Background
1-(3-
C-Ethynyl-s-D-
ribo-pentofuranosyl)cytosine (3'-ethynylcytidine, ECyd, TAS-106) (Additional file
1: Figure S1A) is an antitumor cytidine analogue possessing potent cytotoxic and antitumor activities in preclinical therapeutic models via the inhibition of RNA biosynthesis through the competitive inhibition of RNA polymerase I, II and III. When administered, ECyd is initially phosphorylated by uridine-cytidine kinase (UCK) 1 or 2, generating 3'-ethynylcytidine-5'-monophosphate (ECMP). ECMP then undergoes two additional phosphorylations, generating 3'-ethynylcytidine-5'-diphosphate (ECDP) and 3'-ethynylcytidine-5'-triphosphate (ECTP), respectively [
1]. ECTP is the final active moiety that inhibits RNA polymerases and exerts the anti-tumor effect (Additional file
1: Figure S1B). Among the three phosphorylation steps, UCKs that mediate the initial phosphorylation are the rate limiting enzymes [
2]. In particular, UCK2 is preferentially expressed in cancer cells [
3], while UCK1 expression is observed in both cancer and normal cells, explaining the greater anti-tumor effect on cancer cells while sparing normal cells [
4‐
6]. Furthermore, ECyd is a more efficient substrate for UCK2 than for UCK1. In addition, the expression level of not UCK1 but UCK2 is closely correlated with cellular sensitivity to ECyd [
6].
Previously, we reported that the combination of ECyd and CDDP showed potent anti-proliferative effects in several
in vitro cancer cell lines and an
in vivo xenograft tumor model [
7]. Given the remarkable synergistic effect of ECyd and CDDP, we have initiated a Phase I clinical trial combining ECyd and platinum for patients with solid tumors. This novel combination therapy might provide great benefit for patients whose tumor has an intrinsic resistance to CDDP or an acquired resistance after CDDP treatment.
Head and neck (H&N) cancer is the sixth most common cancer worldwide, and around 90% of cases have an epithelial origin that presents as squamous cell carcinoma (SCCHN). Therefore, this histopathological subtype forms the main focus of H&N cancer treatment [
8]. CDDP is one of the most effective antitumor agents for the treatment of patients with SCCHN. However, acquired resistance to CDDP is a major obstacle to effective, potentially curative chemotherapy in the clinical management of such patients. Even with new second-line options, including Erbitux, a great need remains for alternatives that can deliver improved survival rates in metastatic disease settings. Effective new agents with different targets and/or mechanisms of action are highly needed as either first- or second-line treatments, in combination with standard chemotherapy or as a monotherapy, especially for metastatic SCCHN [
9].
The molecular mechanisms underlying the resistance to CDDP remain unknown in human SCCHN cancers [
10]. Several mechanisms found in many drug-resistant cancer cells include a reduction of drug uptake, an increase in drug export, an increase in intracellular detoxification, an increase in DNA repair systems, and so on. With respect to CDDP drug resistance, multidrug resistance-associated protein 2 (MRP2) might be correlated with CDDP resistance [
11]. However, in general, multiple reports have shown that CDDP is not a substrate for P-glycoprotein, the product of the multidrug resistance gene MDR, and other members of the ATP-binding cassette superfamily of transporters (ABC transporters). Thus, more detailed studies are required to decipher the mechanism of CDDP drug resistance.
Recently, Vault complex (Vaults) was reported to be associated with CDDP resistance through the elimination of platinum chemotherapeutics from cancer cells [
12‐
16]. Vaults are barrel-shaped cytoplasmic ribonucleoprotein particles composed of multiple copies of three different proteins and a small RNA [
17]. The mammalian Vaults are composed of major vault protein (MVP), vault poly ADP-ribose polymerase (VPARP) and telomerase-associated protein 1 (TEP-1), which are complexed with small untranslated vault RNAs (vRNAs) [
18‐
20]. Among the four components, the major component of Vaults is MVP, which constitutes more than 70% of the total mass. Vaults were initially identified as clathrin-coated vesicles, and the first evidence that these structures may contribute to drug resistance was provided when lung resistance-related protein (LRP) was highly expressed in non-P-glycoprotein-mediated drug-resistant cell lines [
21]. Subsequent studies showed that LRP is identical to human MVP [
22]. Although Vaults are expressed in all human tissues, elevated levels of MVP are found in the gut epithelium, lung epithelium, macrophages, and dendritic cells, which are all typically exposed to xenobiotics [
23‐
26]. These findings imply that Vaults have a role in the defense of such tissues against toxic insults. Consistent with this hypothesis, MVP has been found to be overexpressed in various multidrug-resistant cancer cell lines, together with a range of clinical samples such as H&N, ovarian, lung carcinomas, hepatoblastoma, acute myeloid leukemia, and multiple myeloma [
12,
23,
26]. An accumulating number of experimental and clinical investigations have suggested that an elevated expression at the time of diagnosis was an independent prognostic factor for a poor response to chemotherapy and an adverse clinical outcome for a variety of tumor types [
16,
27‐
29]. Because the hollow barrel-shaped structure of the Vaults complex and its subcellular localization have indicated that Vaults are involved in xenobiotic transportation, it was postulated that Vaults contribute to drug resistance by transporting drugs away from their intracellular targets and/or the sequestration of drugs [
30,
31]. Although the decisive function of the vRNAs component is not clear, the vRNAs reportedly has the ability to bind chemotherapeutics, suggesting a pivotal role in drug export.
