References

bioph

Biomedical Photonics

2413-9432

Non-profit partnership for development of domestic photodynamic therapy and photodiagnosis

10.24931/2413-9432-2016-5-3-4-8

bioph-96

Research Article

ОРИГИНАЛЬНЫЕ СТАТЬИ

ORIGINAL ARTICLES

ИЗУЧЕНИЕ МЕХАНИЗМОВ ФОТОИНДУЦИРОВАННОЙ ГИБЕЛИ НА МОДЕЛИ КЛЕТОК МЕЛАНОМЫ КОЖИ

THE STUDY OF MECHANISMS OF PHOTOINDUCED APOPTOSIS IN THE SKIN MALIGNANT MELANOMA CELL MODEL

Гельфонд

М. Л.

Gelfond

M. L.

mark.gelfond@gmail.com

Балдуева

И. А.

Baldueva

I. A.

Барчук

А. С.

Barchuk

A. S.

Гафтон

Г. И.

Gafton

G. I.

Анисимов

В. В.

Anisimov

V. V.

Семилетова

Ю. В.

Semiletova

Yu. V.

Новик

А. В.

Novik

A. V.

Мяснянкин

М. Ю.

Myasnyankin

M. Yu.

Нехаева

Т. Л.

Nekhaeva

T. L.

Данилова

А. Б.

Danilova

A. B.

Воробейчиков

Е. В.

Vorobeychikov

E. V.

Вааль

А. И.

Vaalj

A. I.

Гафтон

И. Г.

Gafton

I. G.

Научно-исследовательский институт онкологии им. Н.Н. Петрова, Санкт-Петербург, Россия Северо-Западный государственный медицинский университет им. И.И. Мечникова, Санкт-Петербург, РоссияРоссияFederal State Institution N.N.Petrov Research Institute of Oncology of Federal Agency of High Technology Medical Assistance, Saint-Petersburg, Russia North-Western State Medical University named after I.I. Mechnikov, Saint-Petersburg, RussiaRussian Federation

Научно-исследовательский институт онкологии им. Н.Н. Петрова, Санкт-Петербург, Россия Первый Санкт-Петербургский государственный медицинский университет им. акад. И.П. Павлова, Санкт-Петербург, РоссияРоссияFederal State Institution N.N.Petrov Research Institute of Oncology of Federal Agency of High Technology Medical Assistance, Saint-Petersburg, Russia Federal State Budgetary Educational Institution of Higher Education Academician I.P. Pavlov First St. Petersburg State Medical University of the Ministry of Healthcare of Russian Federation, Saint-Petersburg, RussiaRussian Federation

Научно-исследовательский институт онкологии им. Н.Н. Петрова, Санкт-Петербург, РоссияРоссияFederal State Institution N.N.Petrov Research Institute of Oncology of Federal Agency of High Technology Medical Assistance, Saint-Petersburg, RussiaRussian Federation

Северо-Западный государственный медицинский университет им. И.И. Мечникова, Санкт-Петербург, РоссияРоссияNorth-Western State Medical University named after I.I. Mechnikov, Saint-Petersburg, RussiaRussian Federation

2016

02122016

5348

Copyright © Гельфонд М.Л., Балдуева И.А., Барчук А.С., Гафтон Г.И., Анисимов В.В., Семилетова Ю.В., Новик А.В., Мяснянкин М.Ю., Нехаева Т.Л., Данилова А.Б., Воробейчиков Е.В., Вааль А.И., Гафтон И.Г., 2016

2016

Гельфонд М.Л., Балдуева И.А., Барчук А.С., Гафтон Г.И., Анисимов В.В., Семилетова Ю.В., Новик А.В., Мяснянкин М.Ю., Нехаева Т.Л., Данилова А.Б., Воробейчиков Е.В., Вааль А.И., Гафтон И.Г.

Gelfond M.L., Baldueva I.A., Barchuk A.S., Gafton G.I., Anisimov V.V., Semiletova Y.V., Novik A.V., Myasnyankin M.Y., Nekhaeva T.L., Danilova A.B., Vorobeychikov E.V., Vaalj A.I., Gafton I.G.

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

https://www.pdt-journal.com/jour/article/view/96

В статье представлены результаты экспериментального исследования иммунного ответа клеток меланомы кожи человека Mel 226 на фотодинамическое воздействие. Изучен фотоиндуцированный апоптоз клеток меланомы кожи in vitro. Исследования показали, что облучение с препаратом фотодитазин в концентрациях 0,5-2,5 мкг/мл (экспозиция в течение 6 и 10 мин за 30 мин до облучения; параметры облучения: длина волны 662 нм, суммарная доза облучения от 40 до 60 Дж/см2) индуцирует ранний апоптоз. Увеличение времени лазерного облучения достоверно ускоряет переход фотосенсибