Introduction
Lung cancer is the leading cause of cancer related death in the developed world, accounting for 12% of deaths worldwide [
1]. Median survival for the majority of patients with advanced non-small cell lung cancer (NSCLC) is 18 months and 9 months for locally advanced or metastatic disease respectively [
2]. Current therapeutic strategies are relatively ineffective, which is reflected by an overall survival rate of just 15% [
3].
Arachidonic acid (AA) can be converted to various eicosanoids by enzymes such as cyclooxygenase (COX), lipoxygenase (LOX), or epoxygenases (cytochrome P-450). The cyclooxygenase enzymes consist of two isoforms, COX-1 and COX-2, which catalyze the first step in the generation of downstream prostanoids from arachidonic acid [
4]. COX-derived prostanoids are involved in a wide range of physiological processes, but have also been implicated in a range of disease states, such as arthritis, heart disease, and pulmonary hypertension [
5]. In the past number of years, there has been significant interest in the role of COX-2 in cancer development and progression. Expression of this enzyme has been associated with a poor prognosis in lung cancer [
6‐
8], while a potential role for COX-2 in lung cancer chemoprevention has been investigated in a number of clinical trials [
9‐
11]. However, chronic administration of high concentrations of selective COX-2 inhibitors has been associated with an increased risk of adverse cardiovascular events [
12‐
14]. Recent studies suggest that the tumour-promoting effects of COX-2 over-expression may be attributable to downstream products of AA metabolism. Increased COX-2 expression is associated with increased levels of downstream enzymes required for prostanoid synthesis, such as prostaglandin E
2 synthase (PGE-S), prostaglandin D
2 synthase (PGD-S), and thromboxane A
2 synthase [
15]. However, the relationship of prostanoid profile to cancer growth is not fully understood.
Thromboxane synthase (TXS) activity was first described in platelets [
16]. The enzyme was later purified as a 60 kDa hemoprotein with spectroscopic characteristics of the cytochrome P-450 family [
17]. TXS metabolises the cyclooxygenase product, prostaglandin H2, into thromboxanes, which are biologically active on cancer cells. TXA
2 is a potent vascoconstrictor and bronchoconstrictor, as well as a potent promoter of platelet aggregation [
18,
19]. TXS and its product, TXA
2, have been shown to promote proliferation, invasion, metastasis and angiogenesis in a variety of cancers [
20‐
24]. TXS over-expression has been reported in thyroid, prostate, colorectal, and bladder cancer [
20‐
22,
24,
25]. Over-expression of this enzyme has been associated with a significant reduction in survival in bladder cancer [
21]. In addition, analysis of prostate tumour specimens revealed increased TXS levels in patient samples of advanced stage and grade [
22,
25]. Thromboxane synthase expression has been associated with tumour growth in a variety of cancers, both
in-vivo and
in-vitro[
21,
24,
26,
27]. A number of these studies have demonstrated a significant reduction in tumour cell growth following selective TXS inhibition [
21,
24,
26], suggesting that targeting this enzyme may have therapeutic efficacy in cancer. Specific thromboxane synthase inhibition has been shown to induce apoptosis, providing a further rationale for therapeutic intervention [
26,
28].
While the expression and role of thromboxane synthase has been examined in a number of cancers and has demonstrated significant promise, this enzyme has not yet been investigated in NSCLC. Due to the clear role of COX-2 in NSCLC pathogenesis, investigation of the downstream TXS enzyme would be of significant interest and relevance. The aim of this study was therefore to examine the expression profile of thromboxane synthase in NSCLC, relative to matched controls. We aimed to correlate TXS expression patterns with a range of clinical parameters, including overall survival (to determine if it is prognostic in the disease). Finally, we also wished to examine the effect of both TXS inhibition and TXS overexpression on in-vitro NSCLC survival mechanisms.
Methods
Patients and tumour specimens
Patients who had received primary chemotherapy (neoadjuvant) treatment were excluded from this study. For protein analysis, a series of 26 fresh-frozen NSCLC specimens (13 Adenocarcinomas and 13 Squamous Cell Carcinomas) with corresponding matched normal tissue from the same individual were collected at surgery at St. James's Hospital. All samples were evaluated by a pathologist immediately following dissection.
