
Several positive associations have been reported between
specific haplogroups of the Y chromosome and a number of
phenotypes, including infertility, low sperm count, prostate
cancer, blood pressure and stature (Jobling and Tyler-Smith,
2003). In respect to sports performance, Moran et al. (2004)
reported that the Y chromosome haplogroups E*, E3* and K*(xP)
were significantly more frequent in the Ethiopian endurance
running groups (n = 44) than in controls (95 members of the
general Ethiopian population and 85 Arsi controls), whereas
haplogroup E3b1 was less frequent.
Gene variants for power athlete status
ACE D allele
The I/D polymorphism of the ACE gene (location: 17q23.3)
denotes a substantial individual variation in renin-angiotensin
system activity with the D allele being associated with higher
ACE activity. Circulating ACE activity was significantly
correlated with isometric and isokinetic quadriceps muscle
strength (Williams et al., 2005). Such effect may depend upon
increased ACE-mediated activation of the growth factor
angiotensin II, and increased degradation of growth-inhibitory
bradykinin. Accordingly, greater training-related increases in
quadriceps muscle strength (Giaccaglia et al., 2008; Folland et
al., 2000), peak elbow flexor muscle strength and biceps muscle
cross-sectional area (Pescatello et al., 2006), and changes in
left ventricular growth (Montgomery et al., 1997) have been
associated with the D allele. Similarly, several studies had
shown the D allele to be associated with greater strength and
muscle volumes at baseline (Charbonneau et al., 2008; Wagner
et al., 2006; Hopkinson et al., 2004) and an increased
percentage of fast-twitch muscle fibres (Zhang et al., 2003). In
addition, the D allele and/or DD genotype was shown to be
over-represented in 20 British (Myerson et al., 1999), 65
Russian (Nazarov et al., 2001), 56 European and
Commonwealth Caucasian swimmers (<400 m) (Woods et al.,
2001), 43 Greek sprinters (Papadimitriou et al., 2009), 25
Portuguese (Costa et al., 2009) and 46 Spanish (Boraita et al.,
2010) strength/power athletes. Contrary to the main hypothesis,
Kim et al. (2010a) had shown that top level power-oriented
athletes (n = 55) had a markedly diminished frequency of the
DD genotype and the D allele than national level power-oriented
athletes (n = 100) or controls (n = 693). The same finding was
reported by Ginevičienė et al. (2011) by studying 51 power-
oriented athletes and 250 controls. Furthermore, several studies
of power/sprint athletes have demonstrated no association
between the ACE I/D polymorphism and power athlete status
(Sessa et al., 2011; Scott et al., 2010; Amir et al., 2007).
Genes for athletic performance
www.cellularandmolecularexercisephysiology.com 11 Sept 2012 ׀ Volume 1 ׀ Issue 1 ׀ e1
Table 1. Gene variants (genetic markers) for endurance athlete status.
Gene
Location
Polymorphism
Endurance-related
marker
Studies with positive results
Studies with negative or
controversial results
Number of
studies
Total number
of studied
athletes
Number of
studies
Total number
of studied
athletes
ACE
17q23.3
Alu I/D (rs4646994)
I
16
1310
11
1263
ACTN3
11q13.1
R577X (rs1815739 C/T)
577X
3
518
11
2382
ADRA2A
10q24-q26
6.7/6.3 kb
6.7-kb
1
148
-
-
ADRB2
5q31-q32
Gly16Arg (rs1042713 G/A)
16Arg
2
629
-
-
ADRB3
8p12-8p11.1
Trp64Arg (rs4994 T/C)
64Arg
1
100
1
81
AQP1
7p14
rs1049305 C/G
rs1049305 C
1
784
-
-
AMPD1
1p13
Gln12X (rs17602729 C/T)
Gln12
2
231
-
-
BDKRB2
14q32.1-q32.2
+9/–9 (exon 1)
–9
2
524
1
74
rs1799722 C/T
rs1799722 T
1
316
-
-
CKM
19q13.32
A/G NcoI (rs8111989 T/C)
rs1803285 A
1
176
3
581
COL5A1
9q34.2-q34.3
rs12722 C/T (BstUI)
rs12722 T
2
385
-
-
COL6A1
21q22.3
rs35796750 T/C
rs35796750 T
1
661
-
-
EPAS1
(HIF2A)
2p21-p16
rs1867785 A/G
rs1867785 G
1
451
-
-
rs11689011 C/T
rs11689011 T
1
451
-
-
GABPB1
(NRF2)
15q21.2
rs12594956 A/C
rs12594956 A
2
163
-
-
rs8031031 C/T
rs8031031 T
1
74
1
89
rs7181866 A/G
rs7181866 G
2
129
1
89
GNB3
2p13
rs5443 C/T (C825T)
rs5443 T
1
74
1
100
HFE
6p21.3
His63Asp (rs1799945 C/G
63Asp
2
148
-
-
HIF1A
14q23.2
Pro582Ser (rs11549465 C/T)
Pro582
1
316
1
265
IL15RA
10p15.1
Asn146Thr (rs2228059 A/C)
rs2228059 A
1
73
-
-
KCNJ11
11p15.1
Glu23Lys (rs5219 C/T)
Glu23
2
282
-
-
MtDNA loci
MtDNA
Haplogroups constructed
from several MtDNA
polymorphisms or single
polymorphisms
H
1
52
-
-
L0
1
70
-
-
M*
1
75
-
-
m.5178C
1
66
-
-
G1
1
79
-
-
m.152C
1
100
-
-
m.514(CA)5
1
100
-
-
N9
1
75
-
-
poly(C≥7) stretch
at m.568-573
1
100
-
-
V
1
102
-
-
Unfavourable: B
1
75
-
-
Unfavourable: K,
J2
1
52
-
-
Unfavourable: T
1
95
-
-
Unfavourable: L3*
1
70
-
-
NFATC4
14q11.2
Gly160Ala (rs2229309 G/C)
Gly160
1
694
-
-
NOS3
7q36
Glu298Asp (rs1799983 G/T)
Glu298
1
443
-
-
(CA)n repeats
164-bp
1
316
-
-
27 bp repeats (4B/4A)
4B
1
168
-
-
rs2070744 T/C (-786 T/C)
rs2070744 T
1
71
1
100
PPARA
22q13.31
rs4253778 G/C
rs4253778 G
4
680
-
-
PPARD
6p21.2-p21.1
rs2016520 T/C
rs2016520 C
2
683
-
-
PPARGC1A
4p15.1
Gly482Ser (rs8192678 G/A)
Gly482
4
849
-
-
PPARGC1B
5q33.1
Ala203Pro (rs7732671 G/C)
203Pro
1
578
-
-
Arg292Ser (rs11959820 C/A)
292Ser
1
316
-
-
PPP3CA
4q24
rs3804358 C/G
rs3804358 C
1
123
1
100
PPP3CB
10q22.2
rs3763679 C/T
rs3763679 C
1
123
1
100
PPP3R1
2p15
Promoter 5I/5D
5I
1
694
-
-
TFAM
10q21
Ser12Thr (rs1937 G/C)
12Thr
1
588
-
-
UCP2
11q13
Ala55Val (rs660339 C/T)
55Val
1
694
-
-
UCP3
11q13
rs1800849 C/T
rs1800849 T
2
877
1
178
VEGFA
6p12
rs2010963 G/C
rs2010963 C
1
942
-
-
VEGFR2
4q11-q12
His472Gln (rs1870377 T/A)
472Gln
1
182
-
-
Y-
chromosome
haplogroups
Y-
chromosome
Haplogroups constructed
from several Y-chr.
