alpha-Tocopherol enhances tumour growth inhibition by cis-dichlorodiammine platinum (II)

Sarna, S.; Kumar, A.; Bhola, R.K.

doi:10.1590/S0100-879X2000000800009

Abstract

Present studies indicate that alpha-tocopherol enhances the efficacy of cisplatin as demonstrated by inoculation of Dalton's lymphoma cells incubated with either cisplatin (5 or 10 µg/ml) alone or cisplatin + alpha-tocopherol (25 or 50 µg/ml) into C3H/He mice. Tumour cells (3 x 10(6) cells/mouse) incubated with cisplatin grow slowly in syngeneic mice as indicated by the late appearance of tumour. However, mice failed to develop tumour when inoculated with tumour cells incubated with cisplatin + alpha-tocopherol. When the animals were challenged with tumour cells (3 x 10(6) cells/mouse) on the 15th day after the initial inoculation, 30-50% survived more than 60 days, with 10% tumour-free survivors being observed in some groups. Antitumour activity was higher in mice receiving lymphoma cells (3 x 10(6) cells/mouse) preincubated with cisplatin + alpha-tocopherol compared to cisplatin alone. Tumour-bearing mice receiving cisplatin in combination with different concentrations of alpha-tocopherol exhibited significantly higher (P<0.001) intratumour platinum content (123-306%) but without any change in the kidney platinum content as compared to those receiving cisplatin (5 or 10 µg/ml) alone. Enhancement of cisplatin-induced tumour growth inhibition is probably due to the modulation of tumour cell membrane permeability by alpha-tocopherol. alpha-Tocopherol might increase the influx of cisplatin into tumour cells, causing the DNA repair machinery to be less efficient due to increased efficiency of adduct formation in the DNA molecule. This effect of alpha-tocopherol can render cisplatin more effective as an antitumour agent.

cisplatin; vitamin E; Dalton's lymphoma; tumour growth inhibition

Braz J Med Biol Res, August 2000, Volume 33(8) 929-936

a-Tocopherol enhances tumour growth inhibition by cis-dichlorodiammine platinum (II)

S. Sarna, A. Kumar and R.K. Bhola

Department of Zoology, Gauhati University, Guwahati, India

References

Correspondence and Footnotes ^{Correspondence and Footnotes} Correspondence and Footnotes

Abstract

Present studies indicate that a-tocopherol enhances the efficacy of cisplatin as demonstrated by inoculation of Dalton's lymphoma cells incubated with either cisplatin (5 or 10 µg/ml) alone or cisplatin + a-tocopherol (25 or 50 µg/ml) into C3H/He mice. Tumour cells (3 x 10⁶cells/mouse) incubated with cisplatin grow slowly in syngeneic mice as indicated by the late appearance of tumour. However, mice failed to develop tumour when inoculated with tumour cells incubated with cisplatin + a-tocopherol. When the animals were challenged with tumour cells (3 x 10⁶cells/mouse) on the 15th day after the initial inoculation, 30-50% survived more than 60 days, with 10% tumour-free survivors being observed in some groups. Antitumour activity was higher in mice receiving lymphoma cells (3 x 10⁶cells/mouse) preincubated with cisplatin + a-tocopherol compared to cisplatin alone. Tumour-bearing mice receiving cisplatin in combination with different concentrations of a-tocopherol exhibited significantly higher (P<0.001) intratumour platinum content (123-306%) but without any change in the kidney platinum content as compared to those receiving cisplatin (5 or 10 µg/ml) alone. Enhancement of cisplatin-induced tumour growth inhibition is probably due to the modulation of tumour cell membrane permeability by a-tocopherol. a-Tocopherol might increase the influx of cisplatin into tumour cells, causing the DNA repair machinery to be less efficient due to increased efficiency of adduct formation in the DNA molecule. This effect of a-tocopherol can render cisplatin more effective as an antitumour agent.