Here, we investigated the antitumor activity of ECyd combined with CDDP in platinum-resistant SCCHN cancer cells named KB/CDDP(T); we found that ECyd suppresses the expression of vRNAs and the CDDP-mediated induction of Vaults, restoring sensitivity to CDDP.
Methods
Cells and reagents
KB cells, a human nasopharyngeal carcinoma cell line, and A549 cells, a human lung carcinoma cell line, were obtained from the American Type Culture Collection. CDDP-resistant KB cells, KB/CDDP(T), were established by stepwise dose escalation with CDDP in our laboratory. ECyd was synthesized at Taiho Pharmaceutical Co., Ltd. (Tokyo, Japan). CDDP and CBDCA were obtained from Nippon Kayaku Co., Ltd. (Tokyo, Japan), SN-38 was obtained from Sigma-Aldrich Co., LLC. (Missouri, USA), and ADM was obtained from Kyowa Hakkou Kirin Co., Ltd. (Tokyo, Japan).
Cell culture and cell survival analysis
KB and KB/CDDP(T) cells were grown in Eagle's Minimum Essential medium containing 10% fetal bovine serum, and A549 cells were grown in F-12 K Medium containing 10% fetal bovine serum. SHIN-3 and HRA cells were grown in RPMI-1640 Medium containing 10% fetal bovine serum. The cells were incubated in a humidified atmosphere of 5% CO
2 at 37°C. A total of 1×10
3 cells in 100 μL of culture medium were inoculated into each well of a 96-well plate. After 24 hours of incubation at 37°C, 100 μL of anticancer drugs diluted with the medium to various concentrations were added to each well and the cultures were incubated for 72 hours at 37°C in 5% CO
2. Cell viability was quantified using a colormetric assay using a Cell Counting Kit-8 (Dojindo, Kumamoto, Japan) [
32].
Drug interaction analysis
A total of 5 x 10
2 cells in 100 μL of culture medium were inoculated into each well of a 96-well plate. After 24 hours of incubation at 37°C, 50 μL each of ECyd and CDDP diluted with the medium to various concentrations were added to each well; the cultures were then incubated for 24 hours at 37°C in 5% CO
2, followed by washing each well twice with drug-free medium and 96 hours of incubation with drug-free medium. The cell viability was quantified using a colormetric assay using a Cell Counting Kit-8 (Dojindo) [
32]. The presence of an additive or synergistic interaction between CDDP and ECyd was determined using the isobologram analysis reported by Steel and Peckham [
33]. The type of interaction between CDDP and ECyd was evaluated by comparing the cytotoxic effects obtained after simultaneous exposures to the drugs with the effects observed after exposure to CDDP or ECyd alone. The interaction indices were calculated using the following equation: interaction index = CDDP c/CDDP e + ECyd c/ECyd e, where CDDP e and ECyd e are the concentrations of CDDP and ECyd that inhibit 50% of the proliferation when used alone, and CDDP c and ECyd c are the concentrations of CDDP and ECyd that produce the same effect when used in combination. According to this method, an interaction index of less than 1.0 indicates a synergistic interaction between two drugs, an interaction index of more than 1.0 indicates antagonism, and an index of 1.0 indicates an additive interaction. The data point in the isobologram corresponds to the actual IC
50 dose of the combined CDDP and ECyd treatment. If a data point is on or within the three lines, this represents an additive treatment effect, whereas a data point that lies below or above the three lines indicates synergism or antagonism, respectively.
