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. Author manuscript; available in PMC: 2019 May 1.
Published in final edited form as: J Thorac Oncol. 2018 Mar 23;13(5):649–659. doi: 10.1016/j.jtho.2018.01.022

Inflammatory Gene Polymorphisms in Lung Cancer Susceptibility

Keith D Eaton 1,3, Perrin E Romine 3, Gary E Goodman 2, Mark D Thornquist 2,4, Matt J Barnett 2, Effie W Petersdorf 1,3
PMCID: PMC5976242  NIHMSID: NIHMS968718  PMID: 29408308

Abstract

Introduction

Chronic inflammation has been implicated in carcinogenesis, with increasing evidence of its role in lung cancer. We aim to evaluate the role of genetic polymorphisms in inflammation-related genes in the risk for developing lung cancer.

Methods

Using a nested case-control study design, 625 cases and 625 well-matched controls were selected from participants in the CARET study, a large, prospective lung cancer chemoprevention trial. The association between lung cancer incidence and survival and 23 polymorphisms descriptive of 11 inflammation-related genes (interferon γ, IL-10, IL-1α, IL-1β, IL-2, IL-4R, IL-4, IL-6, PTGS2 (COX-2), TGF-β1, and TNFα) was evaluated.

Results

Of the 23 polymorphisms, two were associated with risk for lung cancer. Compared to individuals with the wild type (CC) variant, individuals carrying the minor allele variants of the IL-1β-511C>T promoter polymorphism (rs16944) (CT and TT) had decreased odds of lung cancer (OR = 0.74 [95% CI 0.58 – 0.94] and OR = 0.71 [95% CI 0.50 – 1.01], respectively, p = 0.03). Similar results were observed for the IL-1β-1464 C>G promoter polymorphism (rs1143623), with presence of the minor variants CG and CC having decreased odds of lung cancer (OR=0.75[95% CI 0.59-0.95] and OR=0.69[95% CI 0.46-1.03], respectively, p=0.03). Survival was not influenced by genotype.

Conclusions

This study provides further evidence that IL-1β promoter polymorphisms may modulate the risk for developing lung cancer.

Keywords: lung cancer, polymorphism, genetics, cytokines, inflammation

Introduction

Lung cancer is the leading cause of cancer mortality worldwide, with 155,870 deaths predicted in the U.S. in 2017.1 Although the vast majority of lung cancer cases occur in the setting of tobacco use, fewer than 20% of smokers develop lung cancer.2 To explain these observations, a genetic basis for susceptibility to the carcinogenic effects of tobacco smoke has been postulated. Candidate genetic polymorphisms include genes involved in the metabolism and activation of the carcinogens in tobacco smoke, DNA repair, and cell cycle regulation.3,4 Genome wide association studies have demonstrated that single nucleotide polymorphisms (SNPs) located within the 15q25 region encoding for subunits of the nicotinic acetylcholine receptor are significantly associated with risk for lung cancer.5,6

Several lines of evidence support the hypothesis that persons with chronic inflammatory conditions, such as chronic obstructive pulmonary disease7 or asthma,8 have an increased risk of lung cancer, even when exposure to tobacco smoke is taken into account. Asbestos and cigarette smoke may exert some of their carcinogenic effects in the lung through chronic inflammation,9 as tobacco use has been associated with higher levels of inflammatory cytokines and inflammatory cells.10 Other evidence indicates that among persons with lung cancer, a pro-inflammatory state may lead to worse prognosis. This hypothesis is supported by the finding that lung cancer patients with increased numbers of intra-tumoral macrophages had shorter relapse-free survival compared to patients with low intra-tumoral macrophage density.11 In addition, the total degree of systemic inflammation, as measured by C-reactive protein and albumin levels, has been found to be a powerful prognostic indicator in patients with lung cancer.12

