Background
Malignant pleural mesothelioma (MPM) arises from exposure to asbestos fibers with a long latency period, which has been a global health problem for the past few decades. Its anticipated peak incidence is yet to be reached. Mortality and morbidity of MPM remain extremely high, as its treatment is rarely curative. Surgery alone or in combination with radiotherapy and chemotherapy [
1] remains the standard treatment for early-stage disease. Combination chemotherapy for advanced disease carries only modest survival benefit [
2]. Proven effective treatment options are very limited, especially for patients with a poor response to previous chemotherapy.
Amino acids are essential for different cellular functions including synthesis of protein and polyamines [
3]. Intuitively, amino acid depletion may serve as an effective treatment for those cancers that are highly dependent on exogenous source of amino acids. Arginine is a semi-essential amino acid in selected tumors, but can be replenished intracellularly in normal cells. Therefore arginine-degrading enzymes (arginase and arginine deiminase (ADI)) have been tested in treating different cancers that are unable to synthesize arginine [
4,
5]. Overexpression of argininosuccinate synthetase (ASS1) and ornithine transcarbamylase (OTC) is one of the resistance mechanisms in arginase treatment.
BCT-100 is a pegylated arginase (US FDA IND granted in March 2012) (Bio-Cancer Treatment International Limited, Hong Kong), which has been tested in a phase I/II clinical trial for treatment of hepatocellular carcinoma (HCC) with encouraging results [
6]. In vitro, BCT-100 has shown anti-tumor effects in HCC [
4,
7] and acute myeloid leukemia (AML) [
8] with IC
50 values at 100–250 mU/ml and 100–1250 μU/ml respectively. Arginase exerts antiproliferative effects in melanoma [
9] and HCC [
10] by inducing cell cycle arrest and apoptosis. Interestingly an early phase clinical trial of arginine depletion with pegylated ADI (ADI-PEG20) in MPM was reported in 2014 [
11]. Among those MPM with deficient ASS1 expression by immunohistochemistry, treatment with ADI-PEG20 achieved good metabolic response with significant improvement in progression-free survival (hazard ratio 0.53, 95% CI: 0.31 to 0.90,
p = 0.02) compared with best supportive care alone. However, potentially serious anaphylactoid reaction to ADI has been reported. Nonetheless, BCT-100 has been shown in early phase clinical trials to be very well tolerated without anaphylaxis. So far, the effect of BCT-100, with a different mechanism of arginine depletion from ADI, has not been investigated in MPM. We therefore embarked on this study to evaluate the anti-cancer effects of BCT-100 in MPM, which could provide a scientific basis for future clinical development of BCT-100 as a novel treatment for MPM.
Methods
Cell lines and reagents
A panel of 5 mesothelioma cell lines (NCI-H28 (sarcomatoid), MSTO-211H (biphasic), NCI-H226 (epithelioid), NCI-H2052 (sarcomatoid) and NCI-H2452 (epithelioid)) was purchased and authenticated (American Type Culture Collection, Manassas, VA, USA). Cells were incubated in RPMI-1640 medium (Gibco®, Life Technologies, Carlsbad, California, USA) enriched with 10% fetal bovine serum (FBS) (Gibco®) in a humidified atmosphere of 5% CO2 at 37 °C.
Pegylated arginase (BCT-100)
Pegylated arginase (BCT-100, PEG-BCT-100 or rhArg1peg5000) was provided by Bio-cancer Treatment International Limited.
Cell viability assay
Briefly, cells (5000/well) were incubated with different activity units of BCT-100 with/without cisplatin or pemetrexed. Cells incubated with medium only served as a negative control. Following incubation for 72 h, cells were fixed for 10 min with 4% formaldehyde (Sigma-Aldrich, St. Louis, Missouri, United States) in phosphate-buffered saline (PBS) and stained for 10 min with 0.05% crystal violet. The plates were washed for 4 times with tap water and then the cells were lysed with 1% sodium dodecyl sulfate (SDS) solution (Sigma-Aldrich). Absorbance (595 nm) was measured using a microplate reader Fluo Star Optima (Bmg Labtec GmbH, Ortenberg, Germany) [
12].
Tumor growth inhibition in vivo
The 211H and H226 xenograft models were created, while H28, H2052 and H2452 xenografts could not be developed successfully, by subcutaneous injection of 10
7 corresponding cells in PBS into the upper back of 18 nude mice (female, 4–6-week-old, 10–14 g, BALB/cAnN-nu, Charles River Laboratories, Wilmington, USA). Mice were randomized into 3 groups after tumor growth was established. PBS (served as control), BCT-100 (20 and 60 mg/kg twice a week), pemetrexed (Eli Lilly, Indianapolis, Indiana, USA) (150 mg/kg twice a week) and/or cisplatin (Cayman, Teaduspargi, Tallinn, Estonia) (2.5 mg/kg once/week) were administered intraperitoneally. Tumor dimension (using standard calipers) and body weight of mice were measured twice a week and tumor volume was calculated [volume = length x width x width)/2] [
13]. For humane reasons, mice were sacrificed when tumor volume reached 600 mm
3. Tumor xenografts were collected. The study protocol was approved by the institutional Animal Ethics Committee (approval reference number: CULATR 3463-14), and standard humane endpoints for animal research were applied.
Study of protein expression with Western blot, immunohistochemistry and immunofluorescence staining
Western blot was performed as previously described [
12]. Specific primary antibodies [mouse monoclonal anti-human β-actin (Sigma-Aldrich), anti-ASS1, anti-OTC, anti-PARP, (Santa Cruz Biotechnology, Inc., Santa Cruz, California, USA), anti-Bcl-2, anti-cleaved caspase-3, anti-cyclin A2, D3, E1, H, anti-CDK4 (Cell Signaling Technology, Danvers, Massachusetts, USA), anti-Ki67 (ImmunoWay Biotechnology Company, Texas, USA), anti-PEG (RevMAb, San Francisco, USA) antibodies] and corresponding horseradish peroxidase (HRP)-conjugated secondary (Cell Signaling Technology) were purchased. An enhanced chemiluminescence (ECL) kit (GE Healthcare) was used to detect protein expression. Beta-actin was selected as reference protein [
14].
Immunohistochemistry and immunofluorescence staining were carried out according to standard protocol. Anti-cytokeratin 1 (Santa Cruz Biotechnology), anti-PEG and corresponding Alexa Fluor anti-mouse or anti-rabbit (Life Technology) antibody were used. The slides were mounted with Prolong® Gold antifade reagent with 4′,6-diamidino-2-phenylindole (DAPI, Life Technologies). Photos were taken with Nikon Ni-U fluorescence microscope (Nikon, Tokyo, Japan) equipped with camera/detector Diagnostic Instrument RT3 Slider (Meyer Instruments, Houston, USA).
Serum arginine concentration detection
L-arginine ELISA kit was purchased from Immundiagnostik (Bensheim, Hessen, Germany). The procedure was carried out according to manufacturer’s protocol. Briefly, derivatized control, standards and samples were incubated with L-arginine antibody overnight. Peroxidase conjugate was added after washing. Stop solution was then added to cease reaction after incubation with tetramethybenzidine substrate. Absorbance (450 nm) was measured with a reference (620 nm) using a microplate reader Fluo Star Optima.
Terminal Deoxynucleotidyl transferase-dUTP Nick End Labeling (TUNEL) Assay
TUNEL assay was performed according to standard protocol using Click-iT® Plus TUNEL Assay (Life Technologies). Formalin-fixed, paraffin embedded tumor xenograft sections were de-paraffinized, fixed and permeablized. Sections were first incubated with terminal deoxynucleotidyl transferase (TdT) reaction buffer, then TdT buffer containing EdUTP, TdT and TdT enzyme. Slides were stained with TUNEL reaction cocktail (TUNEL reaction buffer, copper protectant, Alexa Fluor® picoyl azide and TUNEL reaction buffer additive). The slides were mounted with Prolong® Gold antifade reagent with DAPI. Photos were taken with Nikon Ni-U fluorescence microscope.
Statistical analysis
Experiments were repeated at least 3 times and data analysed (mean ± standard deviation). The difference between groups was analysed using Student’s two-tailed t-test by Prism (GraphPad Software, La Jolla, Southern California, USA). A p-value < 0.05 defined statistical significance (*: p < 0.05, **: p < 0.01, ***: p < 0.001). Survival time of mice bearing tumor xenografts was defined as the time lapse between the start of treatment and time point when humane endpoints were reached. The difference of median survival between treatment arms was analysed using log-rank test by Prism.
Discussion
BCT-100 showed antiproliferative effects in MPM as demonstrated by crystal violet cell viability assay in our cell line model. In 211H and H226 xenograft models, BCT-100 (60 mg/kg) suppressed tumor growth accompanied by prolonged median survival. Serum arginine concentration and intratumoral arginine content decreased significantly in BCT-100 treatment groups, associated with apoptosis and G1 arrest.
Amino acid depletion is a novel approach for cancer treatment. Asparagine and arginine are both essential amino acids in cancer cells, but not in normal human cells. ADI and BCT-100 were pre-clinically and clinically proven to inhibit arginine auxotrophic tumors with ADI targeting ASS1 deficient cancers and BCT-100 targeting ASS1 and/or OTC negative cancers. Furthermore, ADI-PEG20 has been shown to have interesting anti-cancer effect on ASS-deficient cancers including lymphoma, head and neck cancer, small cell lung cancer, pancreatic cancer and breast cancer through apoptosis and cell cycle arrest [
15].
Arginine depletion carries a systemic effect that may involve the tumor microenvironment. Therefore, we believe that the effect of BCT-100 would be better studied using xenograft models rather cell line models. Since the in vivo tumor suppressive effect of BCT-100 alone has been observed in our study, the combination of BCT-100 and current active chemotherapeutic agents (pemetrexed or cisplatin) in MPM was further investigated. In 211H xenograft model, the effect of BCT-100 was similar to pemetrexed or cisplatin. More importantly, BCT-100 showed a superior effect than pemetrexed in H226 xenograft. It has been shown that thymidylate synthase was highly expressed in H226 xenograft [
14] which can explain the relative pemetrexed resistance in H226 xenograft. Nonetheless, the combination of BCT-100 and pemetrexed did not reveal any additional benefit compared with single agents. As serious side effect (liver cirrhosis) was found with BCT-100/cisplatin combination in 211H xenograft model, this combination was not pursued further in our study.
The common side effects of cisplatin and pemetrexed combination chemotherapy include severe nausea and vomiting [
16], myelosuppression and neutropenia [
17]. With good tolerability of BCT-100 shown in early clinical trials [
6], BCT-100 may potentially serve as an alternative therapeutic agent, though not in combination with existing chemotherapy, in the clinical management of MPM. This is particularly true among patients with MPM that overexpress thymidylate synthase resulting in pemetrexed resistance.
MPM can be sub-divided into epithelioid, sarcomatoid and biphasic histological sub-types, with poorer survival among patients with sarcomatoid and biphasic mesothelioma [
18]. BCT-100 showed tumor suppressive effect in biphasic 211H and epithelioid H226 MPM xenograft models. However, no sarcomatoid mesothelioma xenograft model could be developed in this study for assessment of the efficacy of BCT-100.