For generation of a NSCLC tissue microarray (TMA), paraffin blocks from 204 patients who underwent chemotherapy with surgical resection at St. James's Hospital (2000-2005) for NSCLC of varying histology, stage, and grade were collected. Patients who underwent pre-operative chemotherapy, or were found to have stage IV disease were excluded. Patient tumours were staged according to the tumour-node-metastasis (TNM) classification and histologically classified according to the World Health Organization guidelines. The NSCLC tissue samples were classified as 1) adenocarcinoma, 2) squamous cell carcinoma, and 3) others. Patients range in age from 41 years to 86 years. Patients were followed up by the tumour registries for survival time and outcome with median follow-up of 60 months (ranging from 1 to 88 months).
Generation of NSCLC tissue microarrays
Tissue microarrays were assembled using a tissue arraying instrument (Beecher Instruments, Silver Spring, MD). A 3 mm diameter stylet was used for sampling, with three replicate core samples of tumour taken from different regions in each donor block to account for tumour heterogeneity. Four μM sections of the resulting microarray blocks were cut on a microtome (Leica Microsystems Inc., IL, USA) and dried onto poly-L-lysine-coated glass slides (BDH Laboratory Supplies, Poole, England).
RNA isolation and reverse-transcription PCR analysis
A-549 and SKMES-1 cells for RNA analysis were collected in 1 mL of Tri-Reagent (Molecular Research Center, OH, USA). Total RNA was subsequently isolated according to manufacturers' instructions. RNA quantification was determined spectrophotometrically (Nanodrop technologies, DE, USA), with RNA concentration subsequently used to carry out cDNA synthesis (reverse-transcription). First strand cDNA was prepared using Superscript III according to the manufacturers' instructions (Invitrogen Corporation, CA, USA). cDNA was generated using random primers (Promega, WI, USA), and synthesis reactions were carried out for 3 h at the appropriate temperature. Expression of TXS and
β-actin was examined by RT-PCR using previously published primers [
20,
29].
PCR cycling conditions were as follows:
β-actin: 95°C for 5 min, followed by 35 cycles of (1 min at 94°C, 1 min at 56°C, 1 min at 72°C), with a final extension at 72°C for 10 min.
TXS: 94°C for 5 min, followed by 35 cycles of (30 s at 94°C, 30 s at 55°C, 45 s at 72°C) with a final extension at 72°C for 10 min.
β-actin levels were utilized as the internal loading control for each sample analysed.
Western blot analysis
Primary tissue protein lysates were extracted from NSCLC specimens and matched normal lung tissue using Tri-Reagent (MRC), according to the manufacturers' instructions. Protein samples (25 μg) were separated by pre-cast SDS-PAGE and transferred to PVDF membranes. Membranes were probed overnight at 4°C with a primary antibody directed against thromboxane synthase (1:250 dilution, Cayman, Michigan, USA). Following probing, blots were stripped and re-probed for β-actin (1:20,000, Merck Biosciences, Germany) to normalize for loading differences. Densitometric analysis was carried out on all TXS tumour/normal matched western blots and corresponding β-actin controls. Analysis was carried out using TINA (version 4.0) software (Raytest, Germany). Protein expression was normalized to β-actin controls, and was expressed as a ratio of TXS expression: β-actin expression.
Immunohistochemical staining
COX-2 and TXS staining of NSCLC tissue was carried out manually using Vectastain Elite Kits (Vector labs, Burlingame, CA, USA). Immunostaining was carried out using a rabbit polyclonal IgG specific for COX-2 (1:600 dilution, Cayman Chemical), or a rabbit polyclonal IgG specific for TXS (1:500 dilution, Cayman Chemical). Slides were incubated in the primary antibody for 1 h at room temperature (COX-2), or overnight at 4°C (TXS). Staining was visualised using a ScanScope GL digital slide scanner and Aperios ImageScope software (Aperio Technologies Inc., CA, USA).
