Научная статья на тему 'Порівняльне дослідження протипухлинного ефекту немодифікованих фулеренів c 60 і доксорубіцину'

Порівняльне дослідження протипухлинного ефекту немодифікованих фулеренів c 60 і доксорубіцину Текст научной статьи по специальности «Биотехнологии в медицине»

CC BY
135
49
i Надоели баннеры? Вы всегда можете отключить рекламу.
Журнал
Biotechnologia Acta
CAS
Ключевые слова
С 60 FULLERENE / ФУЛЛЕРЕН С 60 / ДОКСОРУБИЦИН / КАРЦИНОМА ЛЕГКИХ ЛЬЮИСА / ИНГИБИТОР РОСТА ОПУХОЛИ / ПРОДЛЕНИЕ ЖИЗНИ ЖИВОТНЫХ / КОЭФФИЦИЕНТ ИНГИБИРОВАНИЯ МЕТАСТАЗОВ / ФУЛЕРЕН С 60 / ДОКСОРУБіЦИН / КАРЦИНОМА ЛЕГЕНЬ ЛЬЮїСА / іНГіБіТОР РОСТУ ПУХЛИНИ / ПОДОВЖЕННЯ ЖИТТЯ ТВАРИН / КОЕФіЦієНТ іНГіБУВАННЯ МЕТАСТАЗіВ / DOXORUBICIN / LEWIS LUNG CARCINOMA / TUMOR GROWTH INHIBITION / INCREASING OF ANIMAL LIFE SPAN / METASTASIS INHIBITION INDEX

Аннотация научной статьи по биотехнологиям в медицине, автор научной работы — Prylutska S. V., Burlaka A. P., Prylutskyy Yu I., Ritter U., Scharff P.

The purpose of this study was mainly focused on the technology of application of C 60 fullerenes in the combined therapy with doxorubicin for treatment of malignant tumors. Growth experiments of transplanted malignant tumors in the presence of pristine С 60 fullerenes, doxorubicin and C 60 in combination with doxorubicin were performed on groups of mice. It was found that C 60 in combination with doxorubicin injection efficiently inhibits the growth of transplanted malignant tumor as well as metastases of Lewis lung carcinoma. The findings demonstrate the possibility of using C 60 in combination with doxorubicin in anticancer therapy.

i Надоели баннеры? Вы всегда можете отключить рекламу.
iНе можете найти то, что вам нужно? Попробуйте сервис подбора литературы.
i Надоели баннеры? Вы всегда можете отключить рекламу.

Текст научной работы на тему «Порівняльне дослідження протипухлинного ефекту немодифікованих фулеренів c 60 і доксорубіцину»

UDK 546.26.043

COMPARATIVE STUDY OF ANTITUMOR EFFECT OF PRISTINE C60 FULLERENES AND DOXORUBICIN

S. V. Prylutska1 Joint Ukrainian-German Center on Nanobiotechnology,

А. P. Burlaka2 Kyiv National Taras Shevchenko University

Yu. I. Prylutskyy1 2Kavetsky Institute of Experimental Pathology,

U. Ritter3 Oncology and Radiobiology of National Academy of Sciences of Ukraine, Kyiv

P. Scharff3 3Technical University of Ilmenau, Institute of Chemistry

and Biotechnology, Germany

E-mail: [email protected]

Received 20.09.2011

The purpose of this study was mainly focused on the technology of application of C60 fullerenes in the combined therapy with doxorubicin for treatment of malignant tumors. Growth experiments of transplanted malignant tumors in the presence of pristine C60 fullerenes, doxorubicin and C60 in combination with doxorubicin were performed on groups of mice. It was found that C60 in combination with doxorubicin injection efficiently inhibits the growth of transplanted malignant tumor as well as metastases of Lewis lung carcinoma. The findings demonstrate the possibility of using C60 in combination with doxorubicin in anticancer therapy.

Key words: C60 fullerene; doxorubicin; Lewis lung carcinoma; tumor growth inhibition; increasing of animal life span; metastasis inhibition index.

