Introduction
Population differences in cancer incidence may reflect differences in genotype and intake of, or exposure to cancer promoting or preventative factors. Identification of genetic risk factors for cancer often utilises linkage studies in high-risk families, but this approach has proved difficult when applied to prostate cancer due to interacting lifestyle and environmental factors (Crawford, 2003; Xu, Sun & Zheng, 2013). The only clearly established risk factors for prostate cancer are increasing age, family history of prostate cancer and ethnicity (Crawford, 2003; Nordström et al., 2013; Sun et al., 2011), although adoption of a Western diet, increased life expectancy and PSA testing are thought to contribute to the rise in detection of prostate cancer in Asian countries (Xu, Sun & Zheng, 2013).
Although there is evidence for a significant hereditary component of prostate cancer susceptibility, results are inconsistently replicated. A positive family history of prostate cancer is associated with increased risk, but relative risk (RR) ratios vary from one study to the next (Goh et al., 2012). Twin studies have been used to reveal the heritability of prostate cancer and values have ranged from 0.36 to 0.57 (Ahlbom et al., 1997; Lichtenstein et al., 2000; Neale et al., 2005; Page et al., 1997) leaving no doubt regarding a strong genetic component. In addition, in a review of genetic association studies, Xu et al. (Goh et al., 2012; Xu, Sun & Zheng, 2013) concluded that RR of prostate cancer was highest if a primary relative, particularly a brother, was diagnosed with prostate cancer before the age of 60 years.
In numerous studies the association between single nucleotide polymorphisms (SNPs) in the 8q24 region and prostate cancer, have been reported (Amundadottir et al., 2006; Gudmundsson et al., 2007; Wang et al., 2011). For example the A allele of SNP rs1447295was associated with an increased prostate cancer risk in Japanese, Native, Latino, African and European Americans (Freedman et al., 2006; Gudmundsson et al., 2007; Severi et al., 2007). However, reports on this SNP explain only a portion of the signal described (Amundadottir et al., 2006), and fail to account for all of the heritability. Of the five haplotype blocks (on 8q24) associated with various cancers, three solely and independently contribute to prostate cancer risk (Ghoussaini et al., 2008).
Clinical characteristics play an important role in the selection of appropriate treatment and prognosis for prostate cancer (Heidenreich et al., 2014). However, it is likely that clinical characteristics interact with environmental and genetic risk factors to determine risk of prostate cancer progression. The environmental factors that have been identified as playing a possible role in the development or progression of prostate cancer include various aspects of dietary intake, alcohol consumption, tobacco use, physical activity levels and energy balance, although evidence is inconsistent (Wolk, 2009; Xu, Sun & Zheng, 2013). However, it is difficult to clearly delineate risk due to the influence of confounding factors as it is difficult or impossible to control the effect of numerous variables and thus tease out the impact of individual factors. However, an individual’s genes, physiological state and environmental exposures must be considered when assessing disease risk and recommending treatment and lifestyle interventions (Davis & Milner, 2007).
SNPs found in 8q24 regions 1-3 and thought to be associated with prostate cancer risk will be examined in this study and tested for interactions with clinical and environmental factors in a New Zealand population.
Materials and Methods
A retrospective case-control, population-based study was performed to explore the association between 8q24 genotypes and the clinical manifestations of prostate cancer.
A total of 916 male participants (489 with prostate cancer and 427 healthy controls) were recruited from Auckland, New Zealand (NZ) between 2006 and 2014. The study was more than adequately powered based on calculations carried out prior to recruitment on expected GPX1 rs1050450T allele frequency (24 volunteers were required for each group based on a difference in allele frequency of 0.058, significance = 0.05% and power = 80%). Only those who self-reported as having European ancestry were included in this analysis. Due to very small numbers, and therefore low statistical power, it was decided not to analyse data from other ethnic groups. Control participants were a group with no known cancers at recruitment (with the exception of skin cancers). The volunteers were recruited with written informed consent and formed part of either the Urology Study or the Selenium Supplementation Study carried out by the Auckland Cancer Society Research Centre, University of Auckland after receiving approval of the study from the Health and Disabilities Ethics Committees: Northern Y Regional Ethics Committee, NZ, (Ethics Ref: NTY/05/06/037 and NTY/06/07/060). Men with prostate cancer who met the study requirements were selected from the databases from the Auckland Regional Urology facility. This database incorporated the Auckland District Health Board, Counties Manukau District Health Board, Waitemata District Health Board and private practices within the Auckland region. Hardcopy invitations were sent to all eligible men with an approximately 25% response rate. Among the Selenium Supplementation Study participants, only those who consented to the use of their blood samples for future NZ Ethics Committee accredited studies were used in this analysis. The following data were collected and analysed: date of birth, height, weight, chronic medication, smoking status, family history of cancer, diagnostic PSA and Gleason score (where relevant). Data were collected at the time of enrolment. For the prostate cancer group, enrolment initially took place within 12 months of diagnosis (60.2% of those enrolled) and thereafter enrolment criteria were modified such that diagnosis could have taken place at any time prior to enrolment. Gleason scores were obtained from biopsy histopathology unless participants underwent a prostatectomy, in which case the post-surgical Gleason score was used. Alcohol consumption was categorised as “Yes” or “No” such that “Yes” applied to anyone who consumed one or more alcoholic units per week over the past year (prior to recruitment). Smoking was categorised as “never” or “ever” smoked. “Ever” smoked presented both “present” and “former” smokers, as there was insufficient power to analyse “present” smokers on their own. The study investigators were not blinded to group allocation.
Blood collection and processing: Blood samples were collected into EDTA vaccutainer tubes (Becton Dickinson, Plymouth, England) from study participants at enrolment. Total genomic DNA extraction was carried out with the QIAamp DNA Blood Mini Kit (Qiagen, Hilden, Germany). A fully automated procedure on the QIAcube (Qiagen) was followed according to the manufacturer’s recommendations. DNA was quantified and checked for purity using a Nanodrop ND1000 (Thermo Fisher Scientific, Waltham, MA, USA), stored at −20 °C and used for genotyping at a concentration of 10 ng/µl.