polymorphisms
E*, E3* and K*(xP)
1
44
-
-
Unfavourable:
E3b1
1
44
-
-
Genes for athletic performance
www.cellularandmolecularexercisephysiology.com 12 Sept 2012 ׀ Volume 1 ׀ Issue 1 ׀ e1
ACTN3 Arg577 allele
The α-actinins constitute the predominant protein component of
the sarcomeric Z line in skeletal muscle fibres, where they form
a lattice structure that anchors together actin containing thin
filaments and stabilizes the muscle contractile apparatus
(reviewed in Yang et al., 2009). Expression of the α-actininin-3
(ACTN3) is limited to fast muscle fibres responsible for
generating force at high velocity. A common R577X (rs1815739
C/T) genetic variation in the ACTN3 gene (location: 11q13.1)
had been identified. This SNP results in the replacement of an
arginine (Arg or R) with a stop codon at amino acid 577. The
577X allele contains a sequence change that completely
prevents the production of functional α-actinin-3 protein. Several
case-control studies reported that ACTN3 RR genotype (or
Arg577 allele) was over-represented or ACTN3 XX genotype
was under-represented in strength/sprint athletes in comparison
with controls. More specifically, Yang et al. (2003) for the first
time had shown that the frequency of the ACTN3 XX genotype
was reduced in Australian power athletes (n = 107; 6.0% vs.
20/0%) compared to controls, whereas none of the Olympians
or female power athletes had an XX genotype. These findings
have been supported by the independent replications in case-
control studies of elite Finnish sprint athletes (n = 68; frequency
of the XX genotype: 0% vs. 9.2%) (Niemi and Majamaa, 2005),
elite Greek track and field athletes (n = 73; frequency of the RR
genotype: 47.94% vs. 25.97%) (Papadimitriou et al., 2008), top-
level professional soccer players, participating in the Spanish
Championships (n = 60; frequency of the RR genotype: 48.3%
vs. 28.5%) (Santiago et al., 2008), elite-level strength athletes
from across the United States (n = 75; frequency of the XX
genotype: 6.7% vs. 16.3%) (Roth et al., 2008), Russian power-
oriented athletes (n = 486; frequency of the XX genotype: 6.4%
vs. 14.2%) (Druzhevskaya et al., 2008) and Italian artistic
gymnasts (n = 35; frequency of the XX genotype: 2.8% vs.
18.8%) (Massidda et al., 2009). These results were confirmed
by more recent studies of Taiwanese sprint swimmers (n = 168;
frequency of the R allele in female international sprint swimmers:
67.6% vs. 53.7%) (Chiu et al., 2011), Israeli sprinters (n = 81;
frequency of the RR genotype: 52% vs. 27.3%) (Eynon et al.,
2009a), Russian short-distance speed skaters (n = 39;
frequency of the XX genotype: 2.6% vs. 14.5%) (Ahmetov et al.,
2011), and Polish power-oriented athletes (n = 158; frequency
of the R allele: 69.3% vs. 59.6%) (Cieszczyk et al., 2011b). It
should be noted that four studies reported no association
between the ACTN3 R577X polymorphism and power athlete
status (Sessa et al., 2011, Ginevičienė et al., 2010; Scott et al.,
2010; Yang et al., 2007). The hypothesis that ACTN3 Arg577
allele may confer some advantage in power performance events
was supported by several cross-sectional studies in non-
athletes including mouse models of the ACTN3 deficiency
(Ahmetov et al., 2011; Ginevičienė et al., 2010; Chan et al.,
2008; Delmonico et al., 2008; MacArthur et al., 2008; Walsh et
al., 2008; Delmonico et al., 2007; Moran et al., 2007; Vincent et
al., 2007; Clarkson et al., 2005). Additionally, Vincent et al.
(2007) had shown that the percentage of the cross-sectional
area and the number of type IIx (fast-twitch glycolytic) fibres was
greater in the RR than the XX genotype group of young healthy
men. This association was replicated in a second study, where
the ACTN3 R577X polymorphism was shown to be associated
with muscle fibre composition in a group (n = 94) of physically
active men and sub-elite speed skaters (slow-twitch muscle
fibres, RR genotype: 51.7 (12.8)%, RX: 57.4 (13.2)%, XX: 61.5
(16.3)%; P = 0.049), indicating that ACTN3 XX genotype
carriers exhibit a higher proportion of slow-twitch muscle fibres
(Ahmetov et al., 2011). Furthermore, it was supposed that the α-
actinin-3 deficiency may also negatively influence the power
component of competition performance in endurance athletes at
least in Russian rowers and Japanese endurance runners (Saito
et al., 2011; Ahmetov et al., 2010a). There is currently no
univocal evidence that the X allele is advantageous to
endurance athleticism (Alfred et al., 2011). Although three
studies had shown that proportion of the XX genotype and/or X
allele was higher in endurance-oriented athletes compared with
controls (Shang et al., 2010; Eynon et al., 2009a; Yang et al.,
2003), the majority of authors reported no association between
the ACTN3 R577X polymorphism and endurance athlete status
(Döring et al., 2010b; Ginevičienė et al., 2010; Tsianos et al.,
2010; Niemi and Majamaa, 2007; Papadimitriou et al., 2008;
Paparini et al., 2007; Saunders et al., 2007; Yang et al., 2007;
Lucia et al., 2006).