Key words: cisplatin, vitamin E, Dalton's lymphoma, tumour growth inhibition

Introduction

Cisplatin has been used as an immunotherapeutic agent against tumours and has been reported to affect tumour cell antigenicity in vitro (1-4). Various cytotoxic agents have been used in combination with cisplatin to enhance its antitumour effect (5-10). Like other different combinations, thermochemotherapy with cisplatin or carboplatin has also been tried and both combinations were reported to be superior to treatment with hyperthermia alone (11). Preheating of cells also enhanced the cytotoxic effect of cisplatin administered shortly after heating (12). The cytotoxic effect of cisplatin combined with liposomal valinomycin on human ovarian tumour cells has been reported (13). Studies on the pharmacological effect of cisplatin combined with peplomycin have shown a strong block of the G₂M phase of the cell cycle resulting in the most effective killing of tumour cells (14). Clinical trials with this combination therapy have proved its usefulness for improving the clinical condition of the patients (14).

In addition to acting as an antitumour agent, a-tocopherol has been reported to be effective in the inhibition of spontaneous, X-ray and chemically induced transformation of tumour cells (15-17) and to induce morphological differentiation and growth inhibition of murine and human neuroblastoma cells in culture (18). a-Tocopherol has also been reported to induce apoptosis in erythroid leukemia and in prostate and breast cancer cells (19). An additive or synergistic effect of a-tocopherol with a few antitumour agents has been reported for murine neuroblastoma cells both in vitro (20) and in vivo (21). Similarly, some cytotoxic chemotherapeutic agents have also been used in combination with cisplatin in an attempt to achieve enhanced antitumour effects against cisplatin-resistant tumours (7,22). Some success has been achieved but many tumour types are poorly responsive to therapy with cisplatin alone or in combination with other chemotherapeutic agents (23). Hence a lymphoma was chosen to study the synergistic effect of cisplatin and a-tocopherol. In the present investigation, we studied the tumour growth pattern of Dalton's lymphoma cells in vivo after incubation in vitro with different combinations of cisplatin and a-tocopherol to determine whether a-tocopherol enhances the antitumour effect of a low dose of cisplatin.

Material and Methods

Male and female mice of the C3H/He strain aged 8-10 weeks and weighing 20-22 g were used in all experiments. Mice received a commercial feed (Goldmohar, Lipton, India) and water ad libitum. Animals were kept under standard conditions (in a pathogen-free environment at 22-23^oC, with 65-70% relative humidity.

Dalton's lymphoma was obtained from the Chittaranjan Cancer Research Center, Calcutta, India, and maintained in the laboratory by regular serial transplantations in inbred C3H/He mice after a regular interval of 12 days.

Cisplatin was a generous gift from Bristol Myers Co., Syracuse, NY, USA. Dulbecco's modified Eagle's medium (DMEM) and glutamine were purchased from Hi-Media, Mumbai, India. Fetal bovine serum (FBS), a-tocopherol, penicillin and streptomycin were purchased from Sigma Chemical Co., St. Louis, MO, USA. All other chemicals were purchased locally and were of analytical grade or equivalent.

Dalton's lymphoma cells were grown in DMEM supplemented with 10% FBS, 0.3% glutamine, 10 mM NaHCO₃, and 1% penicillin (50 units/ml)-streptomycin (50 µg/ml) on culture dishes in a humidified atmosphere of 5% CO₂ at 37 ± 1^oC. The pHwas maintained at 7.2-7.4 by regulating the flow of CO₂-air.

