Multi‑kinase inhibitors and cisplatin for head and neck cancer treatment in vitro
- Authors:
- Published online on: June 28, 2019 https://doi.org/10.3892/ol.2019.10541
- Pages: 2220-2231
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Copyright: © Brands et al. This is an open access article distributed under the terms of Creative Commons Attribution License.
Abstract
Introduction
According to the Robert Koch Institute, head and neck squamous cell carcinoma (HNSCC) is the sixth most common neoplastic disease, based on ~690,000 new cases worldwide, and 13,800 new cases per year in Germany (1). Despite advances in surgical, radioactive and molecular treatments, the 5-year overall survival rate of patients with HNSCC remains at 55–60%, with most deaths occurring due to organ failure resulting from multiple metastases, which are often resistant to conventional therapies (2). Notably, ≤70% of chemotherapy regimens for the treatment of HNSCC in the USA include cisplatin, underscoring its efficacy in the treatment of this type of cancer (3). However, acquired chemotherapy resistance is a problem in HNSCC (4), and patients who had previously received chemotherapy demonstrated lower response rates to second-line treatment compared with those who did not (5). A reason for this may be the presence of ATP-binding cassette (ABC) transporters (ABCB1, ABCC1 and ABCG2), which can promote multidrug resistance (MDR) (6). These proteins are known to be overexpressed in several types of tumor, and contribute to chemo-resistance due to their efflux pump function (7,8). Cisplatin has been identified as a substrate for ABCB1, ABCC and ABCG family members (9–11).
During the previous decade, cisplatin-based chemotherapies, which are most often used to treat HNSCC, were expanded to include targeted therapy with monoclonal antibodies and tyrosine kinase inhibitors (TKIs). However, the efficacy of TKIs, which were initially aimed at targeting epidermal growth factor receptor (EGFR), was limited; thus, novel therapeutic targets are being considered. In this context, various agents are applied to disrupt the altered signaling in the tumor microenvironment (TME), which comprises immune cells, the tumor vasculature, lymphatics, pericytes and cancer-associated fibroblasts, in addition to collagens and laminins (12–14). Indeed, the complex interaction between the tumor and the components of the TME is of relevance for cell migration, invasion and metastasis. As revealed in other cancer models, ectopic expression of fibroblast growth factor receptor (FGFR), a primary participant in the TME, markedly enhanced cisplatin resistance (15). Additionally, increased FGF2, FGFR2 and FGFR3 expression levels were observed in HNSCC tissues compared with in normal mucosal tissues, suggesting an autocrine influence on HNSCC carcinogenesis (16).
A number of TKIs, which interfere with tumor and micro-environmental interactions, were recently reported to modulate the activity of ABC transporters by directly blocking their efflux function (17). Therefore, the present study aims to investigate whether the TKIs pazopanib, dovitinib and nintedanib are able to enhance cisplatin efficacy in an in vitro model of head and neck cancer.
Materials and methods
The Cancer Genome Atlas (TCGA) analysis
Sample data for the analysis of MDR transporter mRNA expression in HNSCC was retrieved from TCGA via cBioPortal (18,19). Data for 530 cancer samples were analyzed with regard to genetic alterations in ABCB1, ABCC1 and ABCG2. Cases with and without alterations were compared in view of overall and median-month survival.
Cell lines
The cell lines used in the present study are listed in Table I. As previously described, the cells were cultured in a humidified atmosphere of 5% CO2/95% air at 37°C, and the culture medium (Dulbecco's Modified Eagle Medium; Thermo Fisher Scientific, Inc.) was changed 2 to 3 times a week (20). The cell lines were established at the Cancer Institute at the University of Pittsburgh (Pittsburgh, PA, USA), and have been used by our group in several studies, particularly in those investigating the cytotoxicity of anti-neoplastic drugs.
Drugs
Pazopanib (Glaxo Smith Kline GmbH and Co.), dovitinib (Novartis Pharma GmbH), nintedanib (Boehringer Ingelheim Pharma GmbH & Co.) and cisplatin (Accord Healthcare GmbH) were purchased from Selleck Chemicals. The targets of these TKIs are listed In Table II.