The role of chronic infections in the etiology of hepatocellular carcinoma, gastric cancer, and cervical cancer is well established and is postulated to be mediated through the inflammatory response.13 In humans, the role of inflammatory gene polymorphisms has been investigated in a variety of tumors including, gastric, liver, breast, ovarian, prostate, pancreas, skin, colon, and hematologic malignancies. Gene families studied have included IL-1α, IL-1β, IL-1RN, IL-2, IL-4, IL-6, IL-8, IL-10, TNFα, LTα, PTGS2 (COX-2), interferon γ, TLR4, and others.14,15 Inflammatory gene families have been most extensively studied in gastric cancer, where results have been variable. Initial studies suggested that the pro-inflammatory alleles IL-1β-31T and IL-1RN*2 increased effective IL-1 levels and inhibited gastric acid secretion, thereby increasing risk of non-cardia gastric cancer.16,17 These polymorphisms, in addition to polymorphisms in TNFα and IL-10, were found to increase non-cardia gastric cancer risk.16 Further studies, however, have indicated that while IL-1β and IL-1RN SNPs and haplotypes may be associated with atrophic gastritis, there is no association with gastric cancer.18,19 Furthermore, results vary significantly based on the population being studied, with variability most pronounced between Caucasian and Asian populations.20

Various studies have begun to understand the role of inflammatory genes in the pathogenesis of lung cancer. Measured free levels of circulating IL-17A, IL-17F, IL-22, IL-23, and TNF-α have been demonstrated to be significantly increased in patients with non-small cell lung cancer (NSCLC) compared with healthy controls.21 Research has focused on the role of SNPs within the IL-1β gene and the IL-1RN gene, similar to prior studies in gastric cancer. Studies have demonstrated an increased risk of lung cancer as well as COPD among individuals carrying a -31T>C (rs1143627), -511C>T (rs16944), -3893A>G (rs12621220), or -1464 C>G (rs1143623) mutation.2225 Furthermore, studies have demonstrated haplotype linkage disequilibrium between the above IL-1β SNPs and IL-1RN VNTR with association between certain haplotypes and increased risk of lung cancer.2224,26 The success of checkpoint inhibitors in NSCLC has underscored the importance of immune regulations in the development and progression of lung cancer.27

Given these observations linking inflammatory gene SNPs and haplotypes with lung cancer risk, we tested the hypothesis that variation in the form of single nucleotide polymorphisms (SNPs) in additional genes involved in the inflammatory response influences lung cancer risk and prognosis.

Materials and Methods

Subjects

Participants in this study were enrolled in the β-Carotene and Retinol Efficacy Trial (CARET), a large, randomized, multi-center trial which examined the effect of β-carotene and retinol versus placebo in a population at high risk for developing lung cancer.28 Participants in CARET included heavy smokers, aged 50-69 at the time of entry into the study, with a smoking history of 20 or more pack-years, who were either current smokers or had quit within the previous 6 years. As part of the study, genomic DNA was prospectively collected and banked from over 12,000 subjects out of a total of 18,314 enrolled subjects. The Fred Hutchinson Cancer Research Center Institutional Review Board granted approval for the original intervention study, DNA collection, and the use of the samples and data for the current study.

Criteria for the current study included: 1) a diagnosis of lung cancer (both small cell (SCLC) and NSCLC were included), 2) availability of a dried blood spot as source of DNA, and 3) availability of a matched control from the CARET dataset. A matched, nested case-control design was used to minimize bias from population stratification. Demographic and exposure data on this population are well characterized. The average length of follow-up for cases is over seven years. Cases and controls were matched by age, gender, race, occupational exposure to asbestos, year of enrollment, CARET intervention arm, smoking status (current vs. former), and pack-years.

From participants entered into the original CARET trial with banked DNA, a total of 625 lung cancer cases and an equal number of matched controls were identified. The large study population allowed for near-perfect matching on all variables of interest, as shown in Table 1. Histological subtypes were determined from pathology reports when possible. For the purposes of analysis, NSCLC histology was divided into adenocarcinoma (AC), squamous cell carcinoma (SCC), and other NSCLC. Adenocarcinoma was the most frequent subtype with 169 cases, squamous cell carcinoma accounted for 138 cases, other NSCLC 122 cases, and small cell lung cancer 98 cases. Ninety-eight cases did not have an accompanying pathology report and were diagnosed by death certificate, clinically, or by self-report. The number of cases of each of the histological subtypes is shown in Table 1.

Table 1.