Asynchronized lymphoma cells were treated in vitro with cisplatin and a-tocopherol before being injected into different groups of mice. Tumour cells were brought to a concentration of 3 x 10⁶ cells/ml in DMEM containing 10% FBS, antibiotics and sodium bicarbonate. Tumour cell suspensions were incubated for 1 h at 37^oC with different concentrations of cisplatin alone, a-tocopherol alone, or a combination of both. The following groups were used: 1) control, 2) DMSO, 3) 25 µg/ml a-tocopherol, 4) 50 µg/ml a-tocopherol, 5) 5 µg/ml cisplatin, 6) 10 µg/ml cisplatin, 7) 5 µg/ml cisplatin + 25 µg/ml a-tocopherol, 8) 5 µg/ml cisplatin + 50 µg/ml a-tocopherol, 9) 10 µg/ml cisplatin + 25 µg/ml a-tocopherol, and 10) 10 µg/ml cisplatin + 50 µg/ml a-tocopherol. Viability of tumour cells was determined by the Trypan blue exclusion test. Tumour cell suspensions always exhibited more than 90% viability before incubation with any compound. Tumour cells incubated with different doses of cisplatin exhibited more than 80% viable cells, whereas in the case of a-tocopherol, viability was found to be 80-90%. After incubation, 3 x 10⁶ viable cells were injected ip into different groups of mice. Groups of mice in which the tumour did not appear were challenged with tumour cells (3 x 10⁶ cells/mouse) on day 15th after the initial inoculation. Increased survival time, percent survivors on different days and percent of tumour-free survivors were determined in control and experimental groups. Percent increase in the life span (%ILS) of the experimental groups was calculated using the following formula: %ILS = [(T - C)/C] x 100, where T = mean survival days of treated mice and C = mean survival days of untreated control mice.

For estimation of platinum content in tumour and kidney, freshly prepared cisplatin or cisplatin + a-tocopherol solutions were injected ip into tumour-bearing mice. After 24 h mice were sacrificed, lymphoma cells were collected, counted with an electronic cell counter and washed with DMEM twice. The kidneys were removed at the same time and washed with DMEM twice. Tissues were digested with hot nitric acid to remove most of the organic matter and diluted 10-fold in 1% HCl to keep the concentration of salts below 0.2%. Platinum content was estimated with the VG plasmasquad PQ1 ICPMS apparatus. The analytical procedure completely disrupted the platinum molecule and no information was obtained about the chemical form of platinum in tissues.

Each experimental and control group consisted of 10 mice. Each set of experiment was repeated thrice and the results are reported as arithmetic mean ± SD. Statistical significance was analyzed by the Student t-test.

The solvent (DMSO) failed to show any effect on tumour growth inhibition since the survival time of the control animals was not significantly different from that of animals inoculated with tumour cells treated with DMSO alone. All animals inoculated with Dalton's lymphoma cells incubated with different concentrations of a-tocopherol developed tumours. As compared to control, no significant difference in the mean survival time of mice was observed in the group inoculated with tumour cells incubated with 25 µg/ml a-tocopherol (Table 1). However, when the concentration of a-tocopherol was increased to 50 µg/ml, 10% of the animals exhibited an increase in mean survival time of 20 days. The %ILS with 25 and 50 µg/ml a-tocopherol was 7 and 17, respectively (Table 1).

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Mice receiving tumour cells incubated with cisplatin (5 or 10 µg/ml) exhibited a significant increase in mean survival time compared to control (Table 1). High concentration (10 µg/ml) resulted in 75% 60-day survivors with a 228% increase in life span without any tumour-free survivor. However, with 5 µg/ml, the increase in life span and 60-day survivors decreased to 141 and 17%, respectively. Animals initially inoculated with tumour cells incubated with 10 µg/ml cisplatin and subsequently challenged exhibited a 142% increase in life span with 12% tumour-free survivors (Table 2).

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Mice failed to develop tumours when inoculated with tumour cells incubated with 5 or 10 µg/ml cisplatin along with different concentrations of a-tocopherol. These animals when challenged on day 15th after the initial inoculation exhibited a 174% increase in life span with 30% 60-day survivors in the group receiving tumour cells incubated with 5 µg/ml cisplatin + 25 µg/ml a-tocopherol (Table 2). The increase in the life span of the animals was found to be 170% with 40% 60-day survivors if the dose of a-tocopherol was increased to 50 µg/ml in combination with cisplatin. This combination also resulted into 10% tumour-free survivors. Similarly, the group of mice initially receiving tumour cells incubated with 10 µg/ml cisplatin + 25 µg/ml a-tocopherol when challenged on the same day resulted into a 181% increase in life span with 38% 60-day survivors. The increase in life span was found to be 203% including 50% 60-day survivors when the concentration of a-tocopherol was increased to 50 µg/ml in combination with cisplatin (Table 2).