Cancer remains a major cause of premature mortality [1]. This stimulates development of new effective medications capable of selectively inhibit growth and proliferation of tumor cells. One of such drugs is an anthracycline antibiotic, doxorubicin (Dox) [2, 3]. Its molecule is a complex heterocyclic compound, poorly soluble in water and weakly polar organic solvents. However, Dox is able to form inclusion compounds with the DNA molecules and this determines the mechanism of its impact on cancer cells. Intercalation of the DNA molecules with Dox (insertion between adjacent pairs of complementary nucleotides) interferes with the ability of cancer cells to reproduce the genetic information. On the other hand, Dox is capable of producing pathological side effects, primarily a negative impact on the functioning of heart [2, 4]. In this regard, there is a need to develop alternative methods of tumors treatment and to find new substances, which act locally in tumor, causing its destruction. One of the mechanisms of such destruction is the stimulation of tumor cells death by necrosis or apoptosis with preserving of normal cells viability. Biologically active nontoxic C60 fullerenes [5-7], which are able to penetrate through the membrane of cells [8, 9] and have strong antioxidant and antiviral properties [10, 11], could be used for preventing the growth of malignant neoplasms. In

fact, some fullerene derivatives have shown promising anticancer activity [12]. Namely, Murugesan et al. [13] have demonstrated the substantial antiangiogenic activity of C60 fullerenes against either basic fibroblast growth factor- or vascular endothelial growth factor-induced angiogenesis in the chick chlo-rioallantoic membrane model. Meng et al. [14] have reported that fullerene derivatives are capable to regulate in low levels simultaneously more than 10 angiogenic factors in the mRNA level that is further confirmed at the protein level. This result indicates that fullerene-containing materials serve as a potent antiangiogenesis inhibitor that can simultaneously target multiple angiogenic factors. Yin et al. [15, 16] found that metallo-fullerene nanoparticles penetrate plasma membrane of tumor cells, effectively inhibit their proliferation and decrease the activities of those enzymes which are responsible for catalyzing the production of reactive oxygen species in vivo. In addition, the effect of amino-acid derivatives of C60 fullerene in combination with anticancer drug adriamicin as modifiers of biological reactions in the treatment of metastatic tumors was studied in vivo [17]. It was found that amino-acid derivatives of C60 fullerene penetrate the lipid bilayer of biological membrane and are the effective inhibitors of lipid peroxidation. The maximum

therapeutic effect of the amino-acid derivatives of C60 fullerene use (dose 50 mg/kg) in combination with adriamicin (in dose

1 mg/kg) was 40% for the index of metastases inhibition. Within the chemically-induced model of breast cancer the authors [18] investigated the possible protective role of fullerenol to the action of antitumor drug Dox, which caused pulmonary toxicity in rats. These results clearly indicate that the using only Dox (in dose 8 mg/kg) significantly impairs lung function, but preliminary injection of fullerenol (in dose 100 mg/kg; 30 min before Dox) prevents its toxic effect through the inhibition of oxidative stress.

Considering the importance of using C60 fullerenes for the cancer treatment [19], the purpose of this work was mainly focused on comparative analysis of antitumor effect of pristine (unmodified) water-soluble C60 fullerenes and Dox. Moreover, we propose the technology of application of C60 fullerenes in the combined chemotherapy with Dox for treatment of malignant tumors.

Materials and Methods

The C60 fullerene aqueous solution (C60FAS) with maximum concentration of C60

1.0 mg/ml used for the experiments was prepared as follows [20]. Theoretical calculations

[21] showed that this C60FAS contains both single C60 molecules and their clusters (with sizes of about 0.7-4 nm depending of C60 fullerene concentration) in the hydrated state. The STM images of submonolayer C60 fullerene film deposited from aqueous solution on Au(111) surface demonstrate both C60 fullerene clusters with sizes up to ~2.8 nm (the first stable sphere-like cluster consisting of 13 hydrated C60 fullerenes [21]) and single C60 molecules

[22]. Moreover, C60 fullerenes structure the water, absorbed by DNA molecules [23], and thus they can affect the DNA functioning in the biosystem. Finally, it is important to note that used C60FAS does not show a cytotoxic effect with respect to both normal and transformed cells at concentrations below

1.0 mg/ml [6].

