Time-Dependent Changes of Plasma Concentrations of Angiopoietins, Vascular Endothelial Growth Factor, and Soluble Forms of Their Receptors in Nonsmall Cell Lung Cancer Patients Following Surgical Resection

Kopczynska, Ewa; Dancewicz, Maciej; Kowalewski, Janusz; Makarewicz, Roman; Kardymowicz, Hanna; Kaczmarczyk, Agnieszka; Tyrakowski, Tomasz

doi:https://doi.org/10.5402/2012/638352

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Volume 2012 | Article ID 638352 | https://doi.org/10.5402/2012/638352

Time-Dependent Changes of Plasma Concentrations of Angiopoietins, Vascular Endothelial Growth Factor, and Soluble Forms of Their Receptors in Nonsmall Cell Lung Cancer Patients Following Surgical Resection

Ewa Kopczynska,¹Maciej Dancewicz,²Janusz Kowalewski,²Roman Makarewicz,³Hanna Kardymowicz,⁴Agnieszka Kaczmarczyk,⁴and Tomasz Tyrakowski¹

Academic Editor: J. Klijanienko, S. Ran

Received02 Jan 2012

Accepted22 Jan 2012

Published26 Mar 2012

Abstract

Even when patients with nonsmall cell lung cancer undergo surgical resection at an early stage, recurrent disease often impairs the clinical outcome. There are numerous causes potentially responsible for a relapse of the disease, one of them being extensive angiogenesis. The balance of at least two systems, VEGF VEGFR and Ang Tie, regulates vessel formation. The aim of this study was to determine the impact of surgery on the plasma levels of the main angiogenic factors during the first month after surgery in nonsmall cell lung cancer patients. The study group consisted of 37 patients with stage I nonsmall cell lung cancer. Plasma concentrations of Ang1, Ang2, sTie2, VEGF, and sVEGF R1 were evaluated by ELISA three times: before surgical resection and on postoperative days 7 and 30. The median of Ang2 and VEGF concentrations increased on postoperative day 7 and decreased on day 30. On the other hand, the concentration of sTie2 decreased on the 7th day after resection and did not change statistically later on. The concentrations of Ang1 and sVEGF R1 did not change after the surgery. Lung cancer resection results in proangiogenic plasma protein changes that may stimulate tumor recurrences and metastases after early resection.

1. Introduction

Surgical resection remains the standard treatment for patients with stage I nonsmall cell lung cancer (NSCLC). Even in patients who undergo surgical resection at an early stage of NSCLC, recurrent disease often impairs the clinical outcome. The postoperative 5-year survival rate for stage IA and IB NSCLC was reported to range from 72% to 46% in America and in European countries [1, 2].

The major cause of death among cancer patients is angiogenesis-mediated progression of micrometastases (<1 mm in diameter) to lethal macrometastases (≥1 mm) [3]. Recent findings suggest that the critical regulators of the angiogenic switch are bone-marrow-derived endothelial progenitor cells (EPCs) [3]. The soluble factors (e.g., VEGF) secreted by tumors promote the release of both bone-marrow-derived EPCs (including CD34+ VEGFR2+ cells) and hematopoietic cells (including Tie2 expressing monocytes, CXCR4+VEGFR1+ hemangiocytes) into the peripheral circulation and their recruiting to primary tumor or metastatic lesions [4]. The level of circulating bone marrow-derived EPCs is significantly increased in NSCLC patients and correlated with the clinical situation [5, 6]. EPCs contribute to neovascularization by direct luminal incorporation into sprouting nascent vessels [7] and via paracrine secretion of proangiogenic growth factors [8].