AGT 235Thr allele
The angiotensinogen (AGT) (serpin peptidase inhibitor, clade A,
member 8), serum α-globulin formed by the liver, is an essential
component of the renin-angiotensin system. The AGT is cleaved
by the renin to form biologically inactive angiotensin I, the
precursor of active angiotensin II that regulates vascular
resistance and sodium homeostasis, and thus determining
blood pressure. High plasma AGT levels can lead to a parallel
increase in the formation of angiotensin II that may ultimately
result in hypertension. The injection of AGT caused a dose-
dependent increase in mean arterial blood pressure in the rats
(Klett and Granger, 2001). The AGT is encoded by AGT gene
(location: 1q42.2). Agt knockout mice do not produce AGT in
liver, resulting in the complete loss of plasma immunoreactive
angiotensin I. Their systolic blood pressure was significantly
lower than that of the wild-type mice (Tanimoto et al., 1994).
Met235Thr polymorphism of the AGT gene leads to the
substitution of threonine to methionine at position 235 (rs699
T/C). There was a significant relationship between the AGT
Met235Thr polymorphism and hypertension (Fang et al., 2010;
McCole et al., 2002; Jeunemaitre et al., 1997; Caulfield et al.,
1994). Results from the HERITAGE family study suggested that
in middle-aged sedentary normotensive women relationship
between diastolic blood pressure and AGT Met235Thr
polymorphism was dependent on the fat mass (Rankinen et al.,
1999). The AGT Met235Thr variation modifies the
responsiveness of exercise diastolic blood pressure to
endurance training (Rankinen et al., 2000a; Krizanova et al.,
1998). It was demonstrated that regular moderate intensity
exercise attenuates aging-related increase in the systolic blood
pressure and decreases diastolic blood pressure in individuals
with the AGT Met/Met genotype (Rauramaa et al., 2002). The
AGT Met235Thr polymorphism was shown to be associated
with left-ventricular mass index increase in a study of 83 young
healthy individuals after 17 weeks of exercise training (50-80%
VO2max) (Alves et al., 2009). Individuals with the AGT Thr/Thr
genotype had significantly greater left-ventricular mass index
than those with the Met/Met or Met/Thr genotype (P = 0.04),
which suggests that left-ventricular hypertrophy caused by
exercise training was exacerbated in homozygous AGT Thr/Thr
individuals. Results of the study by Karjalainen and colleagues
(1999) suggested that AGT gene Met235Thr polymorphism was
associated with the variability in left ventricular hypertrophy
induced by endurance training. Results of the echocardiography
in 50 male and 30 female elite endurance athletes showed that
Thr/Thr homozygotes had greater left ventricular mass
compared with the Met/Met homozygotes in both men (P =
0.032) and women (P = 0.019). In a study of 60 Spanish elite
athletes (25 cyclists, 20 long-distance runners, and 15 handball
players) and 400 controls there were no significant differences
in the AGT Met235Thr genotype frequencies (Alvares et al.,
2000). Recently, Gómez-Gallego et al. (2009c) compared the
genotype and allele frequencies for the AGT Met235Thr
variation of Caucasian athletes (100 world-class endurance
athletes (professional cyclists, Olympic-class runners), and 63
power athletes (top-level jumpers, throwers, sprinters)) and 119
nonathletic controls. Results revealed a higher percentage of
Thr/Thr genotype carriers among power athletes (34.9%) than
either in controls (16%, P = 0.008) or an endurance group (16%,
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P = 0.005). Therefore, it was assumed that 235Thr allele of the
AGT Met235Thr polymorphism might favour power sports
performance and this could be attributed to the higher activity of
angiotensin II that acts as a growth factor in skeletal muscle.
AMPD1 Gln12 allele
Adenosine monophosphate deaminase (AMPD) is an important
regulator of muscle energy metabolism: By converting AMP into
inosine monophosphate (IMP) with liberation of ammonia, this
enzyme displaces the equilibrium of the myokinase reaction
towards ATP production. The human AMPD1 gene (location:
1p13) produces isoform M, myoadenylate deaminase, and is
expressed at a high level predominantly in adult skeletal muscle.
Homozygotes for the 34C>T mutation (Gln12X) of the AMPD1
have extremely low skeletal muscle AMPD activity, individuals
with one normal and one mutant allele have intermediate activity,
and those with two AMPD1 normal alleles have high activity
(Fischer et al., 2007; Norman et al., 2001). With AMPD1
deficiency individuals exhibit a low AMP deaminase activity, a
faster accumulation of blood lactate during the early recovery
from a 30-s sprint exercise (Norman et al., 2008; Norman et al.,
2001). Fischer et al. (2007) revealed a faster power decrease in
the AMPD-deficient group during the 30-s Wingate cycling test.
These data indicate that AMPD1 deficiency could have a
detrimental effect on sprint/strength performance. Indeed,
Cieszczyk et al. (2012) had shown that Polish power-oriented
athletes (n = 158; short-distance runners, short-distance
swimmers and weightlifters) had a significantly lower (5.4% vs.
13.1%, P = 0.0007) frequency of the AMPD1 12X allele than
controls (n = 160). These results were replicated in a cohort of
Russian power-oriented athletes (n = 305; boxing, wrestling,
speed skating (500-1500 m), powerlifting, swimming (50-100 m),
weightlifting; frequency of the 12X allele: 8.4% vs. 15.0%; P <
0.0001, in comparison with 499 controls)) (Fedotovskaya et al.,
2012a).
Folate-pathway genetic markers (MTHFR rs1801131 C, MTR
rs1805087 G and MTRR rs1801394 G alleles)
DNA methylation is a major epigenetic modification that
suppresses gene expression by modulating the access of the
transcription machinery to the chromatin or by recruiting methyl
binding proteins (Cedar and Bergman, 2009). Barrès et al.
(2012) had shown that exercise-induced acute gene activation
was associated with a dynamic change in DNA methylation in
skeletal muscle and have suggested that DNA hypomethylation
is an early event in contraction-induced gene activation. More
specifically, whole genome methylation was decreased in
skeletal muscle biopsies obtained from healthy sedentary men
and women after acute exercise. Exercise also induced a dose-
dependent expression of PGC-1α, PDK4, and PPAR-δ, together
with a marked hypomethylation on each respective promoter.