The male mice of C57Bl/6J line (20-21 g weight) were kept in a vivarium on a standard diet. The average temperature in a vivarium was 25±1 °C. We have to mention that in all experiments performed in the present work we followed the international principles of European Convention for protection of vertebrate animals.

Tumor transplantation (Lewis lung carcinoma) was performed by intramuscular injection to the animal’s limb (initial number of

tumor cells was equal to -5-105; antitumor effect, Experiment 2) or to the pad of animal’s limb (initial number of tumor cells was equal to -1-106; antimetastatic effect, Experiment 1). As is known, the strain of this tumor is characterized by a high degree of lung metas-tases damage.

The C60FAS in the volume of 0.1 ml (the initial concentration of C60 fullerenes in water was 1.0 mg/ml) was injected intraperitoneal to the animals after the transplantation of tumor (group 1) 5 times with interval through a day given the fact that C60 fullerenes, introduced intraperitoneal to animals (dose 500 mg/kg), excreted from the body within 2-4 days [24]. Dox («Ebewe», Austria; the initial concentration was 0.1 mg/ml) was injected intraperi-toneal to the animals after the transplantation of tumor (group 2) in the volume of 0.1 ml (dose 0.5 mg/kg) one-time for 5 days given the fact that Dox excreted in the urine from the body within 5 days. The C60FAS in the volume of 0.1 ml (the initial concentration was 1.0 mg/ml) was injected intraperitoneal to the animals after the transplantation of tumor one-time for 5 days 30 min prior to the introduction of Dox (group 3). Introduction of Dox (group 2) and C60FAS in combination with Dox (C60+Dox) (group 3) started on the 10th day after the transplantation of tumor, when it appeared visually. Finally, group 0 (mice with transplanted tumor without C60FAS or Dox injection) was used as control. The initial number of animals in each group was 7. On the 20th day of Experiment 1 (antimetastatic effect) all animals were put to death for the purpose of calculating the number of metas-tases in the lung of each animal.

The antitumor effectiveness of the applied technique was estimated using such quantitative indicators as the metastasis inhibition index, tumor growth inhibition and increasing of animal life span [19].

The statistical analysis of obtained results was performed by use the STATISTICA software package including the Student’s t-test [25].

Results and Discussion

The results obtained from Experiment 1 (antimetastatic effect) are presented in Table 1. They clearly demonstrate that the metastasis inhibition index for group 2 (Dox injection) is almost twice the value of this index for group 1 (C60FAS injection) and different in ~1.2 times from the metastasis inhibition index for group 3 (injection of C60+Dox) on 20th day after the tumor transplantation.

Table 1. Experiment 1 (antimetastatic effect)

Notes: start of tumor transplantation — 20.05.2011. Start of C60FAS injection after the tumor transplantation — 22.05.2011 (group 1). Start of Dox (group 2) and C60FAS in combination with Dox (group 3) injection after the tumor transplantation — 30.05.2011. Initial number of animals in experimental groups was n = 7;

* the differences are statistically valid compared with the control ^ < 0.05).

The results extracted from Experiment 2 (antitumor effect) are presented in Table 2. Antitumor effect of drugs was recorded on the 10th day after the transplantation of tumor in all experimental groups. Tumor growth inhibition in group 1 (C60FAS injection) and group 3 (injection of C60+Dox) shows a tendency to decrease from 45 to 22% (21th day after the tumor transplantation) and from 34 to 21%, respectively. On the contrary, tumor growth inhibition in group 2 (Dox injection) increased from 20%, reached a maximum of 28% (14th day after the tumor transplantation), and then stopped altogether. Finally, the increasing of animal life span in group 1 and group 3 are close in value, but above this parameter in ~1.5 times for group 2.

For visual comparison of tumor growth, Fig. presents the animals in group 0 (control; Fig., a), group 1 (C60FAS injection; Fig., b), group 2 (Dox injection; Fig., c) and group 3 (injection of C60+Dox; Fig., d) on 20th day

after the tumor transplantation in Experiment 2. Estimations demonstrate that the average tumor volume in control over this parameter in the experimental groups 1, 2 and 3 in ~1.5, ~3 and ~4.5 times, respectively.