Crystal violet assay
A crystal violet assay was used to analyze drug efficiency. Following 24 h of incubation, the cells were exposed to various concentrations (log2 and log3 dilutions) of cisplatin (starting concentration, 400 µM), pazopanib (starting concentration, 800 µM), dovitinib (starting concentration, 200 µM) and nintedanib (starting concentration, 100 µM). Following cell incubation with the respective drugs for 72 h, the medium was removed and the cells were stained with crystal violet (1 mg/ml double distilled water, 20% methanol) for 12 min. After staining, the supernatant was discarded and the samples were washed several times with water and dried overnight. For absorbance detection using a plate reader (Rainbow Spectra), 100 µl methanol was added to each well for 10 min, and the optical density was measured at 595 nm.
RNA isolation, reverse transcription-quantitative PCR (RT-qPCR) and analysis of receptor expression levels
RNA was isolated from cell pellets using an RNeasy® Mini Kit (Qiagen), and the RNA concentration was determined spectrophotometrically at 260/280 nm using the NanoDrop 2000 (Thermo Fisher Scientific, Inc.). cDNA synthesis was performed with 1 µg of RNA/probe using the QuantiTect® reverse transcription kit (Qiagen) according to the manufacturer's protocol. Semi-quantitative gene expression levels were evaluated using RT-qPCR with the CFX96 Real-Time PCR Detection System (Bio Rad Laboratories, Inc.). The thermocycling conditions were as follows: Heat activation at 95°C for 15 min, followed by 40 cycles of denaturation at 94°C for 15 sec, annealing at 54°C for 30 sec and extension at 72°C for 30 sec. Amplification was performed using a QuantiTect® SYBR® Green PCR kit (Qiagen) in a total volume of 25 µl/probe with 1.5 µl gene-specific QuantiTect primers (Qiagen; listed in Table III). The values were derived from three independent experiments. mRNA levels were quantified using the relative expression RE(%)=2[Cet st(actin)-Ct(gen)] ×100 (21) and normalized to β-actin as the standard, with an assumed expression level of 100%.
Expression levels of ABC transporters in the cell lines were determined using RT-qPCR, whereby expression was determined as a function of PCR cycles as follows: i) Very strong expression ≥0.2; ii) strong expression=0.1–0.19; iii) intermediate expression=0.05–0.09; and iv) weak expression ≤0.04.
Statistical analysis
The results were derived from three independent experiments, and statistical analysis was conducted using Graph Pad Prism software version 6.05 (GraphPad Software, Inc.). The data are presented as the mean ± standard error of the mean between biological replicates. P<0.05 was considered to indicate a statistically significant difference, and P-values were categorized according to confidence intervals. Half inhibitory concentration (IC50) values (the drug concentration that reduced the colony formation efficiency by 50%) were calculated using non-linear regression analysis for mono- and combination treatment. Descriptive statistics were used to illustrate receptor expression. To determine a possible association between the expression level of each transporter and the efficacy of the individual TKI, Pearson's correlation analysis was performed.
Results
TCGA analysis
Analysis of MDR transporter mRNA expression in patients with HNSCC was conducted using data retrieved from TCGA. A total of 530 cases of HNSCC were analyzed with regard to genetic alterations in ABCB1 (18,19). The Kaplan-Meier plot shown in Fig. 1 illustrates the overall survival curves for patients with and without ABCB1 alterations. The median overall survival for cases with genetic alterations (32.46 months) was significantly shorter compared with those without alterations (64.78 months; P=0.0197).
Expression of ABCB1, ABCC1 and ABCG2
Expression levels of ABC transporters in each of the 5 cell lines were analyzed using RT-qPCR, whereby expression was determined as a function of PCR cycles as follows: i) Very strong expression ≥0.2; ii) strong expression=0.1–0.19; iii) intermediate expression=0.05–0.09; and iv) weak expression ≤0.04. As shown in Fig. 2, ABCB1 was detected at weak levels in every cell line except SCC-68, where expression was not detected. In addition, a very strong expression level of ABCC1 was observed in PCI-13 cells, strong expression levels in PCI-1 and PCI-9 cells and intermediate expression levels in PCI-52 and SCC-68 cells. ABCG2 was also detected in each cell line. Although PCI-52 cells exhibited intermediate expression levels of ABCG2, weak expression was detected in all other cell lines.