Quantification of staining intensity
Staining in NSCLC tissue micro-array tissue was blindly scored and quantified by three independent observers (M.C.C., K.G. and G.P.). Expression levels within tumour tissue was quantified across three representative cores per patient as a product of the staining intensity (0 = negative, 1 = weak, 2 = moderate, 3 = strong) x percentage cells stained (< 25%, < 50%, < 75%, < 100%). Staining intensity was quantified under high magnification (x 20), using Aperio Image Scope software (Aperio Technologies). Expression patterns were correlated with a range of clinical parameters such as patient demographics (gender), tumour classifications (tumour subtype, stage, grade, and nodal status) and overall survival.
Enzyme immunoassay analysis of metabolite generation
Plasma levels of TXB2 (thromboxane A2 metabolite) were measured in a retrospective panel of NSCLC plasma samples and age-matched controls (50 chemo-naive patient samples, 19 cancer-free controls). Control samples were taken from patients with no known history of cancer. Plasma samples were isolated from whole blood by centrifugation at 3,000 × g for 10 min. Enzyme immunoassay kits (Assay Designs, MI, USA) were used to determine TXB2 levels in plasma isolated from NSCLC patients and age-matched controls. The assay was carried out according to manufacturers' instructions.
In-vitro experiments
Cell culture and chemicals
Two lung cancer cell lines, A-549 (adenocarcinoma) and SKMES-1 (squamous cell carcinoma) were obtained from and the American Type Culture Collection (Rockville, MD, USA). They were maintained in a humidified atmosphere of 5% CO2 in air at 37°C. A-549 cells were maintained in F-12 (Hams) medium, supplemented with 10% (v/v) foetal bovine serum (FBS), penicillin streptomycin, and L-glutamine. SKMES-1 cells were maintained in Modified Eagle's Medium + Earle's medium (MEM), supplemented with 10% (v/v) FBS, penicillin streptomycin, L-glutamine and non-essential amino acids. Subculturing was carried out when the cells reached 80% confluency. The selective thromboxane synthase inhibitor, ozagrel, was obtained from Cayman.
Generation and characterisation of stable transfectant clones
Human TXAS cDNA was a gift from Prof. Kenneth V. Honn (Wayne State University, Detroit, MA, USA). A 1.5 Kb DNA fragment containing the entire TXAS coding sequence was digested from pBluescript plasmid DNA and inserted into the site of the mammalian vector pcDNA3.1(-) (Invitrogen Corporation, CA, USA) to generate pcDNA3.1(-)-TXAS. The two mammalian vector constructs were individually transfected into SKMES-1 cells. Stable transfection of vector constructs were carried out using FuGENE 6™ transfection reagent (Roche Diagnostics Ltd., Sussex, UK). Approximately 3 × 105 cells were cultured in their respective supplement-free medium. Cells were then transfected with either 1 μg pcDNA-TXS/3.1(-), or pcDNA-3.1(-) (control vector) in antibiotic-free media, containing 3 μL/mL FuGENE 6™, according to manufacturers' instructions. Following transfection, cells were further incubated for 24 h at 37°C. Antibiotic selection was then carried out by treating the cells with Geneticin G-418 (800 μg/mL). Following seven days of antibiotic selection, single cell colonies were selected and amplified. RNA and protein was the isolated from amplified clones isolated in order to examine relative TXS expression levels. The TXS clone with the highest TXS expression level was chosen for further analysis (along with corresponding empty vector control cells).
Cell proliferation analysis
A-549 and SKMES-1 lung cancer cells were seeded at a concentration of 5 × 103/well into 96-well plates and allowed to adhere at 37°C overnight. Following overnight incubation in serum-depleted media, cells were treated for 24 h with and without various concentrations (50 nM, 500 nM, 5 μM) of a selective thromboxane synthase antagonist (Cayman). Cell proliferation was then assessed by BrdU cell proliferation assay, according to the manufacturers' instructions (Roche).
Annexin-V-FITC/Propidium Iodide Apoptosis Assay
Cells were seeded in 6-well plates (at a dilution of 2.5 × 104, or 5 × 104 cells/well), which were allowed to adhere at 37°C overnight. Following this, cells were incubated for 48 h or 72 h in serum-depleted media (0.5% FBS). Cells and supernatants were then collected and transferred into flow tubes (BD Biosciences, MA, USA) for annexin-V-FITC apoptosis analysis by flow cytometry (FACS). Cells were prepared for FACS analysis according to manufacturers' instructions (Roche). Apoptosis levels were measured using a FACS Caliber flow cytometer (BD Biosciences), with data analysis carried out using dot plot analysis.