Genotyping: SNPs were selected based on results from a literature search targeting SNPs that are associated with prostate cancer and found on chromosome 8q24 (Al Olama et al., 2009b; Ghoussaini et al., 2008; Gudmundsson et al., 2009; Gudmundsson et al., 2007; Pal et al., 2009). None of the SNPs at the time of selection were known to be in LD with each other, and SNPs subsequently found to be in LD were removed from the analysis. Genotyping was performed using a Sequenom MassArray system (Sequenom, San Diego, CA, USA). The products were spotted and fired and run on a MALDI-TOF mass spectrometer. The quality of the genotyping was assessed by checking the results from CEU HapMap samples (n = 6) and comparing them with SNP data available on the HapMap Genome Browser release #28, build #37.3 (http://hapmap.ncbi.nlm.nih.gov), as well as by comparing results from duplicate samples. SNP data are deposited in the Figshare repository figshare.com/s/750929b0829d11e583c306ec4bbcf141.
| SNP | Tested Allele | Published OR | Weight LN (OR) | % of total weight | Source |
|---|---|---|---|---|---|
| rs10086908 | T | 1.25 from stage 1 | 0.223 | 5.94% | Al Olama et al. (2009b) |
| rs1016342 | C | 1.26 | 0.231 | 6.15% | Pal et al. (2009) |
| rs1016343 | T | 1.11 | 0.104 | 2.77% | Al Olama et al. (2009b) |
| rs1378897 | A | 1.26 (ns) | 0.231 | 6.15% | Pal et al. (2009) |
| rs1447295 | A | 1.58 | 0.457 | 12.17% | Gudmundsson et al. (2009) |
| rs16901979 | A | 1.8 | 0.588 | 15.65% | Gudmundsson et al. (2009) |
| rs16902094 | G | 1.21 | 0.191 | 5.09% | Gudmundsson et al. (2009) |
| rs4242382 | A | 1.39 | 0.329 | 8.76% | Teerlink et al. (2014) |
| rs445114 | T | 1.14 | 0.131 | 3.49% | Gudmundsson et al. (2009) |
| rs620861 | C | 1.11 from stage 1 (ns) | 0.104 | 2.77% | Al Olama et al. (2009b) |
| rs6470494 | T | 1.00a | 0.0 | 0.0% | Pal et al. (2009) |
| rs6470517 | A | 1.58 | 0.457 | 12.17% | Pal et al. (2009) |
| rs6983267 | G | 1.19 | 0.174 | 4.63% | Al Olama et al. (2009b) |
| rs7000448 | T | 1.23 | 0.207 | 5.51% | Ghoussaini et al. (2008) |
| rs871135 | G | 1.39 | 0.329 | 8.76% | Pal et al. (2009) |
DOI: 10.7717/peerj.1731/table-1
Notes:
aOR from Pal et al. (2009) was 1.00. In Liu, Wang & Han (2011) a meta-analysis was carried out with the following results: GWAS meta-analysis OR = 1.14; Replication meta-analysis OR = 1.00; All meta-analyses OR = 1.14. It was decided to use the OR value from the Replication meta-analysis.
SNP
Single nucleotide polymorphism
ns
Not significant
OR
Odds ratio
LN
Natural log
Genetic Risk Score (GRS): A GRS was calculated in order to evaluate the accumulative effects of all the 8q24 SNPs tested. A weighted GRS was created by using 15 SNPs assessed in this study (Table 1) (De Jager et al., 2009). Firstly, the weight value of each SNP was calculated by using the natural log of the published odds ratios and assigning the weight value of each SNP made up to a total of 100%. Secondly, the weighted GRS (named wGRS15 in this study) was calculated by multiplying the weighted value of the SNP by the number of the tested allele of the SNP for each participant. Thirdly, these values were then summed across all of the 15 SNPs (De Jager et al., 2009).
Statistical Analysis: The outcome of interest, namely recorded pathology was fitted for association with 15 candidate SNPs found on chromosome 8q24. Four phenotypic variables (smoking status, alcohol consumption, age at diagnosis/joining the study, and body mass index (BMI)) were tested with the outcomes of interest using a multivariate analysis and squared data. Smoking status, alcohol consumption, and age at diagnosis (cases) were significantly associated with histology and hence these variables were adjusted for prior to further analyses. A generalised linear model was fitted to test the linearity of the genotype-phenotype relationship. For linearity of the genotype-phenotype relationship, an additive model was used whereby each SNP was coded 0, 1, and 2 (Balding, 2006).
All analyses were corrected for multiple testing using a false discovery rate (FDR) (Storey, 2002). SAS (V9.2 SAS Institute., Cary, NC, USA) and R (R Foundation for Statistical Computing, 2012) were used for statistical analyses.
| Phenotypic variables | Status | Malignanta (N = 489) | Controla (N = 427) | OR (95% CI) | P value |
|---|---|---|---|---|---|
| Smoking status: N (%) | Ever smoked (Current/Former) | 227 (64.5) | 144 (37.0) | 2.28 (1.62–3.21) | 2.32e−06 |
| Never | 125 (35.5) | 245 (63.0) | 1.00 | ||
| 137 | 38 | ||||
| Alcohol: N (%) | Yes | 265 (75.3) | 338 (86.4) | 0.57 (0.37-0.90) | 0.0147 |
| No | 87 (24.7) | 53 (13.6) | 1.00 | ||
| Missing Datab | 137 | 36 | |||
| Age at Diagnosis: Mean (SD) | 65.8 (8.2) | 53.1 (13.6) | 1.10 (1.08–1.12) | 9.88e−27 | |
| BMI: Mean (SD) | 27.3 (3.8) | 26.8 (3.7) | 1.02 (0.98–1.07) | 0.2934 |
DOI: 10.7717/peerj.1731/table-2
Notes:
aN, Sample size (complete data set for all four variables with no missing data); OR, Odds ratio; CI, Confidence interval; SD, Standard deviation; BMI, Body mass index; “Yes”, 1 or more alcoholic units a week;
bMissing Data, At least one missing datum point amongst the four variables.
Results
The control group comprised of healthy men with no history of cancer (excluding melanoma) and a PSA below 4 ng/ml. The control group was significantly younger (mean age = 53.1 years) than the men with prostate cancer (mean age 65.8 years). Within five years of enrolment 9 men from the control group had developed prostate cancer and were enrolled as volunteers on the Urology study. Tumour staging data were not used as less than 50% of the data were available. Gleason scores ranged from 4 to 10 with 36% of volunteers with a Gleason score of 6 or less, 45% with a Gleason score of 7 and 20% with a Gleason score of 8 or greater.
Smoking status was tested for association with prostate cancer (Table 2), and there were significantly more “Ever” smoked among those with prostate cancer compared to controls, with an odds ratio (OR) of 2.28 (95% CI [1.62–3.21]). An OR of 0.57 (95% CI [0.37–0.90]) was associated with alcohol consumption, indicating that fewer men with prostate cancer drank one or more alcoholic units per week, than healthy men. After performing a multivariate analysis it was found that as healthy men age, they tend to drink less, whereas men with prostate cancer drink comparatively more than healthy men of a similar age (p = 3.24 e–07). In contrast, older men who smoked were more likely to have prostate cancer than those who never smoked (p = 4.63 e–14). No significant association was found between BMI and prostate cancer. Smoking status, alcohol consumption and age of diagnosis were adjusted for further genotypic analysis. SNP locations are shown in Fig. 1 and Table 3. A risk assessment on malignancy in association with the SNPs is shown in Table 4. Rs16901979and rs6983561were both found to be in strong LD (D′ = 0.999, p = 2.22e–16). For this reason rs6983561was removed from all analyses. Four polymorphisms ( rs10086908(T allele), rs16901979(A allele), rs1447295(A allele) and rs4242682(A allele)) showed an increased risk of prostate cancer compared to the controls before and after adjustment for confounding variables, and remained significant after applying an FDR (Table 4).