BCT-100 effectively decreased serum arginine concentration to 24 and 14% that of control mice in both xenograft models even with low-dose (20 mg/kg) BCT-100 treatment, which could not completely explain the dose-dependent tumor suppression. On the other hand, the dose-dependent arginine depletion was better demonstrated within the intratumoral compartment, which should be more relevant to the activity of BCT-100 on the tumor xenografts. This is in line with the finding of increased intratumoral BCT-100 level with higher dose of BCT-100 treatment, suggesting intratumoral on top of systemic arginine depletion. The intratumoral localization of BCT-100 in MPM xenografts was mainly cytosolic, which is similar to previous finding [
19].
Apoptotic cells were increased after incubating melanoma A375 cells with BCT-100 using annexin-V binding assay [
9]. Caspase-dependent cellular apoptosis was activated by BCT-100 in human hepatoma HepG2 and PLC/PRF/5 cells [
4]. Nonetheless, the in vivo evidence of apoptosis has not yet been shown previously. In our study, apoptosis was induced by BCT-100 in mesothelioma xenograft models as evidenced by alteration of key apoptosis-related factors and TUNEL positive-staining in BCT-100 treatment arms in both xenografts.
It has been shown that BCT-100 could induce G2/M arrest in HCC Hep3B cells, S arrest in HCC HepG2 and PLC/PRF/5 cells [
10], and G2/M arrest in melanoma A375 cells [
9]. On the other hand, G0/G1 arrest was observed with BCT-100 treatment in acute myeloid leukemia cells [
19]. BCT-100-induced G1 arrest was evidenced by altered expression of relevant cell cycle regulators in our in vivo mesothelioma study, suggesting that the exact point of cell cycle arrest could be cell line- or tumor-specific. Ki67 is a functional antigen found in the nucleus that serves as a proliferative marker controlling all phases of the cell cycle [
20]. Downregulation of Ki67 by BCT-100 in both MPM xenografts is consistent with suppression of G1 arrest-related factors.
BCT-100 reduced relative cell viability in Hep3B (hepatoma), A375 (melanoma), 211H (mesothelioma) and H226 (mesothelioma) cells with IC
50 values of 100, 86, 13 and 20 mU/ml respectively [
4,
9]. The effective dose of BCT-100 used was about 27000 U/kg/week in both melanoma and HCC xenograft models [
4,
9] while only about 3000 U/kg/week was administered in MPM xenograft models in our study. The correlation between in vitro and in vivo efficacy of BCT-100 seems to be quite consistent among different tumor types. Furthermore, the dosage of BCT-100 given in a clinical trial for treatment of advanced HCC was 1600 U/kg/week [
6], which was equivalent to about 20000 U/kg/week in mice models [
21]. The effective dose of BCT-100 used in this study was only 3000 U/kg/week which was much lower than that the equivalent dose used in the clinical trial. The dose of BCT-100 used was likely cancer-specific which was possibly due to different types of cancer cells having different arginine and metabolic requirements [
6]. Our finding of the relatively greater sensitivity of MPM than HCC or melanoma to BCT-100 holds promise for future clinical development of BCT-100 in the treatment of MPM. Ideally, the efficacy of BCT-100 in MPM can be better evaluated in primary cultures that provide closer mimicry of tumor microenvironment. However, MPM is a rare disease in Hong Kong with only about 20 new cases per year, which precludes any feasibility of experiments using primary cultures derived from patients’ tumor samples.
Recently, an early-phase clinical trial was conducted using pegylated arginase (BCT-100) at 1600 U/kg/week in the treatment of advanced HCC [
6]. A significantly improved progression-free survival was observed in patients with adequate arginine depletion (ADD) (<8 μM serum arginine concentration) for more than 2 months compared with those with ADD for less than 2 months (6.4 vs 1.7 months, 95% CI: 1.67–1.73,
p = 0.01). Overall survival was also improved with BCT-100 treatment compared with untreated HCC patients (6.4 vs <2–3 months [
22]). Adverse events were mostly mild (pain, insomnia, loss of appetite, constipation, fatigue, vomiting and nausea) with BCT-100 treatment [
6]. Further clinical development of BCT-100 in treatment of unresectable HCC is currently underway.
Acknowledgements
Not applicable.