Characteristics of the Study Population

Cases
(N = 625)		 Controls
(N = 625)
Age [mean (SD)] 59.7 (5.3) 59.6 (5.3)
Gender [n (%)]
 Female 217 (35%) 217 (35%)
 Male 408 (65%) 408 (65%)
Race [n (%)]
 White 614 (98%) 614 (98%)
 Black 6 (1%) 6 (1%)
 Other 5 (1%) 5 (1%)
Study center [n (%)]
 Baltimore 28 (4%) 22 (4%)
 Irvine 126 (20%) 139 (22%)
 New Haven 21 (3%) 33 (5%)
 Portland 190 (30%) 183 (29%)
 San Francisco 21 (3%) 16 (3%)
 Seattle 239 (38%) 232 (37%)
Smoking status at baseline [n (%)]
 Current smoker 463 (74%) 463 (74%)
 Former smoker 162 (26%) 162 (26%)
Pack – years of smoking [mean (SD) ] 53 (18) 53 (18)
Asbestos exposure (% with occupational exposure) 15 (%) 15%
Body mass index [mean (SD)] 26.9 (4.6) 27.1 (4.7)
CARET intervention assignment [n (%)]
 Active vitamins 345 (55%) 345 (55%)
 Placebo 280 (45%) 280 (45%)
Histological Subtype (%)
 Adenocarcinoma 169 (27%)
 Squamous Cell 138 (22%)
 Other NSCLC 122 (19%)
 Small Cell 98 (16%)
 Missing* 98 (16%)
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*

No pathology report available, diagnosed by death certificate only (N = 43), clinically (N = 32), or by self-report (N = 23).

DNA Extraction

DNA was extracted from archived dried blood spots stored on Schleicher and Schuell #907 filter paper stored at −70C. Samples were collected from 1994-1997 and DNA extraction was performed in 2002. Prior work has demonstrated sufficient yield from dried blood samples when stored at −20C for over twenty years; samples in this study were stored for at most eight years.29 Samples were processed as follows. In brief, one 1/16” hole punch (MC Mieth Manufacturing, Port Orange, FL) from the dried blood spot was collected for each case and control. To prevent cross-contamination, the punch was flame-sterilized between samples. Filter paper punches without blood spots served as negative controls. In order to have sufficient DNA for multiple reactions, each sample was PCR-amplified using a multi-strand displacement reaction resulting in whole genome amplification (Qiagen, Valencia, CA) and yielded 20 μl of 1μg/μl DNA. The amplified DNA was diluted 300-fold with reagent grade water and used in all genotyping reactions. DNA amplified using the multi-strand displacement reaction has been found to have better than 99% concordance with traditionally extracted DNA in subsequent Taqman genotyping reactions.30

Genotyping Protocol

In this study, a candidate-gene selection strategy was used to choose genes implicated in cancer or disease.14,15 Common polymorphisms in coding or promoter regions with expected minor allele frequency of greater than 5% were chosen.

All polymorphisms were genotyped using Taqman based allelic discrimination assays. We utilized previously validated assays, described in the National Cancer Institute’s SNP500Cancer project.31 This resource validates the assays’ performance against sequence based typing on over 100 ethnically diverse individuals. The assays used in this study are described by the internal SNP500Cancer identification and rs number (dbSNP reference SNP identification number), and are listed in Table 2.

Table 2.