Enlarge this image.Figure 1: Schematic of 8q24 chromosomal region. Localisation of single nucleotide polymorphisms on 8q24.21 which were tested in this study and show association with prostate cancer risk and/or progression. C-MYC and FAM84B are known genes on 8q24 which border the so-called gene desert. The exact position of the SNPs can be found in Table 3. (Figure adapted from Kastler et al., (2010)). DOI: 10.7717/peerj.1731/fig-1
| SNP/gene | Genotype | Chromosome Position | SNP to Chromosome | Sequence length |
|---|---|---|---|---|
| FAM84B | 127564683–127570711 | 6029 | ||
| rs10086908 | C/T | 128011937 | Fwd | |
| PROSTATE CANCERT1 | 128025399–128033259 | 7861 | ||
| rs6470494 | C/T | 128087904 | Fwd | |
| rs1016342 | C/T | 128092455 | Fwd | |
| rs1016343 | C/T | 128093297 | Fwd | |
| rs1378897 | A/G | 128122659 | Fwd | |
| rs16901979 | A/C | 128124916 | Fwd | |
| rs16902094 | A/G | 128320346 | Fwd | |
| rs445114 | C/T | 128323181 | Fwd | |
| rs620861 | C/T | 128335673 | Rev | |
| rs6983267 | G/T | 128413305 | Fwd | |
| rs871135 | G/T | 128426393 | Fwd | |
| POU5F1B | 128427857–128429455 | 1599 | ||
| rs7000448 | C/T | 128441170 | Fwd | |
| rs6470517 | A/G | 128460404 | Fwd | |
| rs1447295 | A/C | 128485038 | Fwd | |
| rs4242382 | A/G | 128517573 | Fwd | |
| MYC | 128748315–128753680 | 5366 | ||
| PVT1 | 128902874–129113499 | 210626 |
DOI: 10.7717/peerj.1731/table-3
Notes:
SNP
Single nucleotide polymorphism
FAM84B
Family with sequence similarity 84, member B
PROSTATE CANCERT1
prostate cancer associated transcript 1
POU5F1B
POU class 5 homeobox 1B
MYC
v-myc avian myelocytomatosis viral oncogene homolog
PVT1
otherwise known as Pvt1 oncogene
| Tested Allele | N | OR (95% CI) | p value | q value | ||
|---|---|---|---|---|---|---|
| rs10086908 | Malignant | T | 364 | 1.64 (1.25–2.15) | 3.03E−04 | 0.0040 |
| Control | 390 | 1.00 | ||||
| rs16901979 | Malignant | A | 368 | 2.58 (1.48–4.50) | 8.42E−04 | 0.0056 |
| Control | 388 | 1.00 | ||||
| rs1447295 | Malignant | A | 362 | 1.70 (1.18–2.46) | 0.0047 | 0.0209 |
| Control | 389 | 1.00 | ||||
| rs4242382 | Malignant | A | 362 | 1.60 (1.10–2.33) | 0.0133 | 0.0444 |
| Control | 388 | 1.00 | ||||
| rs16902094 | Malignant | G | 366 | 1.31 (1.03–1.65) | 0.0260 | 0.0695 |
| Control | 387 | 1.00 | ||||
| rs1016342 | Malignant | C | 364 | 1.41 (1.02–1.95) | 0.0369 | 0.0822 |
| Control | 389 | 1.00 | ||||
| rs445114 | Malignant | T | 353 | 1.19 (0.93–1.54) | 0.1729 | 0.3300 |
| Control | 392 | 1.00 | ||||
| rs620861 | Malignant | C | 370 | 1.14 (0.90–1.46) | 0.2798 | 0.3965 |
| Control | 369 | 1.00 | ||||
| rs6983267 | Malignant | G | 362 | 1.14 (0.90–1.46) | 0.2803 | 0.3965 |
| Control | 391 | 1.00 | ||||
| rs871135 | Malignant | G | 355 | 1.14 (0.89–1.44) | 0.2967 | 0.3965 |
| Control | 390 | 1.00 | ||||
| rs7000448 | Malignant | T | 360 | 0.92 (0.72–1.18) | 0.5032 | 0.6113 |
| Control | 386 | 1.00 | ||||
| rs1016343 | Malignant | T | 345 | 1.06 (0.79–1.41) | 0.7172 | 0.7986 |
| Control | 398 | 1.00 | ||||
| rs6470494 | Malignant | T | 370 | 1.04 (0.81–1.34) | 0.7794 | 0.8004 |
| Control | 390 | 1.00 | ||||
| rs1378897 | Malignant | A | 372 | 1.05 (0.64–1.73) | 0.8386 | 0.8004 |
| Control | 380 | 1.00 | ||||
| rs6470517 | Malignant | A | 337 | 1.00 (0.68–1.45) | 0.9836 | 0.8762 |
| Control | 391 | 1.00 | ||||
| wGRS15 | Malignant | 283 | 1.10 (1.04–1.15) | 3.14E−04 | ||
| Control | 341 | 1.00 |
DOI: 10.7717/peerj.1731/table-4
Notes:
Bold text indicates statistically significant values.
N
Sample size
OR
Odds ratio
CI
Confidence interval
wGRS15
Weighted genetic risk score based on 15 single nucleotide polymorphisms
Q-value
p-value after correction for multiple testing (Storey, 2002)
The wGRS15 and histology were significantly associated (Table 4) and graphically shown in Fig. 2. As the influence of the risk alleles on prostate cancer increases there is greater variance between the prostate cancer cases and healthy controls (Fig. 2).
Enlarge this image.Figure 2: Genetic risk score. Presentation of weighted genetic risk score differences using 15 genetic polymorphisms found in the 8q24 chromosomal region. DOI: 10.7717/peerj.1731/fig-2
Discussion
In a Caucasian population residing in NZ, we evaluated clinical characteristics as well as 15 SNPs located in the 8q24 chromosomal region that may independently confer susceptibility to prostate cancer. The search for genetic and lifestyle risk factors for prostate cancer is challenging due to varying results from different populations throughout the world and the need to and difficulty associated with controlling for numerous variables. The results presented here help to answer the question regarding the impact of BMI, age, smoking and alcohol intake, as well as polymorphisms in 8q24, on the risk of developing prostate cancer.
Numerous genome wide association studies have been carried out in large case-control studies in order to identify SNPs with small effects on prostate cancer risk and progression. Over 80 common SNPs have been estimated to contribute to prostate cancer risk (Han et al., 2015) and 33% of familial risk is associated with known SNPs (Al Olama et al., 2014). Although in many cases the contribution to genetic risk and interaction with treatment type is understood, the interaction with environmental influences remains to be elucidated (Eeles et al., 2014).
