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Four Common Vascular Endothelial Growth Factor Polymorphisms (−2578C>A, −460C>T, +936C>T, and +405G>C) in Susceptibility to Lung Cancer: A Meta-Analysis

  • Ling Lin,

    Affiliation Department of Thoracic Surgery, Shanghai Chest Hospital, School of Medicine, Shanghai Jiaotong University, Shanghai, China

  • Kejian Cao,

    Affiliation Department of Thoracic Surgery, Shanghai Chest Hospital, School of Medicine, Shanghai Jiaotong University, Shanghai, China

  • Wenhu Chen,

    Affiliation Department of Thoracic Surgery, Shanghai Chest Hospital, School of Medicine, Shanghai Jiaotong University, Shanghai, China

  • Xufeng Pan,

    Affiliation Department of Thoracic Surgery, Shanghai Chest Hospital, School of Medicine, Shanghai Jiaotong University, Shanghai, China

  • Heng Zhao

    h_zhao24@126.com

    Affiliation Department of Thoracic Surgery, Shanghai Chest Hospital, School of Medicine, Shanghai Jiaotong University, Shanghai, China

Abstract

Background and Objective

Vascular endothelial growth factor (VEGF) is one of the key initiators and regulators of angiogenesis and it plays a vital role in the onset and development of malignancy. The association between VEGF gene polymorphisms and lung cancer risk has been extensively studied in recent years, but currently available results remain controversial or ambiguous. The aim of this meta-analysis is to investigate the associations between four common VEGF polymorphisms (i.e., −2578C>A, −460C>T, +936C>T and +405C>G) and lung cancer risk.

Methods

A comprehensive search was conducted to identify all eligible studies to estimate the association between VEGF polymorphisms and lung cancer risk. Crude odds ratios (ORs) with 95% confidence intervals (CIs) were used to evaluate the strength of this association.

Results

A total of 14 published case-control studies with 4,664 cases and 4,571 control subjects were identified. Our meta-analysis provides strong evidence that VEGF −2578C>A polymorphism is capable of increasing lung cancer susceptibility, especially among smokers and lung squamous cell carcinoma (SCC) patients. Additionally, for +936C>T polymorphism, increased lung cancer susceptibility was only observed among lung adenocarcinoma patients. In contrast, VEGF −460C>T polymorphism may be a protective factor among nonsmokers and SCC patients. Nevertheless, we did not find any association between +405C>G polymorphism and lung cancer risk, even when the groups were stratified by ethnicity, smoking status or histological type.

Conclusion

This meta-analysis recommends more investigations into the relationship between −2578C>A and −460C>T lung cancer risks. More detailed and well-designed studies should be conducted to identify the causal variants and the underlying mechanisms of the possible associations.

Introduction

Lung cancer, characterized by uncontrolled cell growth in tissues of the lung [1], accounts for 13% (1.6 million) of the total cancer cases and 18% (1.4 million) of total deaths in 2008 [2]. Lung cancer has become a major public health challenge all over the world, especially in China [3]. Thus, understanding the molecular biology and etiology of lung cancer will be pivotal in designing targeted therapies and personalized medicines. The link to smoking as a definite causative agent for lung cancer has been well established from epidemiologic evidence since the 1950s [4], [5]. However, epidemiological data showed that only 10–15% of heavy tobacco smokers ultimately develop lung cancer [6], [7], suggesting that certain common genetic variants or polymorphisms may influence the risk of lung cancer, particularly among those who have developed lung cancer. Vascular endothelial growth factor (VEGF), also known as vascular permeability factor, is one of the key initiators and regulators of angiogenesis and it plays a critical role in the progress and prognosis of malignancy [8][10]. Evidence from in vitro and in vivo experiments have shown that high levels of VEGF expression were found to be associated with tumor growth and metastasis, whereas the inhibition of VEGF signaling results in suppression of both tumor-induced angiogenesis and tumor growth [11][13]. Bevacizumab, one of the agents for recognizing and blocking vascular endothelial growth factor A (VEGF-A), has been a promising agent in a combination regimen in improving the overall survival and progression-free survival of breast cancer, non-small-cell lung cancer, renal cell carcinoma, and other solid malignancies [14], [15].