It is also important to note that the visual observation of experimental animals revealed that animals in group 1 (C60FAS injection) and group 3 (injection of C60+Dox) compared to the animals in experimental group 2 have greater mobility and that the color of their hair was more explicit shade. Finally, the life span duration for last animal in group 1 and group 3 (42 days after the tumor transplantation) over this parameter in a control group 0 in ~1.5 times.

This study clearly demonstrates that such drugs as C60 fullerenes, Dox and C60+Dox cause an antitumor response at low therapeutic doses. Specifically, it was observed that a treatment with C60+Dox enhances the antitumor activity, namely contributes to the probable inhibition of tumor growth as well as metastases of Lewis lung carcinoma in male mice C57Bl/6J line: the maximum therapeutic effect reached 34% for the tumor growth inhibition and 79% for the metastasis inhibition index; the increasing of animal life reached 24.4%. These results can be explained as a result of the high antioxidant activity of C60 fullerenes [10], neutralizing excess reactive oxygen species in the cell, and possibly blocking the specific cell receptors, for example, endothelial growth factor [13, 14]. In addition, we can assume that the injection of pristine C60 fullerenes in combination with Dox effectively prevents/reduces its toxic affect

Experimental groups Metastasis inhibition index, %*

1 48±3

2 94±4

3 79±4

Table 2. Experiment 2 (antitumor effect)

Number of days after tumor transplantation Group 0 (control) Group 1 (injection of C6„FAS) Tumor growth inhibition*, % Group 2 (injection of Dox) Tumor growth inhibition*, % Group 3 (injection of C60FAS +Dox) Tumor growth inhibition*, %

10 n = 7 n =7 45±4 n = 7 20±1 n = 7 34±3

14 n = 7 n = 7 36±3 n = 7 28±2 n = 7 34±3

19 n = 5 n = 5 25±2 n = 7 n = 7 33±3

21 n = 4 n = 5 22±2 n = 4 n = 6 21±1

29 n = 0 n = 3 n = 2 n = 4

37 n = 1 n = 0 (15±1)%* n = 1

42 n = 0 (21.4±1.4)%* n = 0 (24.4±1.6)%*

Notes: start of tumor transplantation — 11.06.2011. Start of C60FAS injection after the tumor transplantation — 13.06.2011 (group 1). Start of Dox (group 2) and C60FAS in combination with Dox (group 3) injection after the tumor transplantation — 21.06.2011. Initial number of animals in experimental groups was n=7. Increasing of animal life is given in parentheses. * the differences are statistically valid compared with the control ^ < 0.05).

Visual comparison of tumor size for animals of group 0 (control: a), group 1 (C60FAS injection: b), group 2 (Dox injection: c) and group 3 (injection of C60fAs in combination with Dox: d) on 20th day

after the tumor transplantation

on the organism (like a fullerenol through the inhibition of oxidative stress [18]), especially cardiotoxic effect, that requires further using histological and biochemical approaches (in particular, identifying indicators of apoptosis and necrosis of tumors, level of oxygen radicals in the mitochondria of tumor cells). The

proposed technology of treatment with C60+Dox can be very promising in clinical oncology for the inhibition of tumor growth [26].

This work was supported by joint grant of BMBF and State Agency for Science, Innovation and Informatization of Ukraine (Ukr 10/012).

REFERENCES

1. Boyle P., Levin B. World Cancer Report. — WHO, 2008.

2. Hrelia S., Fiorentini D., Maraldi T. et al. Doxorubicin induced early lipid peroxidation associated with changes in glucose transport in cultured cardiomyocites // Biochem. Bio-phys. Acta. — 2002. — V. 64. — P. 139-145.

3. Abou El Hassan M. A. I., Verheul H. M. W., Jorna A S. et al. The new cardioprotector mono-hydroxyethylrutoside protects against doxorubicin-induced inflammatory effects in vitro // Brit. J. Cancer. — 2003. — V. 98. — P. 357-362.

4. De Vita V. T., Hellman S., Rosenberg S. A. Principles and Practice of Oncology, 6th ed, Lippincott Williams and Wilkins, Philadelphia, USA, 2001. — P. 1126-1161.