Single Nucleotide Polymorphisms Studied

Gene SNP500Cancer ID dbSNP ID SNP Region* Alternate nomenclature HWE p-cases HWE p-controls Minor allele frequency in controls
interferon, gamma IFNG-10 rs2069705 − 1615C>T 0.11 0.86 0.34
interleukin 10 IL10 – 01 rs1800871 − 853C>T − 819 0.02 0.12 0.23
IL10-02 rs1800872 −626A>C −592 0.03 0.13 0.23
IL10 – 03 rs1800896 − 1116A>G − 1082 0.04 0.95 0.49
interleukin 1, alpha IL1A-01 rs17561 Ex5+21G>T A114S 0.06 0.79 0.29
IL1A – 02 rs1800587 Ex1+12C>T − 889, 5′UTR 0.13 0.82 0.29
IL1A-04 rs2071374 IVS4-109A>C 0.22 0.48 0.28
interleukin 1, beta IL1B – 01 rs16944 − 1060T>C − 511 0.01 0.23 0.36
IL1B-02 rs1143634 Ex5+14C>T F105F, +3954 0.26 0.68 0.21
IL1B – 09 rs1143623 − 2022C>G − 1464 0.02 0.14 0.30
interleukin 2 IL2-01 rs2069762 IVS1-100G>T 0.94 0.44 0.29
IL2 – 03 rs2069763 Ex2 – 34G>T L38L 0.05 0.08 0.35
interleukin 4 receptor IL4R-02 rs1805011 Ex11+300A>C E400A 0.28 0.69 0.12
IL4R – 06 rs1801275 Ex11+828A>G Q576R 0.45 0.32 0.21
IL4R-23 rs2107356 −28120T>C 0.28 0.57 0.41
interleukin 4 IL4 – 01 rs2243250 − 588C>T − 524 0.19 0.31 0.17
interleukin 6 IL6-01 rs1800795 − 236C>G −174 0.60 0.38 0.44
prostaglandin – endoperoxide synthase 2 (COX2) PTGS2 – 33 rs5275 Ex10+837C>T 3′UTR 0.76 0.70 0.33
transforming growth factor, beta 1 TGFB1-01 rs1982073 Ex1-327C>T L10P 0.62 0.58 0.40
308 bp 3′ of STP
TGFB1-05 rs1800469 C>T −509C>T 0.29 0.70 0.32
tumor necrosis factor TNF-02 rs1800629 −487A>G −308 0.23 0.55 0.19
TNF-04 rs361525 −417A>G −238 0.55 0.70 0.05
TNF – 07 rs1799724 − 1036C>T − 857 0.93 0.26 0.09
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*

The nomenclature is described in reference50

TGFB1-05 has been re-classified as MGC4093-03

HWE, Hardy-Weinberg Equilibrium

Statistical Analysis

Primary Endpoints

Lung cancer risk was assessed by comparing the distribution of SNP genotype frequencies between cases (of all histological subtypes) and controls using a likelihood ratio test in a 2×3 cross-classification table with a p-value threshold of 0.05 as a cutoff for statistical significance. In situations where a genotype from either the case or control was not available due to technical limitations such as amplification failure, both members of the case- control pair were dropped from the analysis. Haplotype analysis was performed using PHASE version 2.1 with a permutation analysis to test for significant differences in haplotype frequencies between cases and controls.32

Stratified analyses

To investigate the possibility that the effect of a genetic polymorphism may be biologically active only in a specific histological subgroup, exploratory analyses were conducted examining the effect of genotype within the histological subtypes based on pathology reports. The controls were each matched to a case in 1:1 fashion.

Based on prior multivariate analyses of the CARET data which delineated the demographic variables predictive of lung cancer risk,33 further exploratory subgroup analyses were performed within the following subpopulations: experimental arm (vitamin supplementation vs. placebo), age above or below the median of 60 years, smoking status (current vs. former), pack-years above or below the median of 48, and gender. These analyses were restricted to case-control pairs as well. Within the analysis of pack-years and age, case-control pairs were dropped if one subject was below the median value and the other was above the median. Pack-years and age were the only variables for which this occurred; the matching was exact for the other variables (intervention arm, smoking status, and gender).

Hardy-Weinberg Equilibrium (HWE)

For all assays, genotype distributions in both cases and controls were assessed for Hardy Weinberg Equilibrium (HWE) using the chi-squared method.

Estimation of Power

Modeling of our data with assumptions of HWE, with 80% power, using a 0.05-level test for heterogeneity in the 2×3 contingency, odds ratios (OR) for increased risk as low as 1.3 for minor allele frequency=0.5 and as low as 1.5 for minor allele frequency of 0.1 can be detected.

Survival analysis

Patients who were diagnosed with lung cancer prior to the collection of the dried blood spots were censored to avoid bias, leaving 580 of the 625 original cases. The method of Kaplan and Meier was used to construct survival curves and Cox regression was performed to estimate hazard ratios (HRs). Differences in survival among subgroups of different genotypes were analyzed using a log-rank test. All statistical tests were two-sided. All analyses were implemented using SAS software (SAS Institute, Cary, NC).

Results

Genotyping

A genotype was assigned for 99.0% of all samples tested with a range of 97.4%-99.7% among the SNPs tested. In order to estimate the rate of genotyping errors, we repeated genotyping of the IL-1β −511 gene polymorphism for all samples and found 99.9% concordance with the original results.

Population genetics

Hardy-Weinberg equilibrium was tested in the control group for each SNP genotyped and all p-values were > 0.05. The minor allele frequencies observed in the control group in this predominantly (98%) Caucasian population are reported in Table 2.