The VEGF gene, which contains a 14-kb coding region with eight exons and seven introns, is located on chromosome 6p21.3 [16]. At least 30 single nucleotide polymorphisms (SNPs) in VEGF gene have been identified and described, and some have even been shown to affect the expression of VEGF gene [17], [18]. Several previously published meta-analyses showed that VEGF +936C>T (rs3025039), one of the most common polymorphisms, was not associated with gastric cancer [19][21], colorectal cancer [22], or breast cancer [23][25]. Additionally, these published meta-analyses also showed that other three common VEGF polymorphisms, −1154G>A (rs1570360), −634G>C (rs2010963) and −460C>T (rs833061), were not associated with colorectal cancer [26] or breast cancer [24], whereas the VEGF −634G/C polymorphism was found to be associated with gastric cancer [20]. In recent years, four common polymorphisms in VEGF gene, −2578C>A, −460C>T, +936C>T, and +405C>G, have been described in several literatures to appear to be involved in the development of lung cancer [27][31]. However, the results remain controversial or inconclusive. To the best of our knowledge, there were no published meta-analyses investigating the association between VEGF gene polymorphisms and lung cancer susceptibility. Therefore, we performed a meta-analysis of all eligible case-control or cohort studies to investigate whether these functional VEGF polymorphisms are associated with any increased risk of lung cancer and whether the associations are modulated by smoking status, histological type or other risk factors. We hope our meta-analysis can potentially be important in early lung cancer identification and become part of the therapeutic strategies in combating lung cancer.

Materials and Methods

Literature Search

Relevant papers for this meta-analysis were systematically identified through literature searches on PubMed, Embase, Web of science and Chinese National Knowledge Infrastructure (CNKI), and Chinese Biomedical Literature Database (CBM) of publications published up to March 9, 2013 relating to VEGF gene polymorphisms and lung cancer risk. As the main search criteria, we used combinations of the following terms: "VEGF", "vascular endothelial growth factor A", "vascular permeability factor", "vascular endothelial growth factor", "lung neoplasms", "pulmonary neoplasms", "bronchial neoplasms", "lung cancer", "bronchial neoplasm", "genetic polymorphism", "single nucleotide polymorphism", "SNP", "mutant", "gene variation". We also reviewed the reference lists of articles retrieved to identify relevant publications.

Inclusion and Exclusion Criteria

Our meta-analysis included genetic association studies fulfilling the following inclusion criteria: (a) a case-control, cohort or cross-sectional study must evaluated at least one of four polymorphisms of VEGF gene and lung cancer risk; (b) the diagnosis of lung cancer patients was confirmed pathologically and controls were confirmed as cancer-free patients; (c) inclusion of sufficient data on the size of the sample, odds ratio (OR), and 95% confidence interval (CI) and (d) articles were published in the English or Chinese language.

Studies were excluded when they represented duplicates of previous publications, or were meta-analyses, case report, letters, reviews or editorial articles. Studies investigating the progression, severity, phenotype modification, response to treatment, or survival were also excluded. Additionally, when data was included in multiple studies using the same case series, either the study with the largest sample size or most recent publication was selected. Finally, family-based studies were excluded because of different design settings. Any disagreements on study inclusion were resolved through discussions between the authors. To ensure the rigour of the current meta-analysis, it was designed and reported according to the Preferred Reporting Items for Systematic Reviews and Meta-analyses (PRISMA) statement. The relevant checklist is shown in Supplement S1.

Data Extraction

All data from the included studies were extracted independently by two investigators, using a piloted data standardized form (when it came to conflicting evaluations, an agreement was settled after a discussion): the first author’s surname, year of publication, country of origin, published language, gender of study individuals and ethnic subgroups, study design, number of subjects, smoking status, histological types of lung cancer, SNP genotyping methods, genotyping method and detected sample, allele and genotype frequencies, and evidence of Hardy-Weinberg equilibrium (HWE) in controls. In addition, we also compared key study characteristics such as location, study time and authorship to determine the existence of multiple publications from the same study.

Quality Assessment of Included Studies

Two authors independently assessed the quality of the published articles according to the modified STROBE quality score systems [32]. Forty assessment items matching with the quality appraisals were used in this meta-analysis, with scores ranging from 0 to 40. Scores of 0–20, 20–30 and 30–40 were defined as low, moderate and high quality, respectively. The two authors resolved their differences through discussions; if no agreement could be reached, a third author decided on a decision. The modified STROBE quality score system is available in Supplement S2.

Statistical Analysis

Crude ORs together with their corresponding 95% CIs were used to calculate and assess the strength of association between VEGF gene polymorphisms and lung cancer risk under five genetic models: allele, dominant, recessive, homozygous, and heterozygous models. The deviation of frequency from those expected under Hardy-Weinberg equilibrium (HWE) was assessed by Chi-squared goodness of fit tests in controls. We explored inter-study variation through prespecified subgrouping of studies according to ethnicity (ie, Caucasian or Asian), gender (ie, female or male), smoking status (ie, smoker or non-smoker), and histological type of lung cancer (ie, adenocarcinoma, squamous cell carcinoma (SCC), and small cell carcinoma (SCLC), where applicable. The statistical significance of the pooled OR was assessed with a Z test. Between-study variation and heterogeneity were estimated using Cochran’s Q-statistic, with P<0.05 as a cutoff for statistically significant heterogeneity [33].