One of the problems associated with comparing results of studies carried out in different countries (with differing PSA testing policies) and in different communities, with varying degrees of uptake of available medical services, is that men in the different studies are diagnosed at a different stage of prostate cancer. PSA is a biomarker that was initially used to monitor response to treatment and since the early 1990’s has been used as an indicator for suspicion of asymptomatic prostate disease (Cooner et al., 1990). A problem arises as detection of prostate cancer using PSA as a screening method identifies lesions whose biological behaviour might not be the same as those identified due to clinical symptoms. In a country where a PSA screening programme is in place over a long period of time, one would expect most men to be recruited in the early stages of disease relative to a study carried out where PSA screening is not encouraged. Also, in the former one would expect to enrol more men with prostate cancer that might remain symptomless i.e., men who would die with prostate cancer and not from prostate cancer. NZ does not recommend PSA screening for asymptomatic men but the National Health Committee agree that prostate cancer is a suitable candidate for screening (NHC, 2004) and for example, one in four men over the age of 40 years living in the Waikato District of NZ were tested for PSA in 2010 (Hodgson et al., 2012). Of these, 71% were asymptomatic (Hodgson et al., 2012). For this reason one would expect a cohort of NZ men diagnosed with prostate cancer to consist of both early and later stage disease, and this is likely the case if Gleason score is considered as an indicator. Despite the increasing awareness of the risk of prostate cancer and the availability of the PSA test as an indicator of prostate cancer suspicion, those with a Gleason score of 8 or greater comprised 20% of the cohort, i.e., they were not diagnosed at an early stage of disease.
Numerous studies report no association between smoking and diagnosis of prostate cancer (Giovannucci et al., 2007; Wolk, 2005), although Giovannucci et al. (2007) and others have found that smoking is associated with an increased odds ratio of developing aggressive prostate cancer. In our study smoking tobacco was significantly associated with prostate cancer risk (Table 2). No association was found between smoking and Gleason score (data not shown). Hereafter smoking was regarded as a confounding variable and adjusted for in further analyses (Table 2).
The lack of an association between BMI and prostate cancer incidence or more aggressive disease in our study could reflect the real lack of an association or it could be due to the inability of this study to adequately address this question. BMI was calculated at the time of enrolment, which varied from within 3 months to 8 years since diagnosis. However, just over 60% of volunteers with prostate cancer were enrolled within 12 months of diagnosis. BMI may have fluctuated over the lifespan and may also have changed since diagnosis and hence the measurement obtained may not reflect the BMI that influenced prostate cancer incidence. A cancer diagnosis sometimes evokes questions regarding causality, and some of our study participants self-reported a change in lifestyle with respect to smoking status, alcohol consumption, exercise and/or diet. Some of these lifestyle changes were maintained and were measurable (e.g., smoking cessation), whilst others (such as cooking methods and a decrease in animal fat intake) were not so easy to define and fluctuated over time. In addition to diagnosis, increasing age may influence lifestyle. In this study we know that fewer men with prostate cancer, drank alcohol than men who were healthy, but we also found that this association was confounded by age such that fewer older men with prostate cancer drank alcohol. Although there is evidence to support the view that alcohol consumption decreases with age, conflicting data also exists (Thomas & Dilip, 1999).
In contrast to the negative association between age and alcohol consumption, in this study age was positively associated with ever smoked and prostate cancer, thus supporting the view that risk of prostate cancer increases with age and smoking of tobacco. For this reason it is difficult to analyse the effect of some lifestyle changes on prostate cancer progression retrospectively and the time delay between diagnosis and enrolment is a limitation of this study.
Numerous risk loci for prostate cancer have been identified including a number in chromosome 8q24 (Amundadottir et al., 2004; Helfand et al., 2010; Kim et al., 2010; Okobia et al., 2011) and we tested 15 SNPs in chromosome 8q24.21 (Table 4) that were thought to contribute to prostate cancer risk, mortality, high Gleason scores or biochemical recurrence. The importance of this region was first implicated in prostate cancer in a genetic linkage analysis in Icelandic families (Amundadottir et al., 2006) and more recently has been proposed as a chromatin regulatory hub (Du et al., 2015). Chromosome aneusomy, including the gain of the 8q24 (MYC) region, has been reported from radical prostatectomy specimens (both carcinoma and adjacent tissues) in those with prostate cancer as well as from 15% of benign prostatic hyperplasia tissue (Zhang et al., 2014). This indicates that these chromosomal changes may occur in the progression of carcinogenesis in prostate tissue. Evidence for prostate cancer association within the region is particularly strong, with five distinct linkage disequilibrium (LD) blocks, spanning a 440-kb interval on 8q24 harbouring risk variants (Al Olama et al., 2009a; Ghoussaini et al., 2008). Although chromosome 8q24 is often described as a gene desert (Kastler et al., 2010; Wasserman, Aneas & Nobrega, 2010) there are a number of genes and SNPs in this region that may lead to the development of prostate cancer (Fig. 1) and could collectively play a role as a biomarker. The closest known gene is c-MYC (Hawksworth et al., 2010). Other neighbouring genes include the pseudogene POU5F1P1 (Kastler et al., 2010), FAM84B (Ghoussaini et al., 2008) and PVT1 (Meyer et al., 2011) (Fig. 1).
C-MYC has an established role in carcinogenesis and is rearranged in approximately 15% of multiple myelomas (Glitza et al., 2015). C-MYC functions to regulate cell-cycle differentiation, proliferation and apoptosis (Albihn, Johnsen & Arsenian Henriksson, 2010) and hence it is an attractive candidate for an association with prostate cancer as these are important molecular targets for environmental variables in cancer prevention (Davis & Milner, 2007). C-MYC over-expression in prostate cancer enables androgen-independent growth and is associated with a Gleason score >5 (Karan et al., 2002; Yang et al., 2005). However, a number of authors have looked for an association between differences in c-MYC and miRNA transcription in normal and malignant tissues and 8q24 polymorphisms, yet no associations were found (Pomerantz et al., 2009; Ribeiro et al., 2007). Despite this, expression of c-MYC in early prostatic cancer tissues has been shown to be a good indicator for aggressive disease (Hawksworth et al., 2010).
The coding sequence for the gene POU5F1B is found in region 3 of chromosome 8q24 (also 4 exons and 3 transcriptional start sites are found in this region) and it is the only gene in this region with coding capacity. In addition it may play a role in regulating stem cell pluripotency (Nichols et al., 1998) and hence SNPs in this region may lead to prostate cancer susceptibility. Although Kastler et al. (2010) found a three-fold higher POU5F1P1 expression in prostate cancer tissue versus surrounding normal tissue, and Pal et al. (2009) have found an association between SNP variants in this region and susceptibility to prostate cancer (and in the case of rs6470517with aggressive prostate cancer), no association has consistently been made between gene expression and prostate cancer risk variants in 8q24 (Gudmundsson et al., 2007) or experimental design has not included both expression and risk variants (Kastler et al., 2010; Pal et al., 2009). SNPs that may be associated with POU5F1P1, namely rs1447295and rs4242383, were found to be significantly associated with prostate cancer both before and after adjustment for confounders and after correction for multiple testing (Tables 2 and 4). Rs1447295was one of the first variants in this region shown to have a strong association with prostate cancer risk in diverse populations (Amundadottir et al., 2006; Robbins et al., 2007; Yeager et al., 2007) and hence, in this respect, our data are consistent with that obtained by others.