High content screening analysis
The effects of selective thromboxane synthase inhibition on apoptosis in A-549 and SKMES-1 cell lines was also examined by High Content Screening using the GE Analyser 1000 (GE/Amersham Biosciences, NJ, USA). Briefly, A-549 and SKMES-1 lung cancer cells were set-up in 96-well plates, and treated as previously described. Following treatment, a Multi-Parameter Apoptosis HitKit was used to assess three fundamental parameters related to apoptosis (nuclear morphology, mitochondrial mass/membrane potential and changes in f-actin content), according to manufacturers' instructions (Cellomics Inc., PA, USA). Stained plates were sealed and run on a GE Analyser 1000.
Cell death detection ELISA and DNA laddering
A-549 and SKMES-1 lung cancer cells were seeded at a concentration of 5 × 104/well into 12-well plates and allowed to adhere at 37°C overnight. Following overnight incubation in serum-depleted media, cells were treated for 24 h with and without various concentrations of the selective TXS antagonist, ozagrel (Cayman). The generation of cytoplasmic histone-associated DNA fragments (mono- and oligo nucleosomes) following apoptosis was then measured by Cell Death Detection ELISA (Roche). Sample preparation and the ELISA procedure were both carried out according to manufacturers' instructions. A similar experimental setup was carried out in 75 cm2 flasks, and apoptosis confirmed by DNA laddering analysis using a DNA-laddering kit (Roche).
Cell invasion assay
Tumour cell invasion was examined using a 96-well Cell Invasion Assay (Chemicon International, CA, USA). Briefly, 1 × 105 cells in 100 μL serum-free media were added per well to an invasion chamber, which had previously been rehydrated with serum-free media. The 96-well plate was then covered and incubated for 24 h at 37°C. Invasion analysis was then carried out according to manufacturers' instructions.
Statistical analysis
Statistical comparison of expression levels of these enzymes between tumour and matched control protein, and plasma samples was calculated using a 2-tailed Students t-test. Correlation analysis was carried out using a Linear (Pearson) Correlation test. Association between clinicopathological features and expression of these enzymes was assessed using a 2-tailed Students t-test for continuous data. Overall survival was examined using Kaplan-Meier's survival curves, with differences in survival assessed by the log-rank test. Statistical analysis for in-vitro experiments was carried out using ANOVA, with post-hoc analysis carried out using Tukey-Kramer multiple comparisons test. Results are expressed as mean ± SEM, with data taken as significant where p < 0.05. All statistical analysis was carried out using InStat Statistical Software Package version 3.0 with survival analysis carried out using SPSS version 16.0 (SPSS Inc., Chicago, IL, USA).
Discussion
The tumour-promoting effects of COX-2 over-expression may be attributable to specific downstream products of arachidonic acid metabolism [
30]. The function of thromboxane synthase and its prostanoid, thromboxane A
2 in the cardiovascular system have been extensively studied and are well known. The enzyme has been shown to have a major role in maintaining cardiovascular haemostasis, mediated through its effects on platelet activation and aggregation. The impact of thromboxane synthase on cancer development and progression has received considerable interest over the past number of years. Expression of this enzyme has been shown to promote tumourigenesis
via its effects on tumour growth, angiogenesis and metastasis [
20‐
22,
24]. However, the role of TXS in non-small cell lung cancer has not yet been investigated. The aim of the current study was to examine the expression profile of TXS in NSCLC and to determine whether expression of this enzyme is a prognostic factor or potential therapeutic target in the disease. Our study demonstrates that TXS expression is increased in NSCLC but was not a prognostic factor in the disease. However our data suggests that TXS promotes tumour growth and development, and is therefore a potential therapeutic target in NSCLC.