We also quantified the effect of heterogeneity with the I2 test (ranges from 0 to 100%), which represents the proportion of inter-study variability that can be attributed to heterogeneity rather than to chance [34]. The fixed effects model (Mantel-Haenszel method) was used, except when a significant Q-test (P<0.05) or I2>50% indicated the existence of heterogeneity among studies; otherwise, the random effects model (DerSimonian-Laird method) was applied for meta-analysis. In order to ensure the reliability of our results, sensitivity analysis was performed by omitting individual studies. Begger’s funnel plots were used to detect publication bias. In addition, Egger’s linear regression test, which measures funnel plot asymmetry via a natural logarithm scale of OR, was also used to evaluate publication bias [35]. All P-values were two-sided. Analyses were conducted with STATA Version 12.0 software (Stata Corp, College Station, TX).

Results

The Characteristics of Included Studies

Our initial literature search yielded 546 reports, which included 13 population-based [28][31], [36][44] and one hospital-based [27] case-control studies meeting the inclusion criteria based on the search criteria for lung cancer susceptibility linking to at least one of four common SNPs of VEGF gene, −2578C>A, −460C>T, +936C>T, and +405C>G. The flow diagram of the selection of studies and specific reasons for exclusion from the meta-analysis are shown in Figure 1. We studied four VEGF SNPs in 4,664 unrelated lung cancer cases and 4,571 unrelated controls from 14 case-control studies. In the eligible studies, there were 12 studies of subjects of Asian descent and only two studies of subjects of Caucasian descent. All included studies extracted DNA from peripheral blood and the VEGF polymorphisms were determined by classic PCR-RFLP in 12 studies, by TaqMan in 1 study, and by PIRA-PCR in another study. SNP genotypes were tested for departures from HWE for controls and all SNPs were in HWE. The qualities of the included studies were moderately high, with a STROBE score of greater than 20. The selected study characteristics were summarized in Table 1. The evaluation of the associations between VEGF −2578C>A, −460C>T, +936C>T, and +405C>G polymorphisms and lung cancer risk are presented in Tables 2, 3, 4 and 5.

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Figure 1. Flow diagram of the selection process of the studies and specific reasons for exclusion from the present meta-analysis.

https://doi.org/10.1371/journal.pone.0075123.g001

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Table 1. Main characteristics and methodological quality of all eligible studies.

https://doi.org/10.1371/journal.pone.0075123.t001

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Table 2. Subgroup analyses for the associations of VEGF −2578C/A with susceptibility to lung cancer in Asians.

https://doi.org/10.1371/journal.pone.0075123.t002

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Table 3. Subgroup analyses for the associations of VEGF −460C/T with susceptibility to lung cancer.

https://doi.org/10.1371/journal.pone.0075123.t003

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Table 4. Subgroup analyses for the associations of VEGF +936C/T with susceptibility to lung cancer under dominant model.

https://doi.org/10.1371/journal.pone.0075123.t004

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Table 5. Subgroup analyses for the associations of VEGF +405C/G with susceptibility to lung cancer.

https://doi.org/10.1371/journal.pone.0075123.t005

VEGF −2578C>A Polymorphism and Risk of Lung Cancer

A total of 7 studies with 22 data sets involving 1,596 cases and 1,857 controls were included in the pooled analysis. All subjects were of Asian ethnicity. Meta-analysis results showed that a statistically significant correlation was found between −2578C>A polymorphism and susceptibility to lung cancer in Asians under allele and homozygous models (for OR = 1.31, 95%CI = 1.10–1.57, P = 0.003; OR = 1.79, 95%CI = 1.30–2.46, P<0.001). We also performed a stratified analysis based on the geographic region of the studies; the results were persistent in both Chinese (for allele model: OR = 1.25, 95%CI: 1.05–1.49, P = 0.014; recessive model: OR = 1.88, 95%CI: 1.27–2.79, P = 0.002; homozygous model: OR = 2.00, 95%CI: 1.42–2.81, P<0.001; heterozygous model: OR = 2.06, 95%CI: 1.07–3.97, P = 0.032) and India populations (for allele model: OR = 1.75, 95%CI: 1.37–2.24, P<0.001; dominant model: OR = 1.26, 95%CI: 4.54–11.6, P<0.001; heterozygous model: OR = 1.08, 95%CI: 1.03–1.19, P<0.001) (Figure 2A). Additionally, a stratified analysis according to smoking status was performed using the information on packs of cigarettes smoked multiply by years of smoking; the variant allele is significantly correlated with increased risk of lung cancer among smoker subgroup(for allele model: OR = 2.18, 95%CI: 1.55–3.09, P<0.001; dominant model: OR = 1.67, 95%CI: 1.17–2.39, P = 0.005; homozygous model: OR = 7.31, 95%CI: 2.14–25.0, P = 0.002; heterozygous model: OR = 3.71, 95%CI: 1.06–13.0, P = 0.041), while not in nonsmokers (P>0.05 for all comparisons) (Figure 2B). Furthermore, we also stratified the case group by histological types and the data indicated the presence of the variant allele was the most strongly associated with SCC (for allele model: OR = 1.90, 95%CI: 1.43–2.52, P<0.001; dominant model: OR = 1.39, 95%CI: 1.01–1.90, P = 0.041; recessive model: OR = 4.87, 95%CI: 2.47–9.61, P<0.001; homozygous model: OR = 5.64, 95%CI: 2.79–11.4, P<0.001; heterozygous model: OR = 3.97, 95%CI: 1.94–8.10, P<0.001) (Figure 2C).