Preparation of total cell lysates and immunoblot analysis
Whole cell lysates were extracted with the M-PER Mammalian Protein Extract (Pierce, Oregon, USA) containing protease inhibitors. The protein concentrations were determined using a bicinchoninic acid protein assay, and equal amounts of protein were separated using a 7.5% SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and were electroblotted onto polyvinylidene difluoride membranes (Millipore, Massachusetts, USA). After blocking, the membranes were probed with primary antibodies against UCK2, MVP (Novus biologicals, Colorado, USA) and β-actin (abcam, Cambridge, UK). After incubation with horseradish peroxidase-conjugated secondary antibodies, the antigen-antibody complexes were visualized using enhanced chemiluminescence (Pierce). Images were captured using an image analyzer (LAS 3000; Fuji Film, Tokyo, Japan).
Immunocytochemistry
Cells plated on chamber slides were fixed with ice-cold 100% methanol, quenched with 0.3% H2O2, and blocked with normal goat serum. After incubation for 30 min with the primary antibodies, anti-MVP, and washing, the biotinylated secondary antibodies were added for 30 min, washed, then followed by preformed avidin DH-biotinylated horseradish peroxidase H complex for 30 min. Slides were then overlaid with DAB, rinsed, dried, mounted, and cover-slipped.
Stealth RNA-mediated interference (RNAi; Invitrogen, California, USA) for MVP or stealth RNAi negative control (Invitrogen) was transfected using Lipofectamine RNAiMAX (Invitrogen) according to the manufacturer’s protocol.
RNA isolation and quantitative real-time reverse-transcription PCR quantification
RNAs were extracted using the RNeasy Mini kit (Qiagen, Venlo, Netherlands). First-strand cDNAs were synthesized using the Quantitect Reverse Transcription kit (Qiagen). Gene expression levels were determined using either the TaqMan Gene Expression Master Mix or the SYBR Green PCR Master Mix on an ABI Prism 7900 platform (Applied Biosystems, California, USA), according to the manufacturer’s protocol. 18S rRNA was used for normalization. The relative quantification of the MVP mRNA and vRNAs was calculated using a comparative cycle threshold method [
34].
In vivostudy
Tumor fragments approximately 2 mm3 in size were transplanted subcutaneously into male BALB/cAJcl-nu nude mice (CLEA Japan, Tokyo, Japan). After reaching a tumor volume of ~150 mm3, the mice were randomly assigned to a control group and drug treatment, each consisting of six animals (day 0). CDDP (7 mg/kg) was administered by intravenous injection and ECyd (0.1 mg/kg/hr) was continuously administered using osmotic pumps (Alzet, California, USA) to six mice on day 1. Tumors were excised at 6 hours post-administration. The animal experiments were performed according to the guidelines and with the approval of the Institutional Animal Care and Use Committee of Taiho Pharmaceutical Co., Ltd. The permitted experimental number is 09TC11.
Discussion
Although we have previously shown that ECyd enhanced the anti-tumor effect of CDDP [
7], the mechanism underlying the sensitization was not clear. This study initially revealed that the enhancement was due to a suppressive effect of ECyd on the Vaults complex that is up-regulated by platinum. We carefully analyzed CDDP-resistant and parental-paired KB cells and identified three supportive observations demonstrating that Vaults is the causative molecule for CDDP resistance in KB/CDDP(T) cells, although several mechanisms of platinum-based drug resistance have been reported [
10‐
16]. First, CDDP treatment induced MVP protein in a dose-dependent manner, which was also observed by CBDCA treatment. Second, MVP-silencing using RNA interference restored the sensitivity to CDDP. Third, the established CDDP-resistant cell line, KB/CDDP(T), expressed a higher MVP expression level at baseline than its parental cell line. Other studies also reported that MVP knock-down and treatment with anti-MVP antibody restored cellular apoptosis in response to CDDP exposure and increased intra-cellular CDDP accumulation [
14], supporting our finding that the up-regulation of MVP is the major mechanism of platinum resistance in KB/CDDP(T) cells.
The present study examined the molecular mechanism underlying the sensitizing effect of ECyd in platinum-resistant cells. Although we previously found that ECyd enhances the anti-tumor effect of CDDP in both
in vitro and
in vivo models [
7], the molecular mechanism explaining this phenomenon remained to be clarified. The strong synergistic effect of the combination of CDDP and ECyd in KB/CDDP(T) cells suggested an antagonistic effect of ECyd on Vaults up-regulation in response to CDDP, resulting in the efflux of CDDP. ECyd seems to exert its suppressive effect on Vaults in two ways, since ECyd is an inhibitor of RNA polymerase I, II, and III [
37]. One mechanism is to suppress the expression of vRNAs via the inhibition of RNA polymerase III [
38], and the other is to suppress the MVP protein through the inhibition of RNA polymerase II. Especially, the finding that ECyd reduced the expression of vRNAs, followed by the dysfunction of Vaults, in CDDP-resistant cells is critical, since it would allow CDDP to exert an anti-tumor effect restricted by Vaults within 24 hours. Although ECyd alone exhibits an anti-proliferative property in cancer cells, the observation that the 24 hours ECyd/CDDP combination exerts a synergistic effect strongly supports the idea that the distorted function of Vaults contributes to the restoration of sensitivity to CDDP, in contrast to the additive effect of this combination in the parental KB cells. As ECyd significantly sensitized the KB/CDDP(T) cells to CDDP in a simultaneous 24 hours combined exposure study, the molecular mechanisms underlying the ECyd-induced enhancement should exert within 24 hours. Unexpectedly 24 hours exposure of ECyd, CDDP and its combination had no effect on MVP expression levels, however, we found that ECyd drastically decreased the expression of vRNAs, which reportedly have the ability to play a pivotal role in drug export, within 24 hours. Furthermore, the decreased expression levels of vRNAs were also demonstrated in nude mice xenograft tumor without induction of vRNAs in CDDP alone. Therefore, we thought of the Vaults dysfunction by the inhibition of vRNAs expression as the mechanism underlying the ECyd-induced enhancement of CDDP efficacy. In addition to Vaults dysfunction, our additional data also indicated that 72 hours exposure of ECyd decreased the induction of MVP expression. Osmotic stress is known to increase the level of MVP expression [
39], and we confirmed that a significant induction of MVP was observed by osmotic stress in KB/CDDP(T) cells (Additional file
1: Figure S5A and B). Similar to the case of the ECyd/CDDP study, ECyd suppressed the up-regulation of MVP protein expression by osmotic stress (Additional file
1: Figure S5C), inferring that the antagonistic effect of ECyd on MVP up-regulation is a general observation, rather than being specific to platinum-mediated up-regulation. Although ECyd is an RNA polymerase inhibitor that is moderately effective even as a single agent in cancer cells, reversing the induction of Vaults, which renders resistance to CDDP, might become the mechanism responsible for the synergistic effect of the combined treatment in addition to Vaults dysfunction by inhibiting the vRNAs synthesis, especially in the long term chemotherapy which reportedly induces the expression of Vaults [
12,
23,
26].
Novel therapeutics to overcome CDDP resistance are needed for the treatment of various types of cancer, such as H&N cancer, small cell lung cancer and ovarian cancer [
10]. This study implied that ECyd and CDDP could be a reasonable combination therapy for improving the clinical benefit to cancer patients treated with platinum-based therapy. Since we have shown that a synergistic anti-tumor effect is observed in H&N cancer and ovarian cancer cells in the present study, similar to the effect in lung cancer cells that we observed in our previous report [
7], it would be interesting to further investigate the effect of this combination in other types of tumors for which the standard medical care is platinum-based therapy. Furthermore, the synergistic effect of ECyd/CDDP is expected to occur preferentially in tumor cells, compared with normal cells. ECyd is activated by UCK2 followed by the inhibition of RNA polymerase I, II and III, which finally leads to the suppression of cancer cell proliferation [
6]. Although RNA polymerases are widely expressed in various types of cells, UCK2 is reportedly expressed at a much higher level in tumor cells than in normal cells [
6]. This finding suggests that ECyd causes Vaults dysfunction preferentially in tumor cells, minimizing side effects in the normal cells of cancer patients treated with a combination of ECyd and platinum. Clinical trials to determine the maximum tolerated dose of the combination of ECyd and carboplatin was recently completed [
40]. Therefore, the clinical outcome of these Phase II trials is eagerly awaited.
In cancer research, the identification of biomarkers to predict the efficacies of therapies has attracted a great deal of attention, given the fact that the clinical benefit of chemotherapeutics is limited in a small portion of patients. We observed that a higher level of MVP expression diminished the anti-tumor effect of CDDP, and the reduction of this effect by ECyd significantly sensitized the resistant cells. In addition to the data indicating that ECyd restores sensitivity to CDDP, a biological mechanism explaining this sensitization has been revealed, in which MVP induction provides resistance to CDDP through the down-regulation of a drug transporter by ECyd. Therefore, the MVP protein level in cancer patients could be explored as a predictive biomarker for identifying patients who may benefit from the combination of ECyd and platinum in future clinical trials.
Competing interests
All six authors are employees of Taiho Pharmaceutical Co., Ltd.
Authors’ contributions
HF and TA performed experiments and analysis; HF, TA, KS, HT, SM and SO participated in the design of the study; HF, SM and SO drafted and revised the manuscript. All authors read and approved the final manuscript.