Similarly, promoter methylation of PGC-1α, PDK4, and PPAR-δ
was markedly decreased in mouse soleus muscles 45 min after
ex vivo contraction (Barrès et al., 2012). Furthermore, recent
findings suggest that DNA hypomethylation induces the
activation of myogenic factors determining proliferation and
differentiation of myoblasts promoting muscle growth and
increase of muscle mass (Terruzzi et al., 2011). Since
components of the folate-pathway (homocysteine cycle) are
involved in DNA methylation/demethylation processes (and
synthesis of nucleotides), Terruzzi et al. (2011) have also
investigated whether polymorphisms of the folate-pathway
genes affecting gene expression and protein stability, probably
responsible of DNA methylation deficiency, are associated with
athlete status. The polymorphic variants A1298C (rs1801131
A/C) of 5,10-methylenetetrahydrofolate reductase (MTHFR;
location: 1p36.3), A2756G (rs1805087 A/G) of methionine
synthase (MTR; location: 1q43), A66G (rs1801394 A/G) of
methionine synthase reductase (MTRR; location: 5p15.31)
genes were determined in 77 athletes and 54 control subjects.
The frequencies of MTHFR rs1801131 C (37.0% vs. 19.8%),
MTR rs1805087 G (20.7% vs. 10.8%) and MTRR rs1801394 G
(42.7% vs. 17.0%) alleles (probably associated with a reduced
DNA methylating capacity) were significantly higher in athletes
compared with controls (Terruzzi et al., 2011). Taken together,
these data indicate that elite athletes have a genetic
predisposition to DNA hypomethylation and synthesis (factors
leading to myogenic differentiation stimulation, muscle mass
increase and induction of genes involved in energy metabolism).
HIF1A 582Ser allele
Glycolysis is the central source of anaerobic energy in humans,
and this metabolic pathway is regulated under low-oxygen
conditions by the transcription factor hypoxia-inducible factor 1α
(HIF1α; encoded by HIF1A; location: 14q23.2). HIF1α controls
the expression of several genes implicated in various cellular
functions including glucose metabolism (glucose transporters
and glycolytic enzymes). A missense polymorphism, Pro582Ser,
is present in exon 12 (C/T at bp 85; rs11549465). The rare T
allele is predicted to result in a proline to serine change in the
amino acid sequence of the protein. This substitution increases
HIF1α protein stability and transcriptional activity, and therefore,
may improve glucose metabolism. Recently, Ahmetov et al.
(2008a) investigated a hypothesis that HIF1A Pro582Ser
genotype distribution may differ for controls and Russian
sprint/strength athletes, for which anaerobic glycolysis is one of
the most important sources of energy for power performance.
The frequency of the HIF1A 582Ser allele was significantly
higher in weightlifters (n = 53) than in 920 controls (17.9% vs.
8.5%; P = 0.001) and increased with their levels of achievement
(sub-elite (14.7%) → elite (18.8%) → highly elite (25.0%)).
These results were replicated in a cohort of Polish power-
orientated athletes (n = 158; the frequency of the HIF1A 582Ser
allele: 17.1% vs. 9.1%; P = 0.01; in comparison with 254
sedentary controls) (Cieszczyk et al., 2011a), but not in 81
Israeli sprinters (Eynon et al., 2010a). Furthermore, the 582Ser
allele was significantly associated with an increased proportion
of fast-twitch muscle fibres in m. vastus lateralis of all-round
speed skaters (Ahmetov et al., 2008a).
IL1RN*2 allele
Inflammation may serve as a mechanism promoting skeletal
muscle repair and hypertrophy (Tidball, 2005). Interleukin-1
receptor antagonist (IL-1RA) is a member of the interleukin 1
(IL-1) cytokine family and modulates a variety of IL-1 related
immune and inflammatory responses. IL-1RA competes with
major inducers of proinflammatory immune responses – IL-1α
and IL1-β for binding to IL-1 receptor on the surface of a variety
of cells. But in contrast to IL-1α and IL-1β, IL-1RA does not
initiate signal transduction. IL-1RA exerts anti-inflammatory
activity by blocking IL-1 receptors and thereby preventing signal
transduction of the pro-inflammatory IL-1 (Pedersen 2000). A
balance between IL-1 and IL-1RA is of importance for regulation
of immune function (Arend, 2002; McIntyre et al., 1991). The IL-
1RA is involved in the inflammatory and repair reactions in
skeletal muscle during and after exercise (Pedersen 2000). IL-
1RA plasma concentration of marathon runners peaked 1.5 h
after the run and there was a positive correlation between the
peak plasma concentrations of IL-6 and IL-1RA (Ostrowski et al.,
2000). The IL-1RA is encoded by the IL1RN gene (location:
2q14.2) in close proximity to the genes coding for IL-1α and L-
1β. The VNTR polymorphism in intron 2 of the IL1RN gene is
caused by the 86-bp variable copy number tandem repeat (two
to six repeats), that contains three potential protein-binding sites
and therefore may have functional significance (Tarlow et al.,
1993). The allele 1 (IL1RN*1) with 4 repeats is more common
than allele 2 (IL1RN*2), containing 2 repeats. Alleles with 3, 5
and 6 repeats are considered to be rare (<1%). The IL1RN gene
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VNTR polymorphism was shown to be associated with the risk
for a number of autoimmune diseases, disorders associated
with chronic inflammation, infection, cancer, osteoporosis,
coronary artery disease, idiopathic inflammatory myopathy,
multiple sclerosis (Witkin et al., 2002; El-Omar et al., 2000;
Rider et al., 2000; Ferri et al., 1999). Young men with the
IL1RN*2 genotype had an increased total fat, serum leptin and
fat of trunk and arm as well as serum levels of IL-1RA and IL-
1RA production ex vivo (Strandberg et al., 2006). In a recent
study of 205 Italian athletes (53 professional and 152
competitive non-professional; sport activities: volleyball, soccer,
rugby, triathlon, basketball, martial arts, track-and field sports,
running, handball, swimming) and 458 non-athletic controls
Cauci et al. (2010) have found that IL1RN gene VNTR
polymorphism was associated with athletic status. The
frequencies of the IL1RN*1/IL1RN*2 genotype (41.0% vs.