The effect of a-tocopherol on in vivo incorporation of cisplatin into tumour and kidney is shown in Table 3. There was a direct correlation between the concentration of cisplatin administered and platinum content in tumour and kidney. a-Tocopherol significantly enhanced the intratumour platinum content. When cisplatin was combined with 20 or 40 mg/kg a-tocopherol, a 256 and 306% increase in the intratumour platinum content was recorded, respectively. However, when the concentration of a-tocopherol was enhanced to 60 mg/kg, the increase in platinum content was reduced to 123%. a-Tocopherol failed to show any effect on the platinum content of the kidney.

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Results

Vitamins are antioxidants since they prevent the toxic effects of free radicals, which can interact with a variety of cellular molecules causing inhibition or alteration of functions through lipid peroxidation, DNA damage and enzyme inactivation. Vitamins possess chemical properties that allow them to regulate the oxidation-reduction potential of the cell and are frequently used in cancer therapies (24).

The present study indicates that a-tocopherol enhances the tumour growth inhibition induced by a low dose of cisplatin. a-Tocopherol alone had no significant effect on tumour growth inhibition, with only 10% of the animals showing increased survival time when inoculated with tumour cells incubated with 50 µg/ml a-tocopherol. It has been reported that a-tocopherol slightly enhances the proliferation (25) and inhibits the differentiation (26) of mouse myeloid leukemia cells. The growth of a variety of cell types is inhibited by vitamin E succinate (27-29) whereas d-a-tocopherol or its analogues such as acetate and nicotinate esters as well as the water-soluble analogue Trolox had very little effect on cell growth and differentiation in vitro (27). It has been suggested that vitamin E succinate, having a negative charge, membrane permeability and stability in intracellular compartments, inhibits cell growth and transformation, at least in part due to the inhibition of protein kinase C activity. However, vitamin E succinate did not significantly affect the growth of melanoma cells in culture (24).

Mice inoculated with cisplatin incubated with tumour cells exhibited a significant increase in their mean survival time compared to control. Palpable tumour was observed on day 15 in the group receiving tumour cells incubated with 5 µg/ml cisplatin, but when the concentration of cisplatin was enhanced to 10 µg/ml, tumour failed to appear on the same day. Even a challenge of the latter group with tumour cells resulted into an increase in the mean survival time of mice compared to control with 12% tumour-free survivors (Table 2). This shows that cisplatin brings about some changes in lymphoma cells responsible for the late appearance of the tumour. These changes may be morphological involving loss of membrane integrity and cell shrinkage (30,31). Cell surface and biochemical alterations have been reported to occur when fibrosarcoma cells are treated in vitro with cisplatin (3,32). In the present system a greater therapeutic benefit was achieved with 10 µg/ml cisplatin which resulted into increased mean survival time of animals even after the challenge. This concentration of cisplatin was shown to release a maximum amount of sialic acid from tumour cells if incubated in vitro (32) and may have been responsible for this effect. A synergistic effect of cisplatin and a-tocopherol was also apparent in the present study. The therapeutic potential of cisplatin was greatly enhanced by a-tocopherol since tumour cells incubated with various combinations of cisplatin + a-tocopherol failed to grow in animals. The mean survival time of animals increased even after challenge in different combination groups. This shows that tumour cells are viable after 1 h of drug treatment, being able to enhance the immune response but unable to grow into a tumour. Recently, it has been reported that after treatment with cisplatin and a-tocopherol these tumour cells progress towards necrosis (33). A marked inhibition of tumour growth was reported earlier when cisplatin was directly inoculated into tumour-bearing mice in combination with vitamins (24,34).