Rs16901979was found to be significantly associated with prostate cancer in this study). This is in general agreement with the article by Gudmundsson et al. (2007) where rs16901979is believed to contribute 2–4% to the heritability of prostate cancer in Caucasian populations, but a vastly greater percentage of heritability in Negroid populations.
In addition to the difference in mean age between the cases and controls, a limitation of this study is the lack of a definitive test to confirm that those within the control group did not have prostate cancer. A negative biopsy of the prostate gland would be a suitable criterium for inclusion of volunteers into the control group, but this was not a reasonable expectation.
Conclusion
Prostate cancer is one of the most common cancers amongst men, yet suitable biomarkers to accurately and reliably identify prostate cancer are not available. In this study both modifiable and non-modifiable risk factors for prostate cancer have been identified. A genetic risk score was calculated based on the 15 SNPs tested and found to be significantly associated with prostate cancer. Smoking and age significantly contributed to the risk of developing prostate cancer, and this risk was further increased by the presence of five SNPs in the 8q24 chromosomal region. The results presented here help to answer the question regarding the impact of modifiable risk factors, as well as polymorphisms in 8q24, on the risk of developing prostate cancer.
Additional Information and Declarations
Competing Interests
Lynnette R. Ferguson is an Academic Editor for PeerJ.
Author Contributions
Karen S. Bishop conceived and designed the experiments, performed the experiments, wrote the paper, prepared figures and/or tables, reviewed drafts of the paper.
Dug Yeo Han analyzed the data, contributed reagents/materials/analysis tools, wrote the paper, prepared figures and/or tables, reviewed drafts of the paper.
Nishi Karunasinghe reviewed drafts of the paper, obtained ethical approval, set-up the cohorts; co-ordinated sample collection, processed the samples and stored them for future work.
Megan Goudie reviewed drafts of the paper, recruited and enrolled the volunteers with prostate cancer, obtained blood samples and obtain clinical data.
Jonathan G. Masters reviewed drafts of the paper, involved in patient recruitment, provided clinical advice.
Lynnette R. Ferguson contributed reagents/materials/analysis tools, reviewed drafts of the paper.
Human Ethics
The following information was supplied relating to ethical approvals (i.e., approving body and any reference numbers):
Health and Disabilities Ethics Committees: Northern Y Regional Ethics Committee, NZ.
Ethics Ref: NTY/05/06/037 and NTY/06/07/060.
Data Availability
The following information was supplied regarding data availability:
Figshare: https://figshare.com/s/750929b0829d11e583c306ec4bbcf141.
Funding
This work was supported by funding received from the New Zealand Cancer Society, Auckland Cancer Society, New Zealand; The Goodfellow Trust, New Zealand; and The A+ Trust, Auckland District Health Board, New Zealand. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Ahlbom A, Lichtenstein P, Malmström H, Feychting M, Pedersen NL, Hemminki K. 1997. Cancer in Twins: genetic and Nongenetic Familial Risk Factors. Journal of the National Cancer Institute 89:287-293
Albihn A, Johnsen JI, Arsenian Henriksson M. 2010. Chapter 6—MYC in oncogenesis and as a target for cancer therapies. In: George FVW, George K, eds. Advances in cancer research. Cambridge: Academic Press. Vol. 107:163-224
Al Olama AA, Kote-Jarai Z, Berndt SI, Conti DV, Schumacher F, Han Y, Benlloch S, Hazelett DJ, Wang Z, Saunders E, Leongamornlert D, Lindstrom S, Jugurnauth-Little S, Dadaev T, Tymrakiewicz M, Stram DO, Rand K, Wan P, Stram A, Sheng X, Pooler LC, Park K, Xia L, Tyrer J, Kolonel LN, Le Marchand L, Hoover RN, Machiela MJ, Yeager M, Burdette L, Chung CC, Hutchinson A, Yu K, Goh C, Ahmed M, Govindasami K, Guy M, Tammela TLJ, Auvinen A, Wahlfors T, Schleutker J, Visakorpi T, Leinonen KA, Xu J, Aly M, Donovan J, Travis RC, Key TJ, Siddiq A, Canzian F, Khaw K-T, Takahashi A, Kubo M, Pharoah P, Pashayan N, Weischer M, Nordestgaard BG, Nielsen SF, Klarskov P, Roder MA, Iversen P, Thibodeau SN, McDonnell SK, Schaid DJ, Stanford JL, Kolb S, Holt S, Knudsen B, Coll AH, Gapstur SM, Diver WR, Stevens VL, Maier C, Luedeke M, Herkommer K, Rinckleb AE, Strom SS, Pettaway C, Yeboah ED, Tettey Y, Biritwum RB, Adjei AA, Tay E, Truelove A, Niwa S, Chokkalingam AP, Cannon-Albright L, Cybulski C, Wokolorczyk D, Kluzniak W, Park J, Sellers T, Lin H-Y, Isaacs WB, Partin AW, Brenner H, Dieffenbach AK, Stegmaier C, Chen C, Giovannucci EL, Ma J, Stampfer M, Penney KL, Mucci L, John EM, Ingles SA, Kittles RA, Murphy AB, Pandha H, Michael A, Kierzek AM, Blot W, Signorello LB, Zheng W, Albanes D, Virtamo J, Weinstein S, Nemesure B, Carpten J, Leske C, Wu S-Y, Hennis A, Kibel AS, Rybicki BA, Neslund-Dudas C, Hsing AW, Chu L, Goodman PJ, Klein EA, Zheng SL, Batra J, Clements J, Spurdle A, Teixeira MR, Paulo P, Maia S, Slavov C, Kaneva R, Mitev V, Witte JS, Casey G, Gillanders EM, Seminara D, Riboli E, Hamdy FC, Coetzee GA, Li Q, Freedman ML, Hunter DJ, Muir K, Gronberg H, Neal DE, Southey M, Giles GG, Severi G, Breast and Prostate Cancer Cohort Consortium (BPC3), PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium, COGS (Collaborative Oncological Gene-environment Study) Consortium, GAME-ON/ELLIPSE Consortium, Cook MB, Nakagawa H, Wiklund F, Kraft P, Chanock SJ, Henderson BE, Easton DF, Eeles RA, Haiman CA+158 more. 2014. A meta-analysis of 87,040 individuals identifies 23 new susceptibility loci for prostate cancer. Nature Genetics 46:1103-1109