5. Andrievsky G., Klochkov V., Derevyanchenko L. Is the C60 Fullerene Molecule Toxic?!// Fuller. Nanotubes Carb. Nanostruct. — 2005. — V. 13. — P. 363-376.

6. Prylutska S. V., Matyshevska O. P., Golub A. A. et al. Study of C60 fullerenes and C60-contain-ing composites cytotoxicity in vitro // Mater. Sci. Engineer. C. — 2007. — V. 27. — P. 1121-1124.

7. Johnston H. J., Hutchison G. R., Christensen F. M. et al. The biological mechanisms and physicochemical characteristics responsible for driving fullerene toxicity // Toxicol. Sci. — 2010. — V. 114. — P. 162-182.

8. Foley S., Crowley C., Smaihi M. et al. Cellular localisation of a water-soluble fullerene derivative // Biochem. Biophys. Res. Com-mun. — 2002. — V. 294. — P. 116-119.

9. Schuetze C., Ritter U., Scharff P. et al. Interaction of N-fluorescein-5-isothiocya-nate pyrrolidine-C60 compound with a model bimolecular lipid membrane // Mat. Sci. Engineer. C. — 2011. — V. 31. — P. 1148-1150.

10. Prylutska S. V., Grynyuk 1.1., Matyshevska O. P. et al. Anti-oxidant properties of C60 fullerenes in vitro // Fuller. Nanotubes Carb. Nanostruct. — 2008. — V. 16. — P. 698-705.

11. Medicinal chemistry and pharmacological potential of fullerenes and carbon nanotubes. Series: Carbon Materials: Chemistry and Physics. / T. Da Ros, F. Cataldo, (Eds.). — Netherlands: Springer, 2008. — 408 pp.

12. Freitas Jr R. A. Nanomedicine, Volume IIA: Biocompatibility, Landes Bioscience. — Georgetown: TX, 2003.

13. Murugesan S., Mousa S. A., O’Connor L. J. et al. Carbon inhibits vascular endothelial growth factor- and fibroblast growth factor-promoted angiogenesis // FEBS Lett. — 2007. — V. 581. — P. 1157-1160.

14. Meng H., Xing G., Sun B. et al. Potent angio-genesis inhibition by the particulate form of fullerene derivatives // ASC Nano. — 2010. — V. 4. — P. 2773-2783.

15. Yin J. J., Lao F., Fu P. P. et al. Inhibition of tumor growth by endohedral metallo-fullerenol nanoparticles optimized as reactive oxygen species scavenger // Mol. Pharmacol. — 2008. — V. 74. — P. 1132-1140.

16. Yin J. J., Lao F., Fu P. P. et al. The scavenging of reactive oxygen species and the potential for cell protection by functionalized fulle-rene materials // Biomaterials. — 2009. — V. 30. — P. 611-621.

17. Faingold 1.1,, Konovalova N. P., Kotelnikova R. A. et al. The amino-acid derivatives of C60 fullerene — modifiers of biological reactions in the cytostatic therapy of metastatic tumors // Rus. Biotherapy J. — 2007. — V. 6. — P. 52 (in Russian).

18. Injac R., Radic N., Govedarica B. et al. Acute doxorubicin pulmotoxicity in rats with malignant neoplasm is effectively treated with fullerenol C60(OH)24 through inhibition of oxidative stress // Pharmacol. Reports. — 2009. — V. 61. — P. 335-342.

19. Prylutska S. V., Burlaka A. P., Klymenko P. P. et al. Using water-soluble C60 fullerenes in anticancer therapy // Cancer Nanotechnol. — 2011. — V. 2, N 1. — P. 105-110.

20. Scharff P., Risch K., Carta-Abelmann L. et al. Structure of C60 fullerene in water: spectroscopic data // Carbon. — 2004. — V. 42. — P. 1203-1206.

21. Bulavin L., Adamenko I., Prylutskyy Yu. et al. Structure of fullerene C60 in aqueous solution // Phys. Chem. Chem. Phys. — 2000. — V. 2. — P. 1627-1629.

22. Prylutska S. V., Burlaka A. P., Prylutskyy Yu. I., et al. Pristine C60 fullerenes inhibit the rate of tumor growth and metastasis. // Exp. Oncol. — 2011. — V. 33, N 3. — P. 162-164.