26.4%, P < 0.001) and IL1RN*2 allele (32.2% vs. 22.9%, P <
0.001) were significantly higher in athletes compared to non-
athlete controls. Furthermore, the IL1RN*1/IL1RN*2 genotype
was more frequent (52.8% vs. 36.8%) in professional
(participants of Olympic Games, medalists in International
Games, Third Division soccer players) than in non-professional
(training and competitions >10 h/week) athletes. One might
assume that carriers of the IL1RN*2 allele may have an
advantage in adaptation to high intensity exercise.
IL6 rs1800795 G allele
The interleukin-6 (IL-6) (also known as B-cell stimulatory factor-
2 (BSF-2) and interferon beta-2) is a pleiotropic cytokine
involved in a wide variety of biological functions, including
regulation of differentiation, proliferation and survival of target
cells, and control for the immune acute-phase response (Horn
et al., 2000; Hirano et al., 1986). It is mainly produced by the
immune cells, but also is expressed in muscle cells (acts as a
"myokine"), and is elevated in the response to muscle
contraction (Febbrario and Pedersen, 2005). During physical
exercise the concentration of plasma IL-6 increases because of
its release from muscles, which mediates metabolic processes.
The IL-6 is relevant to many diseases such as diabetes
(Kristiansen and Mandrup-Poulsen, 2005), atherosclerosis
(Schuett et al., 2009; Huber et al., 1999), depression (Dowlati et
al., 2010) and rheumatoid arthritis (Nishimoto, 2006). The IL-6
was linked to the regulation of glucose homeostasis during
exercise. There was a relationship between the IL-6 release at
the end of exercise and muscle glycogen concentration after
exercise, which suggested that IL-6 acts as a carbohydrate
sensor (Helge et al., 2003). The IL-6 plays an important role in
the regulating fat metabolism in the muscle, increasing rates of
fatty acid oxidation, and attenuating insulin’s lipogenic effects
(Bruce and Dyck, 2004). The IL-6 also plays a role in the
hypertrophic muscle growth with a contribution of satellite cells
to this process (Serrano et al., 2008). Changes in the IL-6
system may represent systemic responses in the muscle
inflammation and repair processes (Philippou et al., 2009). The
interleukin-6 was produced in larger amounts than any other
cytokine in the relation to strenuous exercise. Strenuous
exercise leads to a significant elevation of IL-6 in the serum,
thereby eliciting an acute phase response (Northoff and Berg,
1991). In resting muscle the IL6 gene was silent, but it was
rapidly activated by the muscle contractions (Pedersen et al.,
2003). The -174 C/G (rs1800795) polymorphism in the promoter
of the IL6 gene (location: 7p21) alters transcriptional response
(Fishman et al., 1998). There was a genetically determined
difference in the degree of the IL-6 response to stressful stimuli
between individuals, with C allele found to be associated with
significantly lower levels of plasma IL-6. In a study by
Huuskonen et al. (2009), the IL6 gene -174G/C polymorphism
was shown to be associated with the VO2max and BMI responses
to physical training. Individuals with CG genotype had more
pronounced increase in the VO2max and decrease in the BMI
after 8-week of military training. Individuals with the C allele had
significantly reduced IL-6 levels in serum after long-term
exercise training program (Oberbach et al., 2008). The IL6 -
174G/C genotype was shown to be associated with high-density
lipoprotein cholesterol response to exercise training (Nishimoto
et al., 2006). Ruiz et al. (2010b) studied the IL6 -174 G/C
polymorphism in 153 elite Caucasian Spanish male athletes
(100 endurance athletes and 53 power athletes) and 100 non-
athletic controls. The frequencies of the GG genotype and G
allele were significantly higher in power-oriented athletes
compared with the endurance-oriented athletes and non-athletic
controls. It was suggested that G allele of the IL6 -174 G/C
polymorphism might favour sprint/power sports performance.
Not consistent with results of the Spanish study, Eynon et al.
(2011c) reported that there were no differences in allelic and
genotypic frequencies of the IL6 -174 C/G polymorphism among
74 elite endurance athletes, 81 power athletes and 205 non-
athletic controls (Israeli population).
NOS3 rs2070744 T allele
Nitric oxide (NO) is involved in human skeletal muscle uptake
during exercise (McConell and Kingwell, 2006) and modulation
of oxygen consumption in skeletal muscles (Wilkerson et al.,
2004). Dietary nitrate supplementation enhances muscle
contractile efficiency during knee-extensor exercise and
tolerance to high-intensity exercise in humans (Bailey et al.,
2010; Bailey et al., 2009). Therefore, one might anticipate that
genetic variation in the endothelial nitric oxide synthase gene
(NOS3; location: 7q36; NOS3 generates NO in blood vessels)
could be associated with power/sprint performance. Indeed,
Drozdovska et al. (2009) have found that the frequency of the
NOS3 rs2070744 T (-786 T/C polymorphism) allele was
significantly higher in 56 Ukrainian power-oriented athletes
(jumpers, throwers, sprinters) compared to 147 controls (77.7%
vs. 65.0%; P = 0.024). These results were confirmed in two
independent studies of 53 Spanish elite power-oriented athletes
(jumpers, throwers, sprinters) and 100 non-athletic controls
(frequency of the rs2070744 T allele: 71.0% vs. 56.0%; P =
0.015) (Gómez-Gallego et al., 2009a) and 29 Italian power-
oriented athletes (Sessa et al., 2011). Furthermore, Sessa et al.
(2011) have demonstrated that the frequency of the Glu298
allele (Glu298Asp polymorphism) was significantly higher in 29
Italian power-oriented athletes in comparison with controls.
PPARA rs4253778 C allele
PPARα is a ligand-activated transcription factor that regulates
the expression of genes involved in fatty acid uptake and
oxidation, glucose and lipid metabolism, left ventricular growth
and control of body weight. Jamshidi et al. (2002) had shown
that British army recruits homozygous for the rare PPARA gene
(location: 22q13.31) C allele of the rs4253778 (intron 7 G/C)
polymorphism had a 3-fold greater increase in LV mass in
response to training than G allele homozygotes. The hypothesis
that intron 7 C allele is associated with the hypertrophic effect
due to influences on cardiac and skeletal muscle substrate
utilization was supported by the findings that PPARA C allele
was over-represented in 180 Russian power-oriented athletes
(27.2% vs. 16.4%, P = 0.0001; in comparison with 1,242
controls) and associated with an increased proportion of fast-
twitch muscle fibres in m. vastus lateralis of 40 male controls
(Ahmetov et al., 2006) and with the best results of handgrip
strength testing in middle school-age boys (Ahmetov et al.