Efficacy of cisplatin
Treatment with cisplatin for 72 h exhibited concentration-dependent effects in all cell lines. The control number for each cell line was set to 100%. Applied in a log3 dilution, cisplatin caused a reduction in cell viability to 9.6±1% at a concentration of 44 µM in PCI-1 cells, which resulted in an IC50 value of 0.3 µM. Similar results were observed for PCI-13 and SCC-68 cells, with viable fractions of 9.2±0.9 and 12.5±1.1%, respectively, and IC50 values of 1.1 and 11.9 µM. By contrast, PCI-9 and PCI-52 cells showed a maximum reduction in the viable fraction to 38.3±2.3 and 31±6.8%, respectively, and the inhibitory concentrations showed a similar range at 11.1 and 4.6 µM. These results are shown in Fig. 3, and the IC50 values are listed in Table IV.
Efficacy of pazopanib in combination with cisplatin
As shown in Fig. 4, the combination of pazopanib in a log2 dilution, and cisplatin with the individual IC50 concentration (displayed in Table IV) revealed concentration-dependent effects in all cell lines. In PCI-1 cells, only a small response to combination therapy was detected, which was similar to that revealed for pazopanib mono-therapy. The maximum effect was observed at the highest concentration used, which reduced the viable cell fraction to 46.6±15.1% compared with mono-therapy (51.3±3.9%). The calculated IC50 concentrations for mono- and combination therapy were 11.22 and 10.47 µM, respectively, and no significant differences were observed. Similar results were obtained for SCC-68 cells. In mono- and combination therapy, SCC-68 cells revealed only a minimal response to TKIs. No distinct differences in the reduction in cell count were illustrated between Pazopanib treatment alone (62.5±4.3%) and that with combination therapy (64.4±21.9%). Additionally, the respective IC50 value of 10.2 µM did not change significantly. By contrast, differences between mono- and combination therapy were detected in PCI-13 and PCI-52 cells; each cell line exhibited similar reductions in viability following mono- and combination therapy (to 57.9±4.2 and 56.7±12.2%, compared with 84.9±4.4% and 94.4±19.6% for mono- and combined therapy, respectively), and the calculated IC50 values were distinctly different (9.33 and 34.67 µM, compared with 20.42 and 26.3 µM, for mono- and combined therapy, respectively). PCI-9 appeared to be the only cell line that was notably sensitive to combination therapy, with a strong maximum effect in cell count reduction (to 76.9±7.5 and 50.8±12.9%) and a distinctly lower IC50 value (64.57 and 24.55 µM for mono- and combined therapy, respectively). The calculated IC50 values are listed in Table V.
 | Table V.Half inhibitory concentrations of pazopanib, dovitinib and nintedanib in mono- and combination therapy with cisplatin. |
In summary, 2 of the 5 cell lines (PCI-1 and SCC-68) showed no distinct differences in the response to mono- and combination therapy with regard to the reduction in maximum cell count and IC50 concentrations. The other 2 cell lines (PCI-13, PCI-52) exhibited inhibitory effects in response to combination therapy, whereas synergistic effects were only detected in PCI-9 cells.
Efficacy of dovitinib in combination with cisplatin
The combination of dovitinib in a log2 dilution, and cisplatin with its predetermined individual IC50 concentration (Table IV) also exerted concentration-dependent effects in each cell line (Fig. 5). In contrast to pazopanib, distinct differences between mono- and the combination therapy were not detected in any of the cell lines; furthermore, no distinct differences were demonstrated with regard to the IC50 concentrations between the 2 therapy types. In PCI-1 cells, counts were reduced to 19.5±3.4% with mono-therapy, and 6.8±1.8% with combination therapy, and only a small difference was detected when comparing the IC50 values (14.13 and 19.95 µM, respectively). Moreover, minimal differences in inhibitory effects were observed in PCI-13 cells between mono- and combination therapy, with a maximum effect in the range of 7.6 to 10.1%. PCI-52 cells showed similar results, with mono-therapy causing a maximum reduction of the viable fraction to 24.5±5.8%, and an IC50 concentration of 14.2 µM, which was not significantly different from that observed following combination therapy. Furthermore, the findings of PCI-9 cells were similar, whereby the maximum reduction of the viable fraction differed marginally between mono- and combination therapy (to 35.9±12.2 and 27.1±3.9%). The IC50 values are listed in Table V.
In all of the examined cell lines combination therapy did not exhibit additive or synergistic effects compared with mono treatment.