The ORs for cancer risk by genotype are presented in Table 3. An association between the IL-1β promoter polymorphisms rs16944 (also described as IL1B_01 or -511C>T) and rs1143623 (IL1B_09 or -1464 C>G) and lung cancer risk was found. The size of this effect was modest, with presence of the minor allele variants of IL-1β-511C>T (rs16944) (CT and TT) having decreased odds of lung cancer, compared to individuals carrying the wild type (CC) variant (OR = 0.74 [95% CI 0.58 – 0.94] and OR = 0.71 [95% CI 0.50 – 1.01]; test of heterogeneity, p = 0.03). Similar results were observed for the IL-1β-1464 C>G (rs1143623) promoter polymorphism, with presence of the minor variants CG and CC having decreased odds of lung cancer (OR=0.75[95% CI 0.59-0.95] and OR=0.69[95% CI 0.46-1.03]; test of heterogeneity, p=0.03). Results were re-analyzed by intervention arm with no statistically significant difference noted between the intervention and the placebo groups (data not shown). Haplotypes inferred by the PHASE program are displayed for cases and controls in Table 4. A statistically significant (p = 0.02) difference between the haplotype distributions between cases and controls was observed for IL-1β. No other statistically significant association between genotype and lung cancer risk was found for other haplotypes or individual SNPs. The inflammatory gene polymorphisms studied showed no significant effect on survival.

Table 3.

Genotypes in Lung Cancer Cases and Controls

Gene Polymorphism Genotype Cases, n(%o) Controls, n(%) OR(95% CI)
IFNG_10 TT 268(43.3) 274(44.3) 1
TC 265(42.8) 274(44.3) 0.99(0.78–1.26)
CC 86(13.9) 71(11.5) 1.24(0.87–1.77)
p=0.44
IL10_01 CC 382(61.9) 371(60.1) 1
CT 195(31.6) 206(33.4) 0.92(0.72–1.17)
TT 40(6.5) 40(6.5) 0.97(0.61–1.54)
p=0.79
IL10_02 CC 382(61.6) 375(60.5) 1
CA 197(31.8) 206(33.2) 0.94(0.74–1.20)
AA 41(6.6) 39(6.3) 1.03(0.65–1.64)
p=0.85
IL10_03 AA 160(26.9) 158(26.6) 1
AG 273(45.9) 297(49.9) 0.91(0.69–1.19)
GG 162(27.2) 140(23.5) 1.14(0.83–1.57)
p=0.27
IL1A_01 GG 303(49.2) 316(51.3) 1
GT 272(44.2) 249(40.4) 1.14(0.90–1.44)
TT 41(6.7) 51(8.3) 0.84(0.54–1.30)
p=0.30
IL1A_02 CC 299(48.9) 312(51.0) 1
CT 269(44.0) 249(40.7) 1.13(0.89–1.42)
TT 44(7.2) 51(8.3) 0.90(0.58–1.39)
p=0.46
IL1A_04 AA 319(51.5) 322(52.0) 1
AC 242(39.1) 253(40.9) 0.97(0.76–1.22)
CC 58(9.4) 44(7.1) 1.33(0.87–2.03)
p=0.34
IL1B_01 CC 303(49.7) 256(42.0) 1
CT 234(38.4) 267(43.8) 0.74(0.58–0.94)
TT 73(12.0) 87(14.3) 0.71(0.50–1.01)
p=0.03
IL1B_02 CC 361(57.9) 383(61.5) 1
CT 233(37.4) 213(34.2) 1.16(0.92–1.47)
TT 29(4.7) 27(4.3) 1.14(0.66–1.96)
p=0.45
IL1B_09 GG 360(58.3) 313(50.6) 1
GC 209(33.8) 243(39.3) 0.75(0.59–0.95)
CC 49(7.9) 62(10.0) 0.69(0.46–1.03)
p=0.03
IL2_01 TT 312(50.2) 306(49.3) 1
TG 257(41.4) 266(42.8) 0.95(0.75–1.20)
GG 52(8.4) 49(7.9) 1.04(0.68–1.59)
p=0.86
IL2_03 GG 256(42.2) 246(40.5) 1
GT 292(48.1) 296(48.8) 0.95(0.75–1.20)
TT 59(9.7) 65(10.7) 0.87(0.59–1.29)
p=0.77
IL4R_02 AA 450(75.6) 459(77.1) 1
AC 138(23.2) 126(21.2) 1.12(0.85–1.47)
CC 7(1.2) 10(1.7) 0.71(0.27–1.89)
p=0.56
IL4R_06 AA 376(61.3) 387(63.1) 1
AG 212(34.6) 195(31.8) 1.12(0.88–1.42)
GG 25(4.1) 31(5.1) 0.83(0.48–1.43)
p=0.47
IL4R_23 CC 211(34.4) 219(35.7) 1
CT 307(50.0) 290(47.2) 1.10(0.86–1.41)
TT 96(15.6) 105(17.1) 0.95(0.68–1.33)
p=0.60
IL4_01 CC 454(73.7) 433(70.3) 1
CT 145(23.5) 163(26.5) 0.85(0.65–1.10)
TT 17(2.8) 20(3.2) 0.81(0.42–1.57)
p=0.41
IL6_01 GG 190(31.1) 194(31.8) 1
GC 295(48.3) 292(47.8) 1.03(0.80–1.33)
CC 126(20.6) 125(20.5) 1.03(0.75–1.41)
p=0.97
PTGS2_33 TT 274(44.7) 271(44.2) 1
CT 273(44.5) 276(45.0) 0.98(0.77–1.24)
CC 66(10.8) 66(10.8) 0.99(0.68–1.45)
p=0.98
TGFB1_01 TT 238(39.1) 224(36.8) 1
CT 281(46.2) 286(47.0) 0.92(0.72–1.18)
CC 89(14.6) 98(16.1) 0.85(0.61–1.20)
p=0.64
TGFB1_05 CC 289(47.8) 282(46.6) 1
CT 267(44.1) 259(42.8) 1.01(0.79–1.27)
TT 49(8.1) 64(10.6) 0.75(0.50–1.12)
p=0.33
TNF_02 GG 409(66.3) 404(65.5) 1
GA 181(29.3) 193(31.3) 0.93(0.73–1.18)
AA 27(4.4) 20(3.2) 1.33(0.74–2.42)
p=0.48
TNF_04 GG 556(89.5) 561(90.3) 1
GA 64(10.3) 58(9.3) 1.11(0.77–1.62)
AA 1(0.2) 2(0.3) 0.50(0.05–5.58)
p=0.72
TNF_07 CC 501(81.1) 516(83.5) 1
CT 111(18.0) 95(15.4) 1.20(0.89–1.62)
TT 6(1.0) 7(1.1) 0.88(0.29–2.65)
p=0.46
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Table 4.