2012a). Furthermore, in a study of 193 Lithuanian athletes
Ginevičienė et al. (2010) had shown that male athletes with
PPARA CC and PPARA GC genotypes had significantly higher
muscle mass and single muscular contraction power (measured
by vertical jump test) than GG homozygotes. The frequency of
the PPARA C allele (26.3% vs. 17.2%; P = 0.012) was also
significantly higher in Lithuanian power-oriented athletes and
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athletes with mixed aerobic/anaerobic activity (n = 80) in
comparison with 250 controls (Ginevičienė et al., 2010).
However, Broos et al. (2011) did not find any association
between the PPARA rs4253778 G/C polymorphism and muscle
strength characteristics in non-athletic young men. There were
no differences in allelic frequencies between 81 Israeli sprinters
and 240 controls (Eynon et al., 2010c).
PPARG 12Ala allele
Peroxisome proliferator-activated receptor γ (PPARγ; encoded
by PPARG; location: 3p25) plays a critical physiological role as
a central transcriptional regulator of adipogenic and lipogenic
programs, insulin sensitivity and glucose homeostasis. The
12Ala variant of the PPARG gene Pro12Ala polymorphism
(rs1801282 C/G) was associated with decreased receptor
activity (Deeb et al., 1998), improved insulin sensitivity (Deeb et
al., 1998) and increased body mass index in humans (Ahmetov
et al., 2007b; Masud and Ye, 2003). The carriers of the 12Ala
allele show better glycaemic response to exercise training
(Adamo et al., 2005), higher rates of skeletal muscle glucose
uptake (Vänttinen et al., 2005b) and greater cross-sectional
area of muscle fibres (Ahmetov et al., 2008d). In a study of
Russian power-oriented athletes (n = 260), the higher frequency
(23.8% vs. 15.1%, P < 0.0001) of the PPARG 12Ala
allelecompared to 1,073 controls has been reported (Ahmetov
et al., 2008d).
Table 2. Gene variants (genetic markers) for power/strength athlete status
Gene
Location
Polymorphism
Power/strength-
related marker
Studies with positive results
Studies with negative or
controversial results
Number of
studies
Total number
of studied
athletes
Number of
studies
Total
number of
studied
athletes
ACE
17q23.3
Alu I/D (rs4646994)
D
6
255
5
365
ACTN3
11q13.1
R577X (rs1815739 C/T)
Arg577
11
1350
4
368
AGT
1q42.2
Met235Thr (rs699 T/C)
235Thr
1
63
-
-
CKM
19q13.32
A/G NcoI (rs8111989 T/C)
rs1803285 G
1
74
-
-
AMPD1
1p13
Gln12X (rs17602729 C/T)
Gln12
2
463
-
-
HIF1A
14q21-q24
Pro582Ser (rs11549465
C/T)
582Ser
2
211
1
81
IL1RN
2q14.2
VNTR 86-bp (intron 2)
IL1RN*2
1
205
-
-
IL6
7p21
-174 C/G (rs1800795 C/G)
rs1800795 G
1
53
1
81
MtDNA
loci
MtDNA
Haplogroups constructed
from several MtDNA
polymorphisms or single
polymorphisms
F
1
60
-
-
m.204C
1
85
-
-
Non-L/U6
1
119
-
-
MTHFR
1p36.3
A1298C (rs1801131 A/C)
rs1801131 C
1
77
-
-
MTR
1q43
A2756G (rs1805087 A/G)
rs1805087 G
1
77
-
-
MTRR
5p15.31
A66G (rs1801394 A/G)
rs1801394 G
1
77
-
-
NOS3
7q36
rs2070744 T/C (-786 T/C)
rs2070744 T
3
138
-
-
Glu298Asp (rs1799983
G/T)
Glu298
1
29
-
-
PPARA
22q13.31
rs4253778 G/C
rs4253778 C
2
260
1
81
PPARG
3p25
Pro12Ala (rs1801282 C/G)
12Ala
1
260
-
-
UCP2
11q13
Ala55Val (rs660339 C/T)
Ala55
1
29
-
-
VDR
12q13.11
FokI f/F (rs10735810 T/C)
rs10735810 T
1
125
-
-
VDR rs10735810 T allele
Vitamin D receptor (VDR) has been found in human skeletal
muscle cells, where it affects muscle cell metabolism by binding
to vitamin D metabolites (Pfeifer et al., 2002). The VDR is
involved in sustaining normocalcemia by inhibiting the
production of parathyroid hormone and has effects on bone and
skeletal muscle biology (Haussler et al., 2011; Garfia et al.,
2002). Vdr knockout mice develop a low bone mass phenotype
with hypocalcemia, hypophosphatemia and elevated calcitriol
levels (Yoshizawa et al., 1997). Almost 200 polymorphisms are
known to exist in the VDR gene (location: 12q13.11).
Polymorphisms in VDR gene are associated with bone mineral
density (Gong et al., 1999), osteoporotic and stress fractures
(Korvala et al., 2010; Moffett et al., 2007), insulin resistance
(Jain et al., 2011), muscle strength (Bahat et al., 2010; Barr et
al., 2010; Murakami et al., 2009; Hopkinson et al., 2008;
Windelinckx et al., 2007; Wang et al., 2006; Grundberg et al.,
2004; Vandevyver et al., 1999; Geusens et al., 1997) and
susceptibility to a range of diseases such as cardiovascular
disease (Chen et al., 2011), osteoporosis (Kiel et al., 2007) and
sarcopenia (Roth et al., 2004). The T/C transition (rs10735810
T/C) in exon 2 of the VDR gene changes the translation start
site. The C allele (also called F allele – absence of the
endonuclease FokI restriction site) carriers have a 3-amino acid
shorter VDR than do individuals with the T allele (or f allele –
presence of the FokI restriction site). The shorter VDR has
enhanced transactivation capacity as a transcription factor
(Whitfield et al., 2001). Rabon-Stith et al. (2005) studied VDR
genotypes of 206 healthy men and women (50-81 years old)
before and after either aerobic exercise training or strength
training. VDR FokI genotype was significantly related to the
femoral neck bone mineral density in response to strength
training, but not aerobic training. More specifically, the
heterozygotes (TC) in the strength training group approached a
significantly greater increase in femoral neck bone mineral
density compared to TT homozygotes. The study investigating
the contribution of the VDR rs10735810 T/C genotype on total
body bone mineral density among Japanese athletes (weight-
bearing (n = 84) and swimming (n = 48)) and 80 non-athletic
controls suggested that the CC genotype was more responsive
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to impact loading in regulating total bone mineral density.