23. Turov V. V., Chehun V. F., Krupskaya T. V. et al. Effect of small addition of C60 fullerenes on the hydrated properties of nanocomposites based on highly dispersed silica and DNA // Chem. Phys. Lett. — 2010. — V. 496. — P. 152-156.

24. Gharbi N., Pressac M., Hadchouel M. et al. C60 fullerene is a powerful antioxidant in vivo with no acute or subacute toxicity // Nano Lett. — 2005. — V. 5. — P. 2578-2585.

25. Gubler E. V. Computational methods of analysis and recognition of pathological processes. — Moscow: Medicine, 1978 (in Russian).

26. Prylutska S. V. Method of treatment of malignant tumors by unmodified C60 fullerenes and doxorubicin combination. Patent of Ukraine for an invention N a201110131, 16 August, 2011.

ПОРІВНЯЛЬНЕ ДОСЛІДЖЕННЯ ПРОТИПУХЛИННОГО ЕФЕКТУ НЕМОДИФІКОВАНИХ ФУЛЕРЕНІВ C60 І ДОКСОРУБІЦИНУ

С. В. Прилуцька1 А. П. Бурлака2 Ю. І. Прилуцький1 У. Ріттер3 П. Шарф3

1Спільний Українсько-німецький центр з нанобіотехнології,

Київський національний університет імені Тараса Шевченка

2Інститут експериментальної патології, онкології і радіобіології ім. Р. Е. Кавецького НАН України, Київ 3Технічний університет Ілменау, Інститут хімії і біотехнології, Німеччина

E-mail: [email protected]

Метою дослідження було розроблення технології застосування фулеренів С60 у комбінованій терапії з доксорубіцином для лікування злоякісних пухлин. Серію експериментів у присутності немодифікованих фулеренів С60, доксорубіцину і С60 у комбінації з доксорубі-цином проводили на групі мишей з трансплантованими злоякісними пухлинами. Встановлено, що введення С60 у комбінації з доксорубіцином ефективно пригнічує як ріст пухлини, так і метастазування карциноми легень Льюїса. Результати демонструють можливість використання С60 у комбінації з доксорубіцином у протипухлинній терапії.

Ключові слова: фулерен С60, доксорубіцин, карцинома легень Льюїса, інгібітор росту пухлини, подовження життя тварин, коефіцієнт інгібування метастазів.

СРАВНИТЕЛЬНОЕ ИССЛЕДОВАНИЕ ПРОТИВООПУХОЛЕВОГО ЭФФЕКТА НЕМОДИФИЦИРОВАННЫХ ФУЛЛЕРЕНОВ С60 И ДОКСОРУБИЦИНА

С. В. Прилуцкая1 А. П. Бурлака2 Ю. И. Прилуцкий1 У. Риттер3 П. Шарф3

Совместный Украинско-немецкий центр по нанобиотехнологии,

Киевский национальный университет имени Тараса Шевченко

2Институт экспериментальной патологии, онкологии и радиобиологии им. Р. Е. Кавецкого НАН Украины, Киев

3Технический университет Илменау, Институт химии и биотехнологии, Германия

Е-та1: [email protected]

Целью исследования была разработка технологии применения фуллеренов С60 в комбинированной терапии с доксорубицином для лечения злокачественных опухолей. Серию экспериментов в присутствии немодифициро-ванных фуллеренов С60, доксорубицина и С60 в сочетании с доксорубицином проводили на группе мышей с трансплантированными злокачественными опухолями. Установлено, что введение С60 в сочетании с доксорубицином эффективно подавляет как рост опухоли, так и метастазирование карциномы легких Льюиса. Результаты демонстрируют возможность использования С60 в сочетании с доксорубици-ном в противоопухолевой терапии.

iНе можете найти то, что вам нужно? Попробуйте сервис подбора литературы.

Ключевые слова: фуллерен С60, доксоруби-цин, карцинома легких Льюиса, ингибитор роста опухоли, продление жизни животных, коэффициент ингибирования метастазов.

i Надоели баннеры? Вы всегда можете отключить рекламу.