Efficacy of nintedanib in combination with cisplatin
As shown in Fig. 6, concentration-dependent effects were obtained using nintedanib alone, or in combination with cisplatin. In contrast to pazopanib and dovitinib, markedly synergistic effects were revealed when comparing the effects of mono- and combination therapy, though the effects of mono-therapy and combination therapy did not differ significantly in PCI-1 and PCI-9 cells. In PCI-1 cells, the curve for mono- and combination therapy, and the respective IC50 concentrations (5.37 and 4.68 µM) were distinctly different. Similar results were demonstrated in PCI-9 cells. Although the viable fraction of cells following mono- and combination differed significantly (32.6±3.9 and 5.9±7.6%), the IC50 values (5.5 and 5.4 µM) did not differ remarkably. In PCI-13 cells, the maximum reduction of the viable fraction (to 18.4±1.6 and 12.5±2.5%) was nearly the same between mono- and combination therapy, respectively, with the calculated IC50 concentrations (5.37 and 5.5 µM). In the PCI-52 cell line, maximum cell reduction ranged from 10.5±9.1 to 12.8±0.7%, and combination therapy IC50 values revealed synergistic effects (17.38 and 8.51 µM). With a maximum cell count reduction to 4.2±1.9% and corresponding IC50 values of 29.51 and 5.13 µM (mono- and combination therapy, respectively), this effect was more distinct in SCC-68 cells.
In summary, by comparing maximum cell count reductions and respective IC50 concentrations, combination therapy exhibited synergistic effects in four of the five cell lines tested (PCI-1, PCI-13, PCI-52 and SCC-68). One cell line (PCI-9) did not exhibit distinct differences in viability between mono- and combination therapy.
Correlation between ABC transporter expression levels and TKI response
Correlation analysis between ABC transporter expression levels and TKI response was based on the lowest concentrations of the TKI that induced significant cell count reduction (pazopanib: 1.25 µM, dovitinib: 6.25 µM, nintedanib: 6.25 µM) and the expression levels of ABCB1, ABCC1 and ABCG2. Pearson's correlation (r) and significance (P) are shown in Table VI. A significant correlation (P=0.0138) was observed between the nintedanib response and ABCB1 expression level. The other ABC transporters were not significantly influenced by TKI response in the cell lines tested (Fig. 7).
| Table VI.Correlation analysis between tyrosine kinase inhibitor (pazopanib, dovitinib and nintedanib) responses and ABC transporter expression levels. |
Expression of receptor tyrosine kinases
As previously described, the expression levels of the respective receptor tyrosine kinases were analyzed using RT-qPCR for each of the 5 cell lines (22). Expression levels were determined as a function of PCR cycles, as follows: i) Very strong expression ≥0.1; ii) strong expression=0.01–0.09; iii) intermediate expression =0.001–0.009; and v) weak expression ≤0.0009. Low and intermediate expression levels of vascular endothelial growth factor receptor (VEGFR) 1 and 3 were exhibited in all of the cell lines, whereas VEGFR2 was only detected in low expression levels in SCC-68 cells. FGFR2 was expressed at high levels in four of the five cell lines (PCI-1, PCI-9, PCI-13, PCI-52 and SCC-68), and FGFR1 was expressed at high levels in PCI-52 and SCC-68 cells. Intermediate and low levels of FGFR3 and FGFR4 were expressed in all five cell lines. Platelet-derived growth factor receptor (PDGFR) α and β were only weakly expressed in the five cell lines. Intermediate expression levels of colony stimulating factor 1 receptor were observed in PCI-1, PCI-13 and SCC-68. Stem cell growth factor receptor exhibited strong expression levels in PCI-52 and SCC-68 cells, whereas fms-like tyrosine kinase 3 was detected at intermediate expression levels in SCC-68 cells (Fig. 8).
Discussion
The results of the present study demonstrated that multi-kinase inhibitors may enhance the efficacy of cisplatin treatment in HNSCC cell lines. This finding highlights an important role for these drugs in addition to their impact on angiogenesis and metastasis.