Enhanced bone mineral density in weight-bearing athletes was
found in C allele carriers (Nakamura et al., 2002). Furthermore,
Hopkinson et al. (2008) have found that both patients with
chronic obstructive pulmonary disease (n = 107) and control
subjects (n = 104) who were homozygous for the C allele of the
FokI polymorphism had less quadriceps strength than did those
with TC or TT genotype. Micheli et al. (2011) have observed
significant differences in VDR FokI genotype frequencies
between medium-high-level male soccer players (n = 125) and
sedentary controls. Homozygous TT genotype of the VDR gene
was significantly more represented in young soccer players than
in a matched sedentary population. There was evidence that
VDR FokI polymorphism affected bone mass in 46 Brazilian
adolescent soccer players (Diogenes et al., 2010). Boys with the
TC genotype had higher total body bone mineral content and
density compared to those with CC genotype. It was suggested
that effect of the FokI polymorphism on bone mineralization
occurs during bone maturation, possibly at the initial pubertal
stages.
Combined impact of gene variants on elite athlete
status
Despite the obvious role of genetics in human athletic
performance, there is little unequivocal evidence in support of a
specific genetic variant with a major gene effect on a relevant
performance phenotype, at least across the normal range of
human trait distributions. This may be because complex traits
are fundamentally polygenic (numerous genes with small
effects), or because researchers failed to take into consideration
the full range of environmental effects, or both (Brutsaert and
Parra, 2006). It is very important to note that each DNA locus
can probably explain a very small proportion of the phenotypic
variance (e.g. ~0.1% to ~1%). Therefore, very large sample
sizes are needed to detect associations and various
combinatorial approaches should be used. To date, few studies
have sought to define or quantify the impact of multiple
genotype combinations that influence human physical
performance (Buxens et al., 2011; Eynon et al., 2011b; Hughes
et al., 2011; Muniesa et al., 2010; Ruiz et al., 2010a; Santiago et
al., 2010; Ahmetov et al., 2009b; Gómez-Gallego et., 2009b;
Ruiz et al., 2009; Ahmetov et al., 2008e; Williams and Folland,
2008; Saunders et al., 2006; Williams et al., 2004). Williams et
al. (2004) had shown evidence for an interaction between the
BDKRB2–9/+9 and ACE I/D polymorphisms in 115 British
subjects, with individuals who were carriers of the ACE II +
BDRRB2 –9/–9 genotype combination having the highest
efficiency of muscular contraction. Furthermore, the
ACE(I)/BDRRB2(–9) (“high kinin receptor activity”) haplotype
was significantly associated with the distance of the preferred
endurance event among elite British athletes (P = 0.003).
Similarly, Saunders et al. (2006) found that the NOS3 Glu298
allele combined with a BDKRB2 –9/–9 genotype was over-
represented in the fastest-finishing Ironman triathletes (28.6%)
compared with controls (17.3%; P = 0.028). Gómez-Gallego et
al. (2009b) had shown that professional road cyclists with the
most strength/power oriented genotype combination, namely
ACE DD + ACTN3 RR/RX, had higher respiratory compensation
threshold values than those with the intermediate combinations
(II + RX/RR, P = 0.036; and DD + XX, P = 0.0004) but similar to
those with the II + XX genotype combination. In a study of 173
Russian rowers, the prevalent combination of ACE I/D, ACTN3
R577X and PPARA intron 7 G/C genotypes in all groups was
ID-RX-GG, and its frequency in elite rowers was different
compared to controls (28.6% vs. 17.3%) (Ahmetov et al., 2008e).
Furthermore, the total frequency of the ACE I, ACTN3 R577,
UCP2 55Val and UCP3 rs1800849 T alleles in highly elite
Russian rowers was 57.1% (P = 0.027 in comparison with
controls (41.2%)). An increasing linear trend of the total
favourable allele frequency with increasing level of rowing
achievement has also been reported (41.9% (non-elite) → 43%
(sub-elite) → 45.8% (elite) → 57.1% (highly elite)) (Ahmetov et
al., 2008e). Recently, Ahmetov et al. (2009b) assessed the
combined impact of 10 gene polymorphisms on endurance
athlete status in a study of 1,432 Russian athletes and 1,132
controls. Firstly, athletes and controls were classified according
to the number of ‘endurance’ polymorphic alleles (NFATC4
Gly160, PPARA rs4253778 G, PPARD rs2016520 C,
PPARGC1A Gly482, PPARGC1B 203Pro, PPP3R1 promoter 5I,
TFAM 12Thr, UCP2 55Val, UCP3 rs1800849 T and VEGFA
rs2010963 C) they possessed. The ‘endurance’ score ranged
from 3 to 13 for controls, and from 5 to 14 for the predominantly
endurance-oriented athletes (athletes of long endurance and
middle endurance groups; n = 578). The most frequently
observed number of ‘endurance’ alleles in controls and
endurance-oriented athletes was 8 (21.7%) and 9 (24.6%)
respectively. On this basis, all subjects were classified into two
groups as having a low (≤ 8) or high (≥ 9) number of ‘endurance’
alleles. The proportion of subjects with a high number of
‘endurance’ alleles was significantly larger in the mixed
(aerobic/anaerobic) group (non-elite: 45.6%, P = 0.038; sub-elite:
62.9%, P = 0.0026; elite: 60.0%, P = 0.042), in the short-
endurance group (non-elite: 46.2%, P = 0.28; sub-elite: 60.0%,
P = 5.6 x 10-4; elite: 70.5%, P = 0.0060), in the middle-
endurance group (non-elite: 44.1%, P = 0.18; sub-elite: 62.4%,
P = 4.0 x 10-8; elite: 71.7%, P = 1.8 x 10-5) and in the long-
endurance group (non-elite: 56.6%, P = 2.3 x 10-6; sub-elite:
75.0%, P = 8.7 x 10-9; elite: 76.4%, P = 1.0 x 10-8) compared to
controls (37.8%). On the contrary, the proportion of athletes with
high number of ‘endurance’ alleles from the power group was
not significantly different from controls (non-elite: 40.6% (n =
261); sub-elite: 41.4% (n = 116); elite: 40.4% (n = 104)).