Al Olama AA, Kote-Jarai Z, Giles GG, Guy M, Morrison J, Severi G, Leongamornlert DA, Tymrakiewicz M, Jhavar S, Saunders E, Hopper JL, Southey MC, Muir KR, English DR, Dearnaley DP, Ardern-Jones AT, Hall AL, O’Brien LT, Wilkinson RA, Sawyer E, Lophatananon A, Horwich A, Huddart RA, Khoo VS, Parker CC, Woodhouse CJ, Thompson A, Christmas T, Ogden C, Cooper C, Donovan JL, Hamdy FC, Neal DE, Eeles RA, Easton DF+25 more. 2009b. Multiple loci on 8q24 associated with prostate cancer susceptibility. Nature Genetics 41:1058-1060
Al Olama A, Kote-Jarai Z, Giles G, Guy M, Morrison J, Severi G, Leongamornlert DA, Tymrakiewicz M, Jhavar S, Saunders E, Hopper JL, Southey MC, Muir KR, English DR, Dearnaley DP, Ardern-Jones AT, Hall AL, O’Brien LT, Wilkinson RA, Sawyer E, Lophatananon A, UK Genetic Prostate Cancer Study Collaborators/British Association of Urological Surgeons’ Section of Oncology; UK Prostate testing for cancer and Treatment study (ProtecT Study) Collaborators, Horwich A, Huddart RA, Khoo VS, Parker CC, Woodhouse CJ, Thompson A, Christmas T, Ogden C, Cooper C, Donovan JL, Hamdy FC, Neal DE, Eeles RA, Easton DF+26 more. 2009a. Multiple loci on 8q24 associated with prostate cancer susceptibility. Nature Genetics 41:1058-1060
Amundadottir LT, Sulem P, Gudmundsson J, Helgason A, Baker A, Agnarsson BA, Sigurdsson A, Benediktsdottir KR, Cazier J-B, Sainz J, Jakobsdottir M, Kostic J, Magnusdottir DN, Ghosh S, Agnarsson K, Birgisdottir B, Le Roux L, Olafsdottir A, Blondal T, Andresdottir M, Gretarsdottir OS, Bergthorsson JT, Gudbjartsson D, Gylfason A, Thorleifsson G, Manolescu A, Kristjansson K, Geirsson G, Isaksson H, Douglas J, Johansson J-E, Balter K, Wiklund F, Montie JE, Yu X, Suarez BK, Ober C, Cooney KA, Gronberg H, Catalona WJ, Einarsson GV, Barkardottir RB, Gulcher JR, Kong A, Thorsteinsdottir U, Stefansson K+36 more. 2006. A common variant associated with prostate cancer in European and African populations. Nature Genetics 38:652-658
Amundadottir LT, Thorvaldsson S, Gudbjartsson DF, Sulem P, Kristjansson K, Arnason S, Gulcher JR, Bjornsson J, Kong A, Thorsteinsdottir U, Stefansson K+1 more. 2004. Cancer as a Complex Phenotype: pattern of Cancer Distribution within and beyond the Nuclear Family. PLoS Medicine 1:e65
Balding DJ. 2006. A tutorial on statistical methods for population association studies. Nature Reviews Genetics 7:781-791
Cooner WH, Mosley BR, Rutherford CL, Beard JH, Pond HS, Terry WJ, Igel TC, Kidd DD. 1990. Prostate-cancer detection in a clinical urological practice by ultrasonography, digital rectal examination and prostate specific antigen. Journal of Urology 143:1146-1154
Crawford ED. 2003. Epidemiology of prostate cancer. Urology 62:3-12
Davis CD, Milner JA. 2007. Biomarkers for diet and cancer prevention research: potentials and challenges. Acta Pharmacologica Sinica 28:1262-1273
De Jager PL, Chibnik LB, Cui J, Reischl J, Lehr S, Simon KC, Aubin C, Bauer D, Heubach JF, Sandbrink R, Tyblova M, Lelkova P, Steering committee of the, B. s., Steering committee of the, B. s., Steering committee of the, L. T. F. s., Steering committee of the, C. C. R. s., Havrdova E, Pohl C, Horakova D, Ascherio A, Hafler DA, Karlson EW+12 more. 2009. Integration of genetic risk factors into a clinical algorithm for multiple sclerosis susceptibility: a weighted genetic risk score. The Lancet. Neurology 8:1111-1119
Du M, Yuan T, Schilter KF, Dittmar RL, Mackinnon A, Huang X, Tschannen M, Worthey E, Jacob H, Xia S, Gao J, Tillmans L, Lu Y, Liu P, Thibodeau SN, Wang L+6 more. 2015. Prostate cancer risk locus at 8q24 as a regulatory hub by physical interactions with multiple genomic loci across the genome. Human Molecular Genetics 24:154-166
Eeles R, Goh C, Castro E, Bancroft E, Guy M, Al Olama AA, Easton D, Kote-Jarai Z. 2014. The genetic epidemiology of prostate cancer and its clinical implications. Nature Reviews Urology 11:18-31
Freedman LS, Potischman N, Kipnis V, Midthune D, Schatzkin A, Thompson FE, Troiano RP, Prentice R, Patterson R, Carroll R, Subar AF+1 more. 2006. A comparison of two dietary instruments for evaluating the fat–breast cancer relationship. International Journal of Epidemiology 35:1011-1021
Ghoussaini M, Song H, Koessler T, Al Olama AA, Kote-Jarai Z, Driver KE, Pooley KA, Ramus SJ, Kjaer SK, Hogdall E, DiCioccio RA, Whittemore AS, Gayther SA, Giles GG, Guy M, Edwards SM, Morrison J, Donovan JL, Hamdy FC, Dearnaley DP, Ardern-Jones AT, Hall AL, O’Brien LT, Gehr-Swain BN, Wilkinson RA, Brown PM, Hopper JL, Neal DE, Pharoah PD, Ponder BA, Eeles RA, Easton DF, Dunning AM, UK Genetic Prostate Cancer Study Collaborators/British Association of Urological Surgeons’ Section of Oncology; UK ProtecT Study Collaborators+24 more. 2008. Multiple loci with different cancer specificities within the 8q24 gene desert. Journal of the National Cancer Institute 100:962-966
Giovannucci E, Liu Y, Platz EA, Stampfer MJ, Willett WC. 2007. Risk factors for prostate cancer incidence and progression in the health professionals follow-up study. International Journal of Cancer 121:1571-1578
Glitza IC, Lu G, Shah R, Bashir Q, Shah N, Champlin RE, Shah J, Orlowski RZ, Qazilbash MH. 2015. Chromosome 8q24.1/c-MYC abnormality: a marker for high-risk myeloma. Leukemia & Lymphoma 56:602-607
Goh CL, Schumacher FR, Easton D, Muir K, Henderson B, Kote-Jarai Z, Eeles RA. 2012. Genetic variants associated with predisposition to prostate cancer and potential clinical implications. Journal of Internal Medicine 271:353-365