The balance of at least two systems, VEGF-VEGFR and Ang-Tie, regulates vessel formation. VEGF is a potent mitogen for micro- and macrovascular endothelial cells derived from arteries, veins, and lymphatics. It directly induces endothelial cell proliferation, migration, and tube formation. The biological effects of VEGF are mediated by two tyrosine kinase receptors, Flt1 (VEGF R1) and KDR (VEGF R2) [9, 10]. Alternative splicing of these mRNA receptors results in soluble forms of each receptor [11]. The soluble form of VEGF R1 (sVEGF R1) inhibits VEGF activity by sequestering VEGF from signaling receptors and by forming nonsignaling heterodimers with VEGF R2 [12].

Ang1 and Ang2 act through competitive binding to the extracellular domain of the endothelial cell—specific receptor tyrosine kinase Tie2. While Ang1 is an agonist, Ang2 could act as an antagonist or agonist depending on cell type and microenvironmental conditions. Several cell types in various tissues express Ang1. Ang2 is mainly expressed in endothelial cells located at sites of vascular remodeling, and it is stored in intracellular WeibelPalade bodies. Ang2 destabilizes capillary integrity by the disruption of connections between the endothelium and the perivascular cells and alone promotes cell death and vessel regression, but, in conjunction with VEGF, it promotes neovascularization. Ang1 mediates migration, adhesion and survival of endothelial cells—it can elicit an antiapoptotic effect. Generally, it has stabilizing effects on blood vessels and anti-inflammatory properties and acts as a sealing-up factor [13, 14]. According to recent findings (2010) [15], the Ang1/Tie2 signal regulates not only vascular quiescence but also angiogenesis. Downstream signaling of Ang1/Tie2 is dependent on the presence or absence of cell-cell contacts. When cell-cell adhesions are disrupted by VEGF, Ang1 induces the formation of ECM-anchored Tie2 and accelerates angiogenesis cooperatively with VEGF. Soluble Tie2 (sTie2), differently from sVEGF R1, is released from Tie2-expressing ECs by a yet unidentified mechanism. Several factors may influence this shedding process. sTie2 is not capable of signal transduction, but by binding to free Ang1 and Ang2 in the plasma it modulates the impact of these factors on angiogenesis [16].

Clinical studies have demonstrated that surgery is associated with changes in plasma composition that make the patient more susceptible to tumor recurrence [17, 18]. Among plasma proteins whose concentrations are altered after surgery are angiogenic factors.

The aim of this study was to determine the impact of surgery on the plasma levels of the main angiogenic factors during the first month after surgery in non-small cell lung cancer patients.

2. Materials and Methods

2.1. Study Population

The study included patients with stage I of non-small cell lung cancer, who underwent tumor resection without any preoperative therapy. These patients were treated in the University Hospital Department of Thoracic Surgery and Tumors, Collegium Medicum in Bydgoszcz, Nicolaus Copernicus University in Toruń, during the years 2008–2010. Three blood samples were taken from each patient: one prior to surgery and others on postoperative days 7 and 30.

The experiment was conducted with the understanding and the consent of the human subject. The study protocol was approved by the Ethical Committee of the Collegium Medicum in Bydgoszcz, Nicolaus Copernicus University in Toruń (Poland).

2.2. Blood Sampling and Processing

Ang1, Ang2, sTie2, VEGF, sVEGF R1 concentrations were evaluated in plasma. Four millilitres of blood were taken from elbow vein. EDTA was used as an anticoagulant. Within 30 minutes after the collection, the blood samples were centrifuged at 2–8°C for 15 minutes at 1000 × g. For complete platelet removal, an additional centrifuge at 10,000 × g for 10 minutes was applied. The plasma was stored at −70°C.

2.3. Angiogenic Factors Determinations

Ang1, Ang2, sTie2, VEGF, sVEGF R1 concentrations were assayed by commercially available sandwich enzyme-linked immunosorbent assay kits from R&D Systems (Quantikine Human Ang1, Ang2, sTie2, VEGF, sVEGF R1 Immunoassay, R&D Systems Inc., Minneapolis, USA). Kits are designed to measure human Ang1, Ang2, sTie2, VEGF, sVEGF R1 in cell culture supernates, serum, plasma, and other biological fluids. Plasma samples for detection of these five factors were diluted 15-, 5-, 10-, 1-, 10-folded, respectively.