HNSCC is the sixth most common cancer worldwide, with an increasing incidence. Despite improvements in diagnostics, treatment and follow-up, the 5-year survival rate of 55–60% has not changed in the last few decades (1,2). As the majority of patients present at an advanced tumor stage, multi-modal treatment, including surgery, radiation and chemotherapy is necessary. In particular, recurrence, locoregional and distant metastasis, and inoperable tumors represent a clinical problem that underscores the importance of chemotherapeutic strategy in this subset of patients (1,2). To date, platinum-based chemotherapy has been used to treat 70% of HNSCC cases in the USA (3), and cisplatin exerts its anti-cancer effects by inducing DNA cross-linking, DNA damage and apoptosis (23). Nonetheless, cisplatin is associated with severe side effects, including ototoxicity, neurotoxicity and myelosuppression (23,24). In addition to these side effects, heterogeneous tumor responses result in poor survival rates, which is partly attributable to neoangiogenesis. Additionally, VEGFR and FGFR signaling is altered in the majority of patients with HNSCC, resulting in tumor growth or neoangiogenesis; this influences the poor prognosis of patients due to associations with nodal metastasis and locoregional recurrence following treatment (25,26). As angiogenesis serves a critical role in tumor growth, inhibition of this process alone is insufficient (27) and other VEGFR-targeted therapies, including bevacizumab, do not have the desired effect. Overall, combination therapy with multi-targeted TKIs and cisplatin may have notable impact on HNSCC therapy.
ABC transporters appear to influence the prognosis of patients with HNSCC (7,8) and ABCB1, ABCC1 and ABCG2 are the most frequently described transporters in MDR (28–30). To date, literature has revealed contradicting data regarding ABC expression levels in patients with HNSCC (31–33); in the present study, TCGA analysis revealed that genetic alterations in ABCB1 occur in 30% of HNSCC cases, resulting in a significant decrease in overall survival (P=0.0197) (18,19).
Because TKIs have the potential to influence ABC transporter expression and function, combination therapy with cisplatin is a reasonable choice. Different MDR ABC transporter mRNA levels in cell lines may provide evidence for variable responses to TKI treatment. For example, in the present study, additive effects as a result of combination treatment were observed, with nintedanib showing the most striking additive effects in 4 of the 5 cell lines tested. Correlation analysis for TKI and ABC transporter expression shows a significant association (P=0.0138) between the nintedanib response and ABCB1 expression levels. However, it is difficult to draw conclusions about the superiority of nintedanib in combination treatment based on tyrosine kinase receptor expression levels. Nonetheless, there is clear evidence of a possible interaction between TKI and ABC transporters, as the respective TKIs specifically influence the expression level and activity of efflux pumps. It has been reported that nintedanib may inhibit ABCB1/ABCG2 mRNA expression and the ATPase activity of these transporters (34). Weiss et al (35) reported that dovitinib is only a weak inhibitor of ABCB1 protein function, but that it induces ABCG2 at low concentrations. By contrast, pazopanib exhibits little interaction with ABCB1 (36) but is a substrate to both ABCB1 and ABCG2 (37,38). There appear to be no data regarding the interaction of ABCC1 and the TKIs investigated.
In a clinical setting, combination therapy with TKIs causes distinct side effects. Reports from Galsky et al (39) revealed poor tolerance to dovitinib in combination with gemcitabine and cisplatin, or gemcitabine and carboplatin in patients with advanced solid tumors due to myelosuppression. Despite the severe side effects associated with multi-targeted TKIs (even in mono-therapy), their effects on neoangiogenesis and metastasis cannot be dismissed.
In conclusion, combination therapy with TKIs and cisplatin appears to be a reasonable approach for HNSCC treatment. Nevertheless, the results require further critical consideration; in the present study, the cells were treated outside of their normal surroundings, without interactions with the TME. Further investigation is required to determine the true efficacy of combination treatments for HNSCC.
Acknowledgements
Not applicable.
Funding
The present study was supported by the Comprehensive Cancer Center Mainfranken (R. Brands) and the Interdisciplinary Center for Clinical Research (S. Hartmann).
Availability of data and materials
The datasets used and/or analyzed during the present study are available from the corresponding author on reasonable request. Additionally, data are available at cbioportal.org, as previously described.
Authors' contributions
RCB performed the experiments, analyzed data and wrote the manuscript. FDD, MLK and VS performed cell culture experiments. SH, AK and UMR analyzed data and wrote the manuscript. AS performed cell culture experiments and analyzed the data. All authors read and approved the final version of the manuscript.
Ethics approval and consent to participate
Not applicable.
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
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