Gudmundsson J, Sulem P, Gudbjartsson DF, Blondal T, Gylfason A, Agnarsson BA, Benediktsdottir KR, Magnusdottir DN, Orlygsdottir G, Jakobsdottir M, Stacey SN, Sigurdsson A, Wahlfors T, Tammela T, Breyer JP, McReynolds KM, Bradley KM, Saez B, Godino J, Navarrete S, Fuertes F, Murillo L, Polo E, Aben KK, Van Oort IM, Suarez BK, Helfand BT, Kan D, Zanon C, Frigge ML, Kristjansson K, Gulcher JR, Einarsson GV, Jonsson E, Catalona WJ, Mayordomo JI, Kiemeney LA, Smith JR, Schleutker J, Barkardottir RB, Kong A, Thorsteinsdottir U, Rafnar T, Stefansson K+34 more. 2009. Genome-wide association and replication studies identify four variants associated with prostate cancer susceptibility. Nature Genetics 41:1122-1126
Gudmundsson J, Sulem P, Manolescu A, Amundadottir LT, Gudbjartsson D, Helgason A, Rafnar T, Bergthorsson JT, Agnarsson BA, Baker A, Sigurdsson A, Benediktsdottir KR, Jakobsdottir M, Xu J, Blondal T, Kostic J, Sun J, Ghosh S, Stacey SN, Mouy M, Saemundsdottir J, Backman VM, Kristjansson K, Tres A, Partin AW, Albers-Akkers MT, Godino-Ivan Marcos J, Walsh PC, Swinkels DW, Navarrete S, Isaacs SD, Aben KK, Graif T, Cashy J, Ruiz-Echarri M, Wiley KE, Suarez BK, Witjes JA, Frigge M, Ober C, Jonsson E, Einarsson GV, Mayordomo JI, Kiemeney LA, Isaacs WB, Catalona WJ, Barkardottir RB, Gulcher JR, Thorsteinsdottir U, Kong A, Stefansson K+41 more. 2007. Genome-wide association study identifies a second prostate cancer susceptibility variant at 8q24. Nature Genetics 39:631-637
Han Y, Signorello LB, Strom SS, Kittles RA, Rybicki BA, Stanford JL, Goodman PJ, Berndt SI, Carpten J, Casey G, Chu L, Conti DV, Rand KA, Diver WR, Hennis AJM, John EM, Kibel AS, Klein EA, Kolb S, Le Marchand L, Leske MC, Murphy AB, Neslund-Dudas C, Park JY, Pettaway C, Rebbeck TR, Gapstur SM, Zheng SL, Wu S-Y, Witte JS, Xu J, Isaacs W, Ingles SA, Hsing A, The, P. C., The, E. G.-O. N. C., Easton DF, Eeles RA, Schumacher FR, Chanock S, Nemesure B, Blot WJ, Stram DO, Henderson BE, Haiman CA+35 more. 2015. Generalizability of established prostate cancer risk variants in men of African ancestry. International Journal of Cancer 136:1210-1217
Hawksworth D, Ravindranath L, Chen Y, Furusato B, Sesterhenn IA, McLeod DG, Srivastava S, Petrovics G. 2010. Overexpression of C-MYC oncogene in prostate cancer predicts biochemical recurrence. Prostate Cancer and Prostatic Disease 13:311-315
Heidenreich A, Bastian PJ, Bellmunt J, Bolla M, Joniau S, van der Kwast T, Mason M, Matveev V, Wiegel T, Zattoni F, Mottet N+1 more. 2014. EAU guidelines on prostate cancer. Part 1: screening, diagnosis, and Local treatment with curative intent—update 2013. European Urology 65:124-137
Helfand BT, Fought AJ, Loeb S, Meeks JJ, Kan D, Catalona WJ. 2010. Genetic prostate cancer risk assessment: common variants in 9 genomic regions are associated with cumulative risk. The Journal of Urology 184:501-505
Hodgson F, Obertová Z, Brown C, Lawrenson R. 2012. PSA testing in general practice. Journal of Primary Health Care 204:199-204
Karan D, Kelly DL, Rizzino A, Lin M-F, Batra SK. 2002. Expression profile of differentially-regulated genes during progression of androgen-independent growth in human prostate cancer cells. Carcinogenesis 23:967-976
Kastler S, Honold L, Luedeke M, Kuefer R, Möller P, Hoegel J, Vogel W, Maier C, Assum G. 2010. POU5F1P1, a putative cancer susceptibility gene, is overexpressed in prostatic carcinoma. The Prostate 70:666-674
Kim S-T, Cheng Y, Hsu F-C, Jin T, Kader AK, Zheng SL, Isaacs WB, Xu J, Sun J. 2010. Prostate cancer risk-associated variants reported from genome-wide association studies: meta-analysis and their contribution to genetic Variation. The Prostate 70:1729-1738
Lichtenstein P, Holm NV, Verkasalo PK, Iliadou A, Kaprio J, Koskenvuo M, Pukkala E, Skytthe A, Hemminki K. 2000. Environmental and heritable factors in the causation of cancer—analyses of cohorts of twins from Sweden, Denmark, and Finland. New England Journal of Medicine 343:78-85
Liu H, Wang B, Han C. 2011. Meta-analysis of genome-wide and replication association studies on prostate cancer. The Prostate 71:209-224
Meyer KB, Maia A-T, O’Reilly M, Ghoussaini M, Prathalingam R, Porter-Gill P, Ambs S, Prokunina-Olsson L, Carroll J, Ponder BAJ. 2011. A functional variant at a prostate cancer predisposition locus at 8q24 Is associated with <italic>PVT1</italic>expression. PLoS Genetics 7:e1002165
Neale RE, Mineau G, Whiteman DC, Brownbill PA, Murphy MF. 2005. Childhood and adult cancer in twins: evidence from the Utah genealogy. Cancer Eidemiology, Biomarkers & Prevention 14:1236-1240
NHC. 2004. Prostate cancer screening in New Zealand. In: NHC adviser (6th edition). vol. 2012 Available at http://nhc.health.govt.nz/publications/nhc-publications-pre-2011/prostate-cancer-screening-new-zealand (accessed June 2012)
Nichols J, Zevnik B, Anastassiadis K, Niwa H, Klewe-Nebenius D, Chambers I, Schöler H, Smith A. 1998. Formation of pluripotent stem cells in the mammalian embryo depends on the POU transcription factor Oct4. Cell 95:379-391
Nordström T, Aly M, Eklund M, Egevad L, Grönberg H. 2013. A genetic score can identify men at high risk for prostate cancer among men with prostate-specific antigen of 1–3 ng/ml. European Urology 65(6):1184-1190
Okobia MN, Zmuda JM, Ferrell RE, Patrick AL, Bunker CH. 2011. Chromosome 8q24 variants are associated with prostate cancer risk in a high risk population of African ancestry. The Prostate 71:1054-1063
Page WF, Braun MM, Partin AW, Caporaso N, Walsh P. 1997. Heredity and prostate cancer: a study of World War II veteran twins. The Prostate 33:240-245