Haplotype Analysis

Haplotype f(controls) f(cases)
IL1A (-01/-04/-02) p=0.43
 TAT 0.284 0.284
 GAC 0.436 0.419
 GCC 0.276 0.290
IL1B (-02/-01/-09) p=0.02
 CCG 0.455 0.484
 CTG 0.065 0.064
 CTC 0.266 0.216
 TCG 0.185 0.203
 TTC 0.029 0.030
IL2 (-03/-01) p=0.94
 GT 0.358 0.372
 GG 0.293 0.289
 TT 0.348 0.338
IL4R(-02/-06) p=1
 AA 0.792 0.785
 AG 0.087 0.089
 CG 0.120 0.126
IL10(-02/-01/-03) p=0.67
 CCG 0.485 0.503
 CCA 0.283 0.272
 ATA 0.230 0.223
TGFB1-01/MGC4093-03 p=0.55
 CT 0.321 0.300
 CC 0.077 0.080
 TC 0.600 0.619
TNF(-07/-02/-04) p=0.67
 CGG 0.675 0.658
 CGA 0.048 0.052
 CAG 0.189 0.189
 TGG 0.086 0.099
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Stratified analyses

Exploratory subgroup analyses were conducted among case-control pairs. We analyzed subsets of the cases and compared them to their matched controls to determine if there were any effects which were present only in a subgroup, and whose effect may be diminished in the overall sample. We stratified by histology (SCLC, NSCLC, SCC, and AC), experimental arm (active vs. placebo), age (<60, >60), smoking status (current vs. former), pack-years (<48, >48), and gender. However, given the large number of comparisons (23 polymorphisms × 14 subgroups) we chose p=0.01 for a significance threshold, and found no statistically significant associations within subgroups. Within the IL-1β promoter polymorphisms we found evidence for an effect across all subgroups (data not shown), with the strongest associations observed in the male, >48 pack-years, current smokers, SCC, and SCLC subgroups. Differences between subgroups did not reach statistical significance in tests for interaction. To investigate the possibility that the effect was dependent on tobacco exposure, the subjects were divided into quartiles. A trend across pack-years was not observed. We also repeated all of the analyses, using a data set which excluded the 98 cases without pathologic confirmation, and this did not alter our findings.