Therapeutic effect of different doses of cisplatin is directly related to the intratumour platinum content. In the present study, a subtherapeutical dose of cisplatin (3 mg/kg) was used in combination with a-tocopherol in order to elevate the intratumour platinum content as well as to observe its nephrotoxic effect. The present study suggests that one of the causes of enhancement of cisplatin-induced tumour growth inhibition by a-tocopherol might increase the uptake of cisplatin into tumour cells. This process is specific because platinum content was elevated only in the tumour and not in the kidney of the animals receiving a-tocopherol along with cisplatin. The increased uptake of cisplatin by a-tocopherol is suggested to be the result of the modulation of cell membrane permeability altering the level of peroxidation (18). In addition, membrane electropermeabilisation also affects both influx and efflux of cisplatin from tumour cells (35). The influx of some anticancer agents has been reported to be increased by vitamin A, which inhibits the growth of neuroblastoma cells (36-39). In addition to the effect of cisplatin on cell permeability, DNA is the critical target for cisplatin-induced cytotoxicity (40). The mechanism involved in the action of cisplatin is its ability to form covalent adducts with the genomic molecules (41-44). This process renders the cells incapable of replication, with consequent cell death (40). Cisplatin has been reported to induce programmed cell death or apoptosis that is triggered by the presence of cisplatin-DNA adducts; however, the signal transduction mechanism that links DNA damage to the cell death pathway remains unknown (30). a-Tocopherol may also act at the site of DNA and RNA where cisplatin binds (45), possibly increasing the efficiency of adduct formation in the genome, thus decreasing the ability of cells to remove these adducts. Such a decrease in the efficiency of the DNA repair machinery of tumour cells enables cisplatin to be more effective as an antitumour agent. Another possibility is that vitamins exert antineoplastic effects by increasing cytolytic and autophagic activity, cell membrane disruption and increased collagen synthesis, thus inhibiting the cancer cell metabolism and proliferation (46) or by stimulating antitumour immunity. Stimulation of helper T cells might enhance the antitumour activity of cisplatin (21). a-Tocopherol has been reported to enhance both lymphoproliferative reactions and the antitumour effect of adriamycin (47,48).

The present results indicate that combined treatment of Dalton's lymphoma with cisplatin and a-tocopherol has some advantage over cisplatin alone. The enhancement of tumour growth inhibition by a-tocopherol is possibly due to its effects on the influx of cisplatin into tumour cells, increasing the efficiency of adduct formation in genomic DNA and thus weakening the DNA repair machinery of tumour cells. This effect of a-tocopherol renders cisplatin more effective as an antitumour agent and indicates the importance and function of vitamins in cancer therapy.

Discussion

Acknowledgments

We are thankful to Dr. D.T. Khating, Head, Regional Sophisticated Instrumentation Centre, Shillong, for providing the facilities for platinum measurement.

Address for correspondence: S. Sarna, Department of Zoology, Gauhati University, Guwahati 781014, India.

S. Sarna is the recipient of financial assistance in the form of a research associateship from the University Grants Commission, New Delhi, India. Received October 27, 1998. Accepted April 10, 2000.

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Correspondence and Footnotes

Publication Dates

Publication in this collection
31 July 2000
Date of issue
Aug 2000

History

Accepted
10 Apr 2000
Received
27 Oct 1998

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1. Bahadur A, Sarna S & Sodhi A (1984). Enhanced cell mediated immunity in mice after cisplatin treatment. Polish Journal of Pharmacology and Pharmacy, 36: 441-448.

[2] 2. Gan XH, Jewett A & Bonavida B (1992). Activation of human peripheral blood derived monocytes by cis-diamminedichloroplatinum: enhanced tumoricidal activity and secretion of tumour necrosis factor-alpha. Natural Immunity, 11: 144-155.

[3] 3. Sarna S & Sodhi A (1978). Chemoimmunotherapeutical study on a fibrosarcoma with cis-dichlorodiammine platinum (II). Indian Journal of Experimental Biology, 16: 1236-1239.