2.4. Statistical Analysis

Statistical analysis was done using nonparametric Mann-Whitney’s test, Wilcoxon signed-rank test, and Pearson’s linear correlation. The results were considered statistically significant for .

3. Results

The study group consisted of 37 patients with non-small cell lung cancer (10 females and 27 males) aged 42 to 80 (with an average age of ). By the standards of clinical staging, all patients were classified as stage I (IA-9, IB-28). Twenty-five patients had squamous cell carcinoma, 6-adenocarcinoma and 6-other histological types of tumor (large cell anaplastic and neuroendocrine carcinoma). The most frequent histological grade was G2 (moderately differentiated).

Table 1 presents concentrations of Ang1, Ang2, sTie2, VEGF, and sVEGF R1 before the surgical treatment of lung cancer patients as well as on the 7th and 30th days after tumor resection. The concentration of Ang1 did not significantly change after resection. The median of Ang2 concentration increased on the 7th day (3688.70 versus 2501.30 pg/mL; ) and subsequently decreased on the 30th day (2858.25 versus 3688.70 pg/mL; ), but it was still elevated in comparison to the pretreatment state (2858.25 versus 2501.30 pg/mL; ). Changes in VEGF concentration were similar to those observed for Ang2; the median of VEGF increased on the 7th day (238.50 versus 124.40 pg/mL; ). However, the concentration of sTie2 decreased on the 7th day after resection (22,567.0 versus 24,806.0 pg/mL; ) and did not change statistically later on. The concentration of sVEGF R1 did not change after resection.

In this study, factor correlations were estimated (Table 2). The correlation of Ang1 and Ang2 was weak, both positive and negative, at all observation points (before: ; after 7: ; after 30: ). The correlation between Ang1 and sTie2 was weak and constant (; ; ); on the other hand, the correlation between Ang2 and sTie2 was repeatedly strong, from slightly negative to highly positive (; ; ). Correlation coefficients for dependence between Ang1 and VEGF were high (; ; ); however, for Ang2 and VEGF were from moderately positive to slightly negative (; ; ). The correlations between VEGF and sVEGF R1 as well sTie2 and sVEGF R1 were moderate.

4. Discussion

Many patients with solid tumors who undergo surgical resection develop local recurrences and remote metastases from residual tumor cells postoperatively. There are numerous causes potentially responsible for a relapse of the disease, one of them being extensive angiogenesis.

Although the postoperative angiogenesis response is well established after surgery, the exact causes and sources of angiogenic factors remain unclear. It is proposed that surgery-induced hypoxia, metabolic changes, and inflammation are the three major causes of the production of angiogenic factors in cancer cells as well as in normal cells (e.g., immune cells and fibroblasts) [19]. Upon surgery, hypoxia-inducible factor (HIF) induces the expression of downstream angiogenic factors such as VEGF and Ang2 in residual cancer cells [20]. An HIF-independent angiogenesis pathway is mainly mediated by the transcriptional coactivator PGC-1 α (peroxisome-proliferator-activated receptor-gamma coactivator-1-α). It is a potent metabolic sensor and regulator induced by a lack of nutrients and oxygen, and it powerfully regulates VEGF expression and angiogenesis in cultured muscle cells and in skeletal muscle in vivo [21]. Surgery-related inflammation is another crucial contributor to angiogenic response following surgical tumor resection. The infiltrating macrophages, immature dendritic cells, and carcinoma-activated fibroblasts are recruited to the surgical site and release numerous angiogenic factors [22].

The aim of this study was to determine the impact of surgery on the plasma levels of the main angiogenic factors during the first month after surgery. VEGF is the most potent promoter of angiogenesis. Ang2 supports VEGF proangiogenic effects. Ang1 stabilizes mature blood vessels. Soluble Tie2 modulates the impact of both proteins on angiogenesis by binding free Ang1 and Ang2 in the bloodstream. VEGFR1 binds VEGF and limits the proangiogenic effects of VEGF at the level of endothelial cells [9–16].