Discussion

The current study tested the hypothesis that variation in the genes that participate in the inflammatory response may increase or decrease risk of lung cancer, and may predict survival among patients with lung cancer. Using a nested case-control study design, this analysis further supports an association of IL-1β promoter polymorphisms and lung cancer risk. These results suggest that susceptibility to lung cancer may be, in part, defined by the individual’s genetic background of this pro-inflammatory cytokine. Additional pro-inflammatory genes tested in this study were not found to be associated with lung cancer risk.

Our cohort was defined prospectively from a large population at risk for lung cancer. We were able to achieve a very high degree of matching between cases and controls for all of the demographic variables which have previously been shown to be of importance in this cohort.33 As such, our analysis is less prone to bias than traditional case-control studies. Many of the cohorts in the literature are hospital-based studies and are thus enriched for disease that is amenable to surgery. This is less representative of the natural history of lung cancer than the present study, in which all incident cases were captured in a prospective cohort. Tobacco and asbestos exposures were well characterized in our study population prior to any of the subjects developing lung cancer. Follow-up procedures were thorough. While not as large as the multinational study of Campa,34 our study was adequately powered to detect effects which are likely to be of clinical significance, with odds ratios as low as 1.3-1.5. It should be noted that this study did not have adequate numbers of cases to perform an independent replication study; this inherently limits the generalizability of these results.

As with all gene association studies, multiple comparisons and subgroup analyses can lead to spurious associations. Our study population was predominantly of Caucasian origin. Different genotype frequencies between ethnic groups may partially explain the lack of association of inflammatory gene polymorphisms with lung cancer previously described in Asian populations.3538 This is similar to the variable results demonstrated in the gastric cancer literature.20 It should also be noted that population stratification within our predominantly Caucasian cohort may also influence our results, and that further validation studies are needed.

The IL-1β gene has been of interest because of its role as a pro-inflammatory cytokine produced by macrophages, monocytes, and lung epithelia. IL-1 has been shown to be upregulated in lung cancer. Higher IL-1 concentrations within tumors have been associated with a more virulent tumors and poor prognosis.39 Furthermore, VNTR polymorphisms in the IL-1βRN, which acts as a competitive ligand with IL-1, have been associated with lung cancer risk.26 IL-1β promoter polymorphisms have been shown to have an important role in the pathogenesis of gastric and other cancers. The IL-1β-511 and -31 polymorphisms lie in the promoter region and have been found to be in strong linkage disequilibrium.17,25 The –31 polymorphic position lies within a TATA-box element, with the variant C allele causing disruption of binding to the TATA-box.17 The variant -31C allele has been shown to be associated with a decreased promotion of IL-1β in in-vitro studies of human lung epithelial cells.40 This is felt to be secondary to the specific binding of a transcription factor (Yin Yang 1) to the -31C allele, decreasing transcription of IL-1β.41 This study did not test for the -31C>T SNP, however, in several studies IL-1β-31 and IL-1β-511 are perfectly concordant.17 As has been previously demonstrated, this study found a decreased odds of lung cancer in patients with either the homozygous or heterozygous -511T allele or -1464C allele.22,23,25 In the report by Zienolddiny, the less frequent IL-1β-31CC/IL-1β-511TT genotypes were associated with a decreased risk of lung cancer (OR = 0.40 for IL-1β-511 minor allele homozygotes and OR = 0.52 for heterozygotes) and a lower incidence of mutated p53 compared to the common allele.25