Pal P, Xi H, Guha S, Sun G, Helfand BT, Meeks JJ, Suarez BK, Catalona WJ, Deka R. 2009. Common variants in 8q24 are associated with risk for prostate cancer and tumor aggressiveness in men of European ancestry. The Prostate 69:1548-1556
Pomerantz MM, Beckwith CA, Regan MM, Wyman SK, Petrovics G, Chen Y, Hawksworth DJ, Schumacher FR, Mucci L, Penney KL, Stampfer MJ, Chan JA, Ardlie KG, Fritz BR, Parkin RK, Lin DW, Dyke M, Herman P, Lee S, Oh WK, Kantoff PW, Tewari M, McLeod DG, Srivastava S, Freedman ML+15 more. 2009. Evaluation of the 8q24 prostate cancer risk Locus and MYC expression. Cancer Research 69:5568-5574
R Foundation for Statistical Computing. 2012. R: a language and environment for statistical computing. Vienna. Available at http://www.R-project.org
Ribeiro FR, Henrique R, Martins AT, Jerónimo C, Teixeira MR. 2007. Relative copy number gain of MYC in diagnostic needle biopsies is an independent prognostic factor for prostate cancer patients. European Urology 52:116-125
Robbins C, Torres JB, Hooker S, Bonilla C, Hernandez W, Candreva A, Ahaghotu C, Kittles R, Carpten J. 2007. Confirmation study of prostate cancer risk variants at 8q24 in African Americans identifies a novel risk locus. Genome Research 17:1717-1722
Severi G, Hayes VM, Padilla EJD, English DR, Southey MC, Sutherland RL, Hopper JL, Giles GG. 2007. The common variant rs1447295 on chromosome 8q24 and prostate cancer risk: results from an Australian population-based case-control Study. Cancer Epidemiology Biomarkers & Prevention 16:610-612
Storey JD. 2002. A direct approach to false discovery rates. Journal of the Royal Statistical Society: Series B (Statistical Methodology) 64:479-498
Sun J, Kader AK, Hsu F-C, Kim S-T, Zhu Y, Turner AR, Jin T, Zhang Z, Adolfsson J, Wiklund F, Zheng SL, Isaacs WB, Grönberg H, Xu J+4 more. 2011. Inherited genetic markers discovered to date are able to identify a significant number of men at considerably elevated risk for prostate cancer. The Prostate 71:421-430
Teerlink C, Thibodeau S, McDonnell S, Schaid D, Rinckleb A, Maier C, Vogel W, Cancel-Tassin G, Egrot C, Cussenot O, Foulkes W, Giles G, Hopper J, Severi G, Eeles R, Easton D, Kote-Jarai Z, Guy M, Cooney K, Ray A, Zuhlke K, Lange E, FitzGerald L, Stanford J, Ostrander E, Wiley K, Isaacs S, Walsh P, Isaacs W, Wahlfors T, Tammela T, Schleutker J, Wiklund F, Grönberg H, Emanuelsson M, Carpten J, Bailey-Wilson J, Whittemore A, Oakley-Girvan I, Hsieh C-L, Catalona W, Zheng SL, Jin G, Lu L, Xu J, Camp N, Cannon-Albright L+37 more. 2014. Association analysis of 9,560 prostate cancer cases from the International Consortium of Prostate Cancer Genetics confirms the role of reported prostate cancer associated SNPs for familial disease. Human Genetics 133:347-356
Thomas LP, Dilip VJ. 1999. The potential impact of the baby-boom generation on substance abuse among elderly persons. Psychiatric Services 50:1184-1188
Wang Y, Ray AM, Johnson EK, Zuhlke KA, Cooney KA, Lange EM. 2011. Evidence for an association between prostate cancer and chromosome 8q24 and 10q11 genetic variants in African American men: the flint men’s health study. The Prostate 71:225-231
Wasserman NF, Aneas I, Nobrega MA. 2010. An 8q24 gene desert variant associated with prostate cancer risk confers differential in vivo activity to a MYC enhancer. Genome Research 20:1191-1197
Wolk A. 2005. Diet, lifestyle and risk of prostate cancer. Acta Oncologica 44:277-281
Wolk A. 2009. Mantzoros CS, ed. Diet and Physical Activity in Cancer Prevention Nutrition and Metabolism. New York: Humana Press. 161-192
Xu J, Sun J, Zheng SL. 2013. Prostate cancer risk-associated genetic markers and their potential clinical utility. Asian Journal of Andrology 15:314-322
Yang G, Timme TL, Frolov A, Wheeler TM, Thompson TC. 2005. Combined c-Myc and caveolin-1 expression in human prostate carcinoma predicts prostate carcinoma progression. Cancer 103:1186-1194
Yeager M, Orr N, Hayes RB, Jacobs KB, Kraft P, Wacholder S, Minichiello MJ, Fearnhead P, Yu K, Chatterjee N, Wang Z, Welch R, Staats BJ, Calle EE, Feigelson HS, Thun MJ, Rodriguez C, Albanes D, Virtamo J, Weinstein S, Schumacher FR, Giovannucci E, Willett WC, Cancel-Tassin G, Cussenot O, Valeri A, Andriole GL, Gelmann EP, Tucker M, Gerhard DS, Fraumeni JF, Hoover R, Hunter DJ, Chanock SJ, Thomas G+25 more. 2007. Genome-wide association study of prostate cancer identifies a second risk locus at 8q24. Nature Genetics 39:645-649
Zhang Y, Perez T, Blondin B, Du J, Liu P, Escarzaga D, Coon JS, Morrison LE, Pestova K. 2014. Identification of FISH biomarkers to detect chromosome abnormalities associated with prostate adenocarcinoma in tumour and field effect environment. BMC Cancer 14:129
Karen S. Bishop1, Dug Yeo Han2,3, Nishi Karunasinghe1, Megan Goudie4, Jonathan G. Masters4, Lynnette R. Ferguson1,2,3 1 Auckland Cancer Society Research Centre, Faculty of Medical and Health Sciences, University of Auckland, Auckland, New Zealand 2 Nutrigenomics New Zealand, University of Auckland, Auckland, New Zealand 3 Discipline of Nutrition and Dietetics, Faculty of Medical and Health Sciences, University of Auckland, Auckland, New Zealand 4 Urology Department, Auckland District Health Board, Auckland, New Zealand
© 2016 Bishop et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, reproduction and adaptation in any medium and for any purpose provided that it is properly attributed. For attribution, the original author(s), title, publication source (PeerJ) and either DOI or URL of the article must be cited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.