We found that lung cancer surgery is associated with significantly increased plasma VEGF and Ang2 levels postoperatively. VEGF was increased for at least 7 days, Ang2 for 30 days; however, sTie2 was decreased. All of these changes are proangiogenic. Plasma Ang1 and sVEGFR1 concentrations did not change significantly in the postoperative period. Although Ang1 levels did not change and Ang2 increased, the Ang1/Ang2 ratio remained unchanged, but there was a tendency for unfavorable decrease. The Ang1/Ang2 ratio may be more important than angiopoietin levels and it depends on the angiogenic phase; when Ang2 expression is relatively higher than that of Ang1, the induction of tumor angiogenesis is triggered (the “angiogenic switch” is turned on).

Postoperatively increased plasma concentrations of VEGF and Ang2 should be considered in conjunction with those of their inhibitors: sVEGFR1 and sTie2, respectively. The lack of change in sVEGF R1 and a decrease in total sTie2 blood concentration after surgery should result in a greater amount of VEGF and Ang2 free to bind to EC-bound receptors. The VEGF/sVEGFR1 and Ang2/sTie2 ratios were greater both on postoperative days 7 and 30 than the preoperative baseline, and the effective concentrations of VEGF and Ang2 were increased after surgery.

In our study, a correlation between Ang2 and VEGF before surgery was noted (). A higher correlation was found between Ang1 and VEGF, both before surgery () and on postoperative days 7 () and 30 ().

The problem concerning NSCLC resection has not been addressed in published studies (according to our searches), although Kumara et al. [23–25] investigated this issue in colorectal cancer. We obtained results similar to theirs. As colorectal resection is associated with persistent proangiogenic plasma protein changes (increase of VEGF and Ang2 levels), Shantha Kumara et al. [26] assessed the impact of preoperative and postoperative plasma on in vitro endothelial cell behavior. Postoperative plasma stimulates in vitro endothelial cell growth, migration and invasion, so it may stimulate the growth of residual tumor.

Elevated plasma VEGF levels could have an impact on tumor recurrence, growth of micrometastases, or development of new metastases in the early postoperative period. There are some good reasons to believe that (1) VEGF is a critical cytokine in tumor angiogenesis and a target for therapy [27], (2) tumor growth is intensified by VEGF, which binds to endothelial cells and initiates the process of new blood vessel formation [28], (3) high preoperative blood VEGF levels are associated with more advanced disease and a worse prognosis in lung cancer patients [29, 30].

Similarly to VEGF, an increased plasma Ang2 concentration may contribute to angiogenesis-mediated relapse of the disease due to the following facts: (1) Ang2 destabilizes capillary integrity and, in conjunction with VEGF, promotes neovascularization [31] as well as tumor angiogenesis [32]; (2) increased plasma/serum concentration of Ang2 was observed in various cancers, among others in lung cancer [33], breast and prostate cancer [34], and cervical cancer [35]; (3) in many studies the correlation between Ang2 expression and tumor progression was observed [36–39]; (4) the expression/concentration of Ang2 correlates with various angiogenesis factors, for example, with VEGF in liver cancer [39], which suggests their synergistic role in the regulation of tumor angiogenesis.

5. Conclusions

All the presented data seem to suggest that proangiogenic plasma alterations after surgery may result in cancer patients developing recurrent disease either from unrecognized tissue microfoci of tumor cells or from viable cells that persist in the circulation. The inclusion of angiogenic factors in the postoperative diagnostics of lung cancer could lead to improved follow-up therapy and individual antiangiogenic therapy.

Conflict of Interests

The authors declare that they have no conflict of interests.

Acknowledgment

The research was supported by the grant of Nicolaus Copernicus University in Toruń, no. 21/2010.

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Copyright © 2012 Ewa Kopczyńska et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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