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Figure 2. Forest plot of ORs for the association between VEGF −2578C>A polymorphism and susceptibility to lung cancer in subgroup analysis based on country of origin (A), smoking status (B), and histological type (C) under the dominant model.

https://doi.org/10.1371/journal.pone.0075123.g002

VEGF −460C >T Polymorphism and Risk of Lung Cancer

VEGF −460C>T polymorphism was investigated in six studies with a total of 3,167 cases and 2,769 controls. There was no evidence of association between −460C>T polymorphism and lung cancer risk (for allele model: OR = 0.94, 95%CI: 0.79–1.12, P = 0.495; dominant model: OR = 0.86, 95%CI: 0.59–1.24, P = 0.415; recessive model: OR = 0.98, 95%CI: 0.73–1.32, P = 0.788; homozygous model: OR = 0.89, 95%CI: 0.60–1.33, P = 0.579; heterozygous model: OR = 1.01, 95%CI: 0.79–1.28, P = 0.969). Again, lung cancer cases and controls did not significantly differ in the subgroup analyses based on ethnicity (data not shown) (Figure 3A). However, when stratified analysis by smoking status was performed, a lower prevalence of the variant allele was observed among nonsmokers (for dominant model: OR = 0.32, 95%CI: 0.18–0.55, P<0.001; recessive model: OR = 0.35, 95%CI: 0.20–0.61, P<0.001) (Figure 3B). Additionally, further analysis on histological type was performed, and we found that −460C>T polymorphism was significantly associated with decreased risk of SCC (for allele model: OR = 0.81, 95%CI: 0.68–0.96, P = 0.013; dominant model: OR = 0.71, 95%CI: 0.48–0.97, P = 0.026; homozygous model: OR = 0.69, 95%CI: 0.46–0.94, P = 0.015; heterozygous model: OR = 0.81, 95%CI: 0.65–0.99, P = 0.020), but not in adenocarcinoma and SCLC patients (P>0.05 for all comparisons) (Figure 3C).

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Figure 3. Forest plot of ORs for the association between VEGF −460C>T polymorphism and susceptibility to lung cancer in subgroup analysis based on ethnicity (A), smoking status (B), and histological type (C) under the dominant model.

https://doi.org/10.1371/journal.pone.0075123.g003

VEGF +936C>T Polymorphism and Risk of Lung Cancer

Eight studies investigated the association between +936C>T polymorphism and lung cancer susceptibility with a total of 3,288 cases and 3,092 controls. We did not find any association between +936C>T genotype and lung cancer risk under the dominant model (OR = 1.19, 95%CI: 0.86–1.63, P = 0.301), even when the groups were stratified by ethnicity (Caucasian: OR = 0.99, 95%CI: 0.80–1.22, P = 0.9372; Asian: OR = 1.28, 95%CI: 0.77–2.12, P = 0.338), gender (male: OR = 1.00, 95%CI: 0.81–1.23, P = 0.972; female: OR = 1.12, 95%CI: 0.92–1.38, P = 0.266), or smoking status (smokers: OR = 0.74, 95%CI: 0.39–1.41, P = 0.360; nonsmokers: OR = 1.56, 95%CI: 1.01–2.43, P = 0.052). Nevertheless, in the subgroup analysis on histological subtype, increased lung cancer susceptibility was shown among the adenocarcinoma subgroup (OR = 1.24, 95%CI: 1.03–1.44, P = 0.012) (Figure 4).

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Figure 4. Forest plot of ORs for the association between VEGF +936C>T polymorphism and susceptibility to lung cancer in subgroup analysis based on ethnicity (A), gender (B), smoking status (C), and histological type (D) under the dominant model.

https://doi.org/10.1371/journal.pone.0075123.g004

VEGF +405C>G Polymorphism and Risk of Lung Cancer

A total of six studies involving 3,035 cases and 2,880 controls were included in the pooled analysis. The overall data did not show a marked association between +405C>G polymorphism and lung cancer risk in any genetic model, indicating that individuals with G allele might not have an increased lung cancer risk compared with those who carry wild-type C allele (for allele model: OR = 1.03, 95%CI: 0.80–1.31, P = 0.840; dominant model: OR = 1.23, 95%CI: 0.60–2.50, P = 0.573; recessive model: OR = 0.815, 95%CI: 0.62–1.05, P = 0.108; homozygous model: OR = 0.92, 95%CI: 0.62–1.37, P = 0.689; heterozygous model: OR = 0.70, 95%CI: 0.46–1.07, P = 0.099). Likewise, stratified analyses were also conducted according to ethnicity, smoking status and histological type of cancer. Unfortunately, there was no statistical difference in genotype distributions between cases and controls, and overall and different subgroups (P>0.05 for all comparisons; data not shown).

Sensitivity Analysis and Publication Bias

Sensitivity analysis was performed to assess the influence of each study on the pooled ORs by omitting individual studies. The analysis results suggested that no individual study significantly altered the pooled ORs in VEGF −2578C>A, −460C>T, +936C>T, and +405C>G polymorphisms under the allele model (data not shown), which indicates that our studies were statistically accurate.

Begger's funnel plot and Egger's linear regression test were performed on the metadata to assess publication bias of the individual studies. The shapes of the funnel plots did not reveal any evidence of obvious asymmetry in VEGF −2578C>A (A), −460C>T (B), +936C>T (C), and +405C>G (D) polymorphisms (Figure 5). Egger's test also displayed no significant statistical evidence of publication bias (−2578C>A: t = 0.99, P = 0.369; −460C>T: t = 0.53, P = 0.623; +936C>T: t = 0.28, P = 0.786; +405C>G: t = −1.08, P = 0.339).

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Figure 5. Funnel plots showed symmetric distribution.

Log OR is plotted against the standard error of log OR for studies on VEGF −2578C>A (A), −460C>T (B), +936C>T (C) and +405C>G (D) polymorphisms. The dots represent specific studies for the indicated association.

https://doi.org/10.1371/journal.pone.0075123.g005

Discussion

Evidence from preclinical and clinical studies shows that VEGF, as a predominant angiogenic factor in human cancers, plays a vital role in the carcinogenesis pathway, which has been proved to be a key step in tumor occurrence, progression and prognosis [12], [45]. Several functional polymorphisms of VEGF gene have been confirmed to be correlated with high levels of VEGF protein in cancer cells and high tumor angiogenic activity, and they also contribute to the susceptibility and severity of cancer, including lung cancer [36]. Although cigarette smoking is the major cause of lung cancer, only a small fraction of smokers develop this disease during their lifetime, which suggests that both genetic factors and lifestyle risk factors are modulating individual susceptibility to lung cancer risk. A study by Koukourakis et al. reported that non-small cell lung cancer patients with specific VEGF gene polymorphisms develop tumors with low VEGF expression and poor vascularization [46]. In recent years, the associations between VEGF and risk of lung cancer have been extensively investigated, obtaining conflicting results. Therefore, we employed a meta-analysis to explore a more precise evaluation for the associations. To our knowledge, this is the first meta-analysis on this topic.

The present meta-analysis, including 4,664 cases and 4,571 controls from 14 published case-control studies, explored the association between VEGF −2578C>A, −460C>T, +936C>T, and +405C>G polymorphisms and lung cancer risk. According to our pooled analysis, −2578C>A polymorphism may have a correlation with increased lung cancer risk. This finding may be biologically plausible since Koukourakis et al. observed that −2578CC was associated with lower VEGF expression and lower vascular density in lung cancer tissues compared to the −2578C C/A [46]. When lung cancer cases were stratified by histological subtype, the data indicated that the presence of −2578A was strongly associated with SCC, while similar finding was not observed in SCLC and adenocarcinoma. Although a research reported by Jin et al. demonstrated that −2578AA genotype was significantly associated with low histologic grade tumors [47], the reason for such a divergence of VEGF expression and angiogenic status in tumors of similar histologic type and differentiation remains obscure. Thus, more studies should be conducted to further examine the underlying mechanism. Furthermore, the stratified analysis according to smoking status revealed that −2578A is significantly correlated with increased risk of lung cancer among smokers, suggesting that this polymorphism may not be an independent risk factor, but perhaps an effect modifier that acts synergistically with smoking in lung cancer risk.

As for VEGF −460C>T polymorphism, the overall data did not show a marked association of this polymorphism with lung cancer risk in any genetic model, even in the subgroup analyses according to ethnicity. However, when stratified analysis by smoking status and histological type were performed, a lower prevalence of −460T allele was observed among nonsmokers, lung adenocarcinoma cases, and SCC cases. Some clinical evidence suggests that cigarette smoking may stimulate both angiogenesis and VEGF expression, which exacerbates the rapid cancer progression effect of angiogenesis [48], [49]. Thus, it is possible that cigarette smoke and VEGF activate multiple effects in lung cancer. For VEGF +936C>T, +405C>G polymorphisms, we found no overall association between these two polymorphisms or its interaction with smoking on lung cancer risk in any genetic model. When stratified analyses were conducted according to ethnicity and histological types of cancer, increased lung cancer susceptibility was only observed among the adenocarcinoma subgroup for +936C>T polymorphism, while there was no statistical difference in genotype distributions between cases and controls for any different subgroups for +405C>G polymorphism. Actually, there exist conflicting reports in some literatures regarding the exact function of the +405G/C polymorphism. Some clinical studies suggested that +405C allele has been associated with lower VEGF production, while some groups reported higher VEGF levels or even no association with +405C/C genotype [17], [50], [51]. Thus, whether these polymorphisms are truly functional requires further investigation through confirmatory studies and in vitro functional assays.

The current meta-analysis has several limitations that should be noted. First, the sample size in the present study was relatively small, so small, but potential, genetic effects may not be detectable. A small sample size may not have enough statistical power to explore the real association, especially in subgroup analysis. Additionally, as with other complex traits, lung cancer risk may also be modulated by several other genetic markers beyond VEGF, and our meta-analysis emphasized that elucidating the pathogenesis of lung cancer would demand an investigation into the association for many gene variants that may constitute distinct pathophysiological pathways. Third, we identified two studies from Caucasian populations and obtained no data from African populations, thus the two racial groups need to be further studied in the future. Therefore, the results should ideally be confirmed in further studies to strengthen the conclusions. Aside from the limitations listed above, our meta-analysis still has some strength. To the best of our knowledge, this is the first meta-analysis on the relationship between VEGF gene polymorphisms and lung cancer. We also explored inter-study variations by prespecified subgrouping of studies according to ethnicity, smoking status, gender, and histological type among cases. Furthermore, although this meta-analysis does not accommodate all previously published data, they are limited compared to the evidence that we generated.

In conclusion, this meta-analysis provides strong evidence that VEGF −2578C>A polymorphism is capable of increasing lung cancer susceptibility, especially among smokers and lung SCC patients. Additionally, for +936C>T polymorphism, increased lung cancer susceptibility was only observed among lung adenocarcinoma patients. In contrast, VEGF −460C>T polymorphism may be a protective factor among nonsmokers, lung adenocarcinoma and SCC patients. However, we did not find any association between +405C>G polymorphism and lung cancer risk, even when the groups were stratified by ethnicity, smoking status or histological type. More detailed and well-designed studies with larger population and different ethnicities are needed to further evaluate these associations.

Supporting Information

Supplement S2.

Modified STROBE quality score systems.

https://doi.org/10.1371/journal.pone.0075123.s002

(DOC)

Author Contributions

Conceived and designed the experiments: LL KJC HZ. Performed the experiments: LL WHC. Analyzed the data: XFP. Contributed reagents/materials/analysis tools: LL KJC. Wrote the paper: LL KJC WHC XFP HZ.

References

  1. 1. D'Amico A, Pennazza G, Santonico M, Martinelli E, Roscioni C, et al. (2010) An investigation on electronic nose diagnosis of lung cancer. Lung Cancer 68: 170–176.
  2. 2. Jemal A, Bray F (2011) Center MM, Ferlay J, Ward E, et al (2011) Global cancer statistics. CA Cancer J Clin 61: 69–90.
  3. 3. Molina JR, Yang P, Cassivi SD, Schild SE, Adjei AA (2008) Non-small cell lung cancer: epidemiology, risk factors, treatment, and survivorship. Mayo Clin Proc 83: 584–594.
  4. 4. Doll R, Hill AB (1950) Smoking and carcinoma of the lung; preliminary report. Br Med J 2: 739–748.
  5. 5. Parkin DM, Pisani P, Lopez AD, Masuyer E (1994) At least one in seven cases of cancer is caused by smoking. Global estimates for 1985. Int J Cancer 59: 494–504.
  6. 6. Tang D, Santella RM, Blackwood AM, Young TL, Mayer J, et al. (1995) A molecular epidemiological case-control study of lung cancer. Cancer Epidemiol Biomarkers Prev 4: 341–346.
  7. 7. Toh CK, Gao F, Lim WT, Leong SS, Fong KW, et al. (2006) Never-smokers with lung cancer: epidemiologic evidence of a distinct disease entity. J Clin Oncol 24: 2245–2251.
  8. 8. Miller DL, Dibbens JA, Damert A, Risau W, Vadas MA, et al. (1998) The vascular endothelial growth factor mRNA contains an internal ribosome entry site. FEBS Lett 434: 417–420.
  9. 9. Barbera-Guillem E, Nyhus JK, Wolford CC, Friece CR, Sampsel JW (2002) Vascular endothelial growth factor secretion by tumor-infiltrating macrophages essentially supports tumor angiogenesis, and IgG immune complexes potentiate the process. Cancer Res 62: 7042–7049.
  10. 10. Evensen L, Micklem DR, Blois A, Berge SV, Aarsaether N, et al. (2009) Mural cell associated VEGF is required for organotypic vessel formation. PLoS One 4: e5798.
  11. 11. Ferrara N (2002) VEGF and the quest for tumour angiogenesis factors. Nat Rev Cancer 2: 795–803.
  12. 12. Hicklin DJ, Ellis LM (2005) Role of the vascular endothelial growth factor pathway in tumor growth and angiogenesis. J Clin Oncol 23: 1011–1027.
  13. 13. Andersen S, Donnem T, Al-Shibli K, Al-Saad S, Stenvold H, et al. (2011) Prognostic impacts of angiopoietins in NSCLC tumor cells and stroma: VEGF-A impact is strongly associated with Ang-2. PLoS One 6: e19773.
  14. 14. Shih T, Lindley C (2006) Bevacizumab: an angiogenesis inhibitor for the treatment of solid malignancies. Clin Ther 28: 1779–1802.
  15. 15. Welch S, Spithoff K, Rumble RB, Maroun J (2010) Bevacizumab combined with chemotherapy for patients with advanced colorectal cancer: a systematic review. Ann Oncol 21: 1152–1162.
  16. 16. Vincenti V, Cassano C, Rocchi M, Persico G (1996) Assignment of the vascular endothelial growth factor gene to human chromosome 6p21.3. Circulation 93: 1493–1495.
  17. 17. Watson CJ, Webb NJ, Bottomley MJ, Brenchley PE (2000) Identification of polymorphisms within the vascular endothelial growth factor (VEGF) gene: correlation with variation in VEGF protein production. Cytokine 12: 1232–1235.
  18. 18. Ruggiero D, Dalmasso C, Nutile T, Sorice R, Dionisi L, et al. (2011) Genetics of VEGF serum variation in human isolated populations of cilento: importance of VEGF polymorphisms. PLoS One 6: e16982.
  19. 19. Zhou Y, Hu W, Zhuang W, Liu GJ, Wu TX, et al. (2010) Vascular endothelial growth factor (VEGF) +936 C/T gene polymorphisms and gastric cancer risk: a meta-analysis involving 4,138 subjects. Int J Biol Markers 25: 213–218.
  20. 20. Liu H, Wang S, Huang C (2011) VEGFA+936C/T and -634G/C polymorphisms and gastric cancer risk: a meta-analysis. Asian Pac J Cancer Prev 12: 1979–1983.
  21. 21. Zhang C, Li JP, Zhou P (2011) Vascular endothelial growth factor (VEGF) +936 C/T gene polymorphism and gastric cancer risk: appraisal of a recent meta-analysis. Int J Biol Markers 26: 274–275.
  22. 22. Zhou LP, Luan H, Dong XH, Jin GJ, Man DL, et al. (2011) Vascular endothelial growth factor +936C/T polymorphism and gastric cancer risk: A meta-analysis. Exp Ther Med 2: 931–936.
  23. 23. Gu D, Wang M (2011) VEGF 936C>T polymorphism and breast cancer risk: evidence from 5,729 cases and 5,868 controls. Breast Cancer Res Treat 125: 489–493.
  24. 24. Wang K, Liu L, Zhu ZM, Shao JH, Xin L (2011) Five polymorphisms of vascular endothelial growth factor (VEGF) and risk of breast cancer: a meta-analysis involving 16,703 individuals. Cytokine 56: 167–173.
  25. 25. Yang DS, Park KH, Woo OH, Woo SU, Kim AR, et al. (2011) Association of a vascular endothelial growth factor gene 936 C/T polymorphism with breast cancer risk: a meta-analysis. Breast Cancer Res Treat 125: 849–853.
  26. 26. Zhou LP, Luan H, Dong XH, Jin GJ, Man DL, et al. (2011) Vascular endothelial growth factor gene polymorphisms and colorectal cancer risk: a meta-analysis. Genet Mol Res 10: 3674–3688.
  27. 27. Zhai R, Liu G, Zhou W, Su L, Heist RS, et al. (2008) Vascular endothelial growth factor genotypes, haplotypes, gender, and the risk of non-small cell lung cancer. Clin Cancer Res 14: 612–617.
  28. 28. Liang J (2009) Vascular endothelial growth factor polymorphisms and risk of lung cancer. Chinese-German Journal of Clinical Oncology: 269–272.
  29. 29. Li Y, Liang J, Liu X, Liu H, Yin B, et al. (2012) Correlation of polymorphisms of the vascular endothelial growth factor gene and the risk of lung cancer in an ethnic Han group of North China. Exp Ther Med 3: 673–676.
  30. 30. Naykoo NA, Hameed I, Aasif M, Shaffi S, Yousuf Q, et al.. (2013) Single nucleotide polymorphisms, haplotype association and tumour expression of the vascular endothelial growth factor (VEGF) gene with lung carcinoma. Gene.
  31. 31. Sun SF, Huang DB, Cao C, Deng ZC (2013) Polymorphism of VEGF-460C/T associated with the risk and clinical characteristics of lung cancer in Chinese population. Med Oncol 30: 410.
  32. 32. da Costa BR, Cevallos M, Altman DG, Rutjes AW, Egger M (2011) Uses and misuses of the STROBE statement: bibliographic study. BMJ Open 1: e000048.
  33. 33. Higgins JP, Thompson SG (2002) Quantifying heterogeneity in a meta-analysis. Stat Med 21: 1539–1558.
  34. 34. Zintzaras E, Ioannidis JP (2005) Heterogeneity testing in meta-analysis of genome searches. Genet Epidemiol 28: 123–137.
  35. 35. Peters JL, Sutton AJ, Jones DR, Abrams KR, Rushton L (2006) Comparison of two methods to detect publication bias in meta-analysis. JAMA 295: 676–680.
  36. 36. Lee SJ, Lee SY, Jeon HS, Park SH, Jang JS, et al. (2005) Vascular endothelial growth factor gene polymorphisms and risk of primary lung cancer. Cancer Epidemiol Biomarkers Prev 14: 571–575.
  37. 37. Yuan JJ (2011) [Study on the association of VEGF genetic polymorphisms with Primary Lung Cancer]: Hebei Medical University.
  38. 38. Wang T, Wang R, Zeng H (2008) [Vascular endothelial growth factor gene polymorphisms and risk of lung cancer]. Academic Conference.
  39. 39. Tan H, Ding CM, Jia SX, Li Y (2008) [Effect of vascular endothelial growth factor polymorphisms in non-small-cell lung cancer]. Academic Conference.
  40. 40. Naik NA, Bhat IA, Afroze D, Rasool R, Mir H, et al. (2012) Vascular endothelial growth factor A gene (VEGFA) polymorphisms and expression of VEGFA gene in lung cancer patients of Kashmir Valley (India). Tumour Biol 33: 833–839.
  41. 41. Liu DS (2010) [Study of the association of VEGF genetic polymorphism with the risk of Primary Lung Cancer]: Hebei Medical University.
  42. 42. Liu CJ (2012) [Study on the association of VEGF genetic polymorphisms with Lung Cancer]: Hebei Medical University.
  43. 43. Li PX, Gan LG, Ruan L, Wei ZX (2012) [Polymorphism of VEGF +936C/T associated with the risk of lung cancer]. Journal of Guangxi Medical University: 100–101.
  44. 44. Gao F, Zhou XT, Zhang ZF, Guo Y (2012) [Relationship between single nucleotide polymorphisms of -460T/C in VEGF gene and the suscpetibility of lung cancer in Hebei province]. Chin J of Cancer Prev and Treat: 575–578.
  45. 45. Yoshiji H, Gomez DE, Shibuya M, Thorgeirsson UP (1996) Expression of vascular endothelial growth factor, its receptor, and other angiogenic factors in human breast cancer. Cancer Res 56: 2013–2016.
  46. 46. Koukourakis MI, Papazoglou D, Giatromanolaki A, Bougioukas G, Maltezos E, et al. (2004) VEGF gene sequence variation defines VEGF gene expression status and angiogenic activity in non-small cell lung cancer. Lung Cancer 46: 293–298.
  47. 47. Jin Q, Hemminki K, Enquist K, Lenner P, Grzybowska E, et al. (2005) Vascular endothelial growth factor polymorphisms in relation to breast cancer development and prognosis. Clin Cancer Res 11: 3647–3653.
  48. 48. Conklin BS, Zhao W, Zhong DS, Chen C (2002) Nicotine and cotinine up-regulate vascular endothelial growth factor expression in endothelial cells. Am J Pathol 160: 413–418.
  49. 49. Kanda Y, Watanabe Y (2007) Nicotine-induced vascular endothelial growth factor release via the EGFR-ERK pathway in rat vascular smooth muscle cells. Life Sci 80: 1409–1414.
  50. 50. Awata T, Inoue K, Kurihara S, Ohkubo T, Watanabe M, et al. (2002) A common polymorphism in the 5′-untranslated region of the VEGF gene is associated with diabetic retinopathy in type 2 diabetes. Diabetes 51: 1635–1639.
  51. 51. Balasubramanian SP, Cox A, Cross SS, Higham SE, Brown NJ, et al. (2007) Influence of VEGF-A gene variation and protein levels in breast cancer susceptibility and severity. Int J Cancer 121: 1009–1016.