Furthermore, the largest difference was seen when the top elite
predominantly endurance-oriented athletes only (n = 21) were
compared to controls (85.7% vs. 37.8%, P = 7.6 x 10-6). The
combined impact of the 10 gene polymorphisms on the two
intermediate endurance phenotypes, namely the proportion of
slow-twitch muscle fibres in m. vastus lateralis of physically
active healthy men (n = 45) and maximal oxygen consumption
in rowers of the national competitive standard (VO2max 55.7 ±
0.9 ml/min/kg; n = 50) was also examined. The number of
‘endurance’ alleles positively correlated with the proportion of
slow-twitch fibers (r = 0.50; P = 4.0 x 10-4) and with the maximal
oxygen consumption of rowers (r = 0.46; P = 7.0 x 10-4)
(Ahmetov et al., 2009b). Ruiz et al. (2009) analysed seven
genetic polymorphisms (ACE, ACTN3, AMPD1, CKMM, HFE,
GDF8 and PPARGC1A) in 46 world-class endurance athletes
and 123 controls. Using the model developed by Williams and
Folland (2008), they determined that the mean ‘total genotype
score’ (TGS, from the accumulated combination of the seven
polymorphisms, with a maximum value of ‘100’ for the
theoretically optimal polygenic score) was higher in athletes
(70.2 ± 15.6) than in controls (62.4 ± 11.5) and also higher than
predicted for the total Spanish population (60.8 ± 12.1),
suggesting an overall more ‘favorable’ polygenic profile in the
athlete group (Ruiz et al., 2009). In a following study, Ruiz et al.
(2010a) determined the TGS in 53 elite power athletes (jumpers,
sprinters), 100 endurance athletes (distance runners and road
cyclists) and 100 non-athletic controls using six polymorphisms
(ACE I/D, ACTN3 R577X, AGT Met235Thr, GDF8 K153R, IL6 -
174 G/C, and NOS3 -786T>C). The mean TGS was significantly
higher in power athletes (70.8 ± 17.3) compared with endurance
athletes (60.4 ± 15.9; P < 0.001) and controls (63.3 ± 13.2; P =
0.012), whereas it did not differ between the latter two groups.
Additionally, Eynon et al. (2011b) analysed the endurance
polygenic profile of 74 Israeli endurance athletes, 81 power
athletes and 240 non-athletes using six gene polymorphisms in
the PPARGC1A-NRF-TFAM pathway (GABPB1 (NRF2)
rs12594956 A/C, GABPB1 rs7181866 A/G, GABPB1 rs8031031
Genes for athletic performance
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C/T, PPARA rs4253778 G/C, PPARD rs2016520 T/C,
PPARGC1A Gly482Ser). The TGS was significantly higher (P <
0.001) in endurance athletes (38.9 ± 17.1) compared with
controls (30.6 ± 12.4) or power athletes (29.0 ± 11.2). Finally,
Buxens et al. (2011) compared genetic profiles in two Spanish
cohorts of world-class endurance (n = 100) and power male
athletes (n = 53) using DNA-microarray technology (36 genetic
variants (within 20 different genes). Stepwise multivariate
logistic regression showed that the rs1800795 (IL6 -174 G/C),
rs1208 (NAT2 K268R) and rs2070744 (NOS3 -786 T/C)
polymorphisms significantly predicted sport performance. The
contribution of the studied genetic factors to sports performance
was 21.4%.
Summary
It has long been recognized that the interindividual variability of
physical performance traits and the ability to become an elite
athlete have a strong genetic basis. The question is no longer
whether or not there is a genetic component to athletic potential
and endurance or strength trainability, but exactly which genes
(out of ~23000 human genes) and DNA
polymorphisms/mutations (out of >50 million SNPs, indels,
CNVs. and mutations) are involved and by which mechanisms
and pathways they exert their effect. Our current progress
towards answering these questions still represents only the first
steps towards a complete understanding of the genetic factors
that influence human physical performance. The next decade
will be an exciting period for sports genomics, as we apply the
new DNA technologies (like whole genome sequencing,
genome-wide association studies (GWAS) etc.) and
bioinformatics to further dissect and analyze the genetic effects
on human physical ability. Efforts to perform GWAS in the
cohorts of athletes are presently underway (at least athletes
from Ethiopia, Jamaica, Kenya, Russia and USA) (Fuku et al.,
2010).
The current review provides evidence that at least 79 genetic
markers (located within 40 autosomal genes, mitochondrial DNA
and Y-chromosome) are linked to elite athlete status (59
endurance-related and 20 power/strength-related genetic
markers). However, it should be emphasized that most (74.7%)
of the case-control and association studies have not yet been
replicated in independent samples. Further, each contributing
gene can explain only a small portion of the observed
interindividual differences in training-induced effects, and there
is still no evidence that the identified variants have substantial
predictive value for prospectively identifying potential elite
athletes. Since DNA polymorphisms for athletic performance do
not fully explain the heritability of athlete status, other forms of
variation, such as rare mutations and epigenetics marks (i.e.
stable and heritable changes in gene expression), must be
considered (Tennessen et al., 2012; Baar 2010). The issues
with respect to appropriate study designs, sample size,
population stratification and quality of the genotype/phenotype
measurement are also of great importance. Future research
should be also focused on identifying genetic markers
associated with other sport-related phenotypes, such as
flexibility, coordination and temperament of elite athletes. The
impact of genetics in sports and exercise appears to have
multiple influences. Its positive effect on exercise performance
must be combined with effective training programs and
favourable lifestyle habits for success in sports and health
benefits. Accordingly, one of the applications of sports genetics
could be the development of predictive genetic performance
tests. Furthermore, the application of genetic testing in sports
could provide new opportunities for sports clubs to understand
athletes’ susceptibility for certain pathological states (injuries,
cardiomyopathies, sudden death etc.), map genetic suitability
for specific team positions and roles, and to gain insights into
athletes’ development in various sports or physical activities.
Conclusion
To conclude, sports genomics is still in the discovery phase and
abundant replication studies are needed before these largely
pioneering findings can be extended to practice in sport. Future
research including genome-wide association studies, whole-
genome sequencing, epigenetic, transcriptomic and proteomic
profiling will allow a better understanding of genetic make-up
and molecular physiology of elite athletes.
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