Examination of TXS expression pattern in matched tumour/normal protein samples revealed significantly increased expression in NSCLC samples relative to matched normal controls. TXS over-expression has been observed in a variety of other cancer types, including thyroid [
20], bladder [
21], prostate [
22] and colorectal cancer [
24]. TXS over-expression has been correlated with significantly reduced patient survival in bladder cancer [
21]. In prostate cancer, its expression was significantly correlated with advanced stage and grade. In this study, the authors suggested that TXS activity was dependant on COX-2 and to a lesser degree, COX-1 to supply the PGH2 substrate [
22,
25]. Previous studies in human lung carcinoma found levels of the downstream metabolite of TXS, TXB
2, to be significantly higher in tumour tissues relative to non-tumour controls [
31]. Circulating TXS prostanoid levels cannot be measured quantitatively due to its very short half-life. In order to determine fractional amounts circulating in the plasma, the amount of the stable TXA
2 metabolite, TXB
2 was measured in a retrospective panel of NSCLC plasma samples and age-matched controls. TXB
2 levels were significantly higher in patient samples, with basal control TXB
2 levels comparing favourably to previous studies (unpublished data). Our observation suggests that circulatory TXB
2 levels are increased in NSCLC, which may potentially impact on a patient's risk of developing venous thrombosis. Venous thromboembolism is a frequent cause of cancer-associated mortality [
32] and patients with NSCLC have a 20-fold elevated risk of thrombosis [
33]. In addition, increases in TXB
2 expression have been associated with increased lipid peroxidation and bcl2 expression [
31], suggesting that circulating TXB
2 levels may promote tumour formation, partly
via apoptosis evasion. As a result of our findings, we are setting up a study to prospectively examine the impact of circulating TXB
2 levels on thromboembolic events and prognosis in NSCLC.
The role of COX-2 in lung cancer is well established, with a number of clinical trials examining COX-2 inhibition as a potential therapy for NSCLC [
9‐
11]. COX-2 expression is required for PGH2 and subsequent prostanoid generation (including thromboxane A
2), and is therefore of importance for the activity and subsequent effects of TXS. This is supported by a previous report that TXS regulates tumour motility
via the COX-2 pathway in prostate cancer [
22]. Thromboxane A
2, the prostanoid product of TXS, has also been shown to mediate COX-2 dependant angiogenesis. Linear correlation analysis revealed a highly significant association of COX-2 with TXS expression, supporting previous observations [
22]. COX-2 and TXS expression levels were both significantly higher in adenocarcinoma patients, relative to squamous. The significance of these observations is unclear, but it has been observed that patients with adenocarcinoma are at a higher risk of developing venous thrombosis than those with squamous cell carcinoma [
33]. A significant increase in COX-2 and TXS expression was also observed in female patients, relative to males. While no studies have previously been carried out to determine a possible gender influence on the expression of these enzymes in cancer, recent studies in murine models have shown that levels of constrictor prostanoids such as COX-2 and TXA
2 are higher in females than males [
34]. Expression levels of both enzymes were not altered with either tumour stage or nodal status. Interestingly, both COX-2 and TXS expression levels were significantly lower in grade 3 tumours, relative to grade 2. These observations are in contrast to those in a prostate cancer study [
22], but are supported by previous observations in breast cancer [
35], suggesting that the expression pattern of this enzyme may vary between cancer types.
COX-2 expression has previously been associated with reduced patient survival in NSCLC [
6‐
8]. Our study noted similar observations. While COX-2 expression was not associated with a significant reduction in long-term (5-year) survival, statistical significance was observed for short-term (2-year) patient survival. In contrast, no significant correlation of TXS expression with patient survival was observed, even when TXS expression was examined in combination with levels of COX-2 expression. While this observation may seem surprising, given previous findings, similar observations have been observed in breast cancer patients where low levels of TXS expression were correlated with tumours of high grade and a predicted poor clinical outcome [
35]. The authors also found that levels of the thromboxane receptor (TP) were negatively associated with disease-free survival, suggesting that the downstream receptor, as opposed to its corresponding synthase, may be prognostic in the disease [
36].