[4] 4. Sarna S, Sodhi A & Bhola RK (1989). A possible mechanism of tumour regression in cisplatin treated mice. Polish Journal of Pharmacology and Pharmacy, 41: 69-76.

[5] 5. Chen G & Pan Q (1988). Potentiation of antitumour activity of cisplatin in mice by 3-aminobenzamide and nicotinamide. Cancer Chemotherapy and Pharmacology, 22: 303-307.

[6] 6. Ohkawa K, Tsukada Y, Dohzono H, Koike K & Terashima Y (1988). The effects of co-administration of selenium and cisplatin (CDDP) on CDDP-induced toxicity and antitumor activity. British Journal of Cancer, 58: 38-41.

[7] 7. Onoda JM, Nelson KK, Taylor JD & Honn KV (1988). Cisplatin and nifedipine: synergistic antitumor effect against an inherently cisplatin-resistant tumor. Cancer Letters, 40: 39-47.

[8] 8. Quarless SA (1988). Chloroquine enhances the cytotoxicity of cis-diamminedichloroplatinum II. Cancer Biochemistry and Biophysics, 10: 11-15.

[9] 9. Sarna S & Bhola RK (1989). Combination therapy of transplantable tumour in mice with cisplatin and glucose. Current Science, 58: 231-233.

[10] 10. Sarna S & Bhola RK (1993). Chemoimmunotherapeutical study on Dalton's lymphoma in mice using cisplatin and ascorbic acid: synergistic antitumour effect in vivo and in vitro Archivum Immunologiae et Therapiae Experimentalis, 41: 327-333.

[11] 11. Schem BC, Mella O & Dahl O (1992). Thermochemotherapy with cisplatin and carboplatin in the BT⁴rat glioma in vitro and in vivo International Journal of Radiation Oncology, Biology, Physics, 23: 109-114.

[12] 12. Majima H, Kashiwado K, Egawa S, Suzuki N & Urano M (1992). Interaction between the kinetics of thermotolerance and effect of cis-diamminedichloroplatinum (II) or bleomycin given at 37^o or 43^oC. International Journal of Hyperthermia, 8: 431-442.

[13] 13. Daoud SS & Forde NH (1991). Synergistic cytotoxic action of cisplatin and liposomal valinomycin on human ovarian carcinoma cells. Cancer Chemotherapy and Pharmacology, 28: 371-376.

[14] 14. Kawamoto K, Wada Y, Kumazawa H, Yamashita T, Kumazawa T & Matsumura H (1992). Experimental and clinical evaluation by flow cytometry for the mechanism of combination therapy (cisplatin and paplomycin). Cytometry, 13: 307-313.

[15] 15. Borek C, Ong A, Mason H, Donahue L & Biaglow JE (1986). Selenium and vitamin E inhibit radiogenic and chemically induced transformation in vitro via different mechanisms. Proceedings of the National Academy of Sciences, USA, 83: 1490-1494.

[16] 16. Radner BS & Kennedy AR (1986). Suppression of X-ray induced transformation by vitamin E in mouse C3H10T1/2 cells. Cancer Letters, 32: 25-32.

[17] 17. Yano T, Obata Y, Yano Y, Otani S & Ichikawa T (1994). Vitamin E acts as a useful chemopreventive agent to reduce spontaneous lung tumorigenesis in mice. Cancer Letters, 87: 205-210.

[18] 18. Prasad KN & Rama B (1984). Modification of the effect of the pharmacological agents, ionizing radiation and hyperthermia on tumour cells by vitamin E. In: Prasad KN (Editor), Vitamins, Nutrition and Cancer Karger, Basel.

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Brasil

Brasil

alpha-Tocopherol enhances tumour growth inhibition by cis-dichlorodiammine platinum (II)

Abstract

Introduction

Material and Methods

Acknowledgments

Correspondence and Footnotes

Publication Dates

History