Interestingly, the Zienolddiny study of the IL-1 promoter polymorphism in NSCLC was expanded to a larger European cohort with 2135 cases and 2115 controls and no evidence of association between IL-1β –31T>C and lung cancer risk was found.34 Similarly, a study by Lind demonstrated an increased risk of NSCLC for individuals with the haplotype homozygous IL-1RN*1(an allele of the IL-1 VTRN with 4 repeats) and IL-1β-31T, but did not show an increased risk in individuals with -31T who were not homozygous for IL-1RN*1.26 It is possible that these discrepant results are secondary to varied genetic backgrounds of the populations being studied. Our study, in a predominantly Caucasian population, did not show an association between alleles of IL-1β rs1143634 and lung cancer, although prior studies in a Japanese population demonstrated an increased risk in individuals who were either homozygous or heterozygous for the T allele.38

This study provides further evidence for an IL-1β risk haplotype. While examining three specific SNPs, rs1143634A>C, rs16944 (-511T>C), and rs1143623 (-1646C>G), this study demonstrates a significantly increased rate of the haplotype CTC among controls, and conversely increased rate of the haplotype TCG among lung cancer cases (p=0.02). This further supports findings in studies by Landvik et al. and Li et al. which demonstrated similar trends in -511 and -1464 containing haplotypes.22,23 Rogus et al. demonstrate in vivo that subjects with haplotypes including homozygous -511C and -1464G alleles have 28-52% higher IL-1β levels.42 It is possible, therefore, that one explanation for the decreased rate of lung cancer in individuals containing -511T and -1464C haplotypes is decreased level of IL-1β production.

The fact that the same IL-1 promoter polymorphism may be protective in lung cancer and cancer-promoting in gastric cancer may be explained by interactions with H. Pylori and the effect of IL-1 on pH in gastric cancer. The direction of the effect noted in our study is consistent with the original report of Zienolddiny, although the magnitude is less.

The current study found a neutral effect of the T>C polymorphism in the 3′-UTR of COX-2 (rs5275). Also known as prostaglandin-endoperoxide synthase 2 (PTGS2), COX-2 is a key enzyme in the inflammatory response. Inhibitors of this enzyme have received significant attention as chemo-preventive and anticancer agents.43 COX-2 is over-expressed in NSCLC and is thought to be an adverse prognostic factor.44 There are several reports in the literature regarding the role of the T>C polymorphism in the 3′-UTR of COX-2 (rs5275) which ascribe the allele as either a neutral,34 protective,37 or predisposing45 risk factor for lung cancer. Our data are consistent with this allele having no effect on lung cancer risk.

This study did not find any correlation between genotype and lung cancer risk for TNFα, TGFβ1, IL-10 and IL-6, genes previously associated with risk in the literature.36,46 There are many possible reasons for the failure to replicate these prior findings. The initial reports may arise from chance, as many of the findings were present only in retrospectively defined subsets of the subjects studied and multiple hypotheses were investigated. Another possibility is that varied ethnic background of study populations may result in a different genetic background which confers a different biologic significance to a given functional polymorphism. Furthermore, the specific SNPs genotyped vary between studies. For example, recent work has shown a possible association between the -634 C>G (rs1800796) SNP of the IL-6 gene, which was not tested in our study.47,48 In our study of predominantly Caucasian individuals, the size of our study population and the minor allele frequencies for these four genes should have been sufficiently large to detect odds ratios as low as 1.3-1.5, thus the absence of findings makes it highly unlikely that a gene with a large OR is present among the inflammatory gene polymorphisms studied.

This study provides further evidence of a relationship between the IL-1β promoter polymorphisms and lung cancer risk. The central role of the IL-1 pathway in the initiation of the inflammatory response and the association of cancer risk with polymorphisms in this pathway justify further research into this area. Recombinant IL-1 receptor antagonists are already in clinical use for rheumatoid arthritis. Recently, the CANTOS trial demonstrated decreased incidence of and mortality from lung cancer in patients treated with canakinumab, a humanized monoclonal antibody that inhibits IL-1β.49 As further studies examine the role of this pathway in cancer promotion, translational research clarifying the role of this pathway in lung cancer could proceed rapidly.

Acknowledgments

This work was funded by grants from the National Cancer Institute (R21CA101791, K12CA076930, U01CA063673, and P30CA015704) and the Seattle Foundation (TE3680).

We acknowledge the technical assistance of Mari Malkki, Michelle Bauer, and Paula Filipcic.

Footnotes

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Summary Conflict of Interest: The authors have no conflicts of interest to report.

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