Selective inhibition of TXS has been shown to reduce tumour cell proliferation/survival in a number of cancers including colorectal carcinoma [
24], and bladder cancer [
21]. In our study, selective inhibition of TXS significantly (and dose-dependently) reduced tumour cell growth in an adenocarcinoma and squamous cell NSCLC cell line. This was mirrored by a reduction in thromboxane metabolite (TXB
2) generation, as assessed by enzyme immunoassay of the culture medium (data not shown). In direct contrast, stable TXS over-expression significantly increased tumour cell growth in SKMES-1 cells, implicating this enzyme as a survival factor and potential therapeutic target in NSCLC. Our observations are in agreement with previous observations in a xenograft colorectal cancer model [
27], and suggest that TXS is a potential therapeutic target in NSCLC pathogenesis. While the effect of TXS inhibition on healthy cells was not examined, previous studies have shown that TXS blockade inhibits endothelial cell migration in response to VEGF or bFGF, suggesting an effect on normal cellular mechanisms [
23]. The significantly increased NSCLC TXS levels observed in our study suggests that TXS inhibition would have a preferential effect on tumour cells and warrants further investigation in NSCLC pathogenesis.
Increased apoptosis following TXS inhibition was demonstrated by High Content Screening (HCS), and quantified using In Cell Analyser software. Apoptosis was characterised by a reduction in mitochondrial mass/potential and
f-actin content in both cell lines following treatment with ozagrel. HCS observations were validated by DNA laddering and Cell Death Detection ELISA. These findings are consistent with a recent study by Moussa
et al. in bladder cancer [
26]. They are also supported by our further observations that stable TXS over-expression appeared to protect against tumour cell apoptosis, relative to controls. It may therefore be hypothesised that TXS exerts its effects on tumour cells, at least in part,
via inhibition of apoptosis. In addition to apoptosis however, TXS and its product, TXA
2 have also been implicated in the regulation of other cancer survival pathways such as angiogenesis [
23], migration [
21,
22], invasion [
21], and tumour cell metastasis [
23]. In our study TXS over-expression significantly increased the invasive capacity of SKMES-1 cells, suggesting another survival mechanism associated with over-expression. In order to further examine the mechanism underlying the effects of selective TXS inhibition, RT
2 Profiler™ Cancer PathwayFinder PCR arrays were used to examine the expression of a panel of genes implicated in tumourigenesis following 24 h treatment with ozagrel (additional file
1). Notable changes in gene expression following treatment were observed in pathways of apoptosis, angiogenesis and invasion/metastasis. While each cell line exhibited distinct gene expression profiles following TXS inhibition, a small subset of genes stood out as being of interest. These included the pro-apoptotic genes
Bax (4-fold increase),
Granzyme A (9-fold increase), and
TNF (4-fold increase) in A-549 cells and anti-apoptotic genes
Bcl2 (3-fold decrease) and
IGF1 (5-fold decrease) in SKMES-1 cells (Additional file
2, Figure S1). The previous observation that increases in circulating TXB
2 expression is associated with BCL2 expression lends support to our observations [
31]. In addition to the effects of TXS inhibition on tumour cell survival mechanisms, examination of downstream genetic pathways implicated in tumourigenesis is also of particular interest in NSCLC, with the potential to provide further insight into the anti-tumour effects of TXS inhibition.
In conclusion, TXS and its metabolite, TXB2, are over-expressed in NSCLC. While TXS was not found to be prognostic, our study clearly shows that it is pro-tumourigenic and may be a target for therapeutic intervention via induction of apoptosis. Inhibition of this enzyme may therefore be a suitable therapeutic approach for NSCLC treatment, either alone, or in combination with conventional chemotherapeutic agents.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
MCC carried out all in-vitro experiments (with the exception of high content screening) and drafted the manuscript. KG carried out high content screening analysis. KG also generated the NSCLC tissue microarrays, carried out TMA staining analysis (TXS and COX-2) and collected/isolated NSCLC protein and plasma samples (and relevant controls). RC aided in the generation of the NSCLC tissue microarrays. R.C. also cut sections from these TMAs and assisted in optimisation of both TXS and COX-2 IHC staining. EK participated in the design of the study and also provided technical (pathological) expertise in relation to the staining and grading of NSCLC tissue microarrays (and full-face sections) for both TXS and COX-2. KJO'B participated in the design and coordination of the study and provided technical expertise when drafting the manuscript. GPP played a major role in the design and coordination of the study. GPP also carried out TMA staining analysis (TXS and COX-2) and helped draft the manuscript. All authors read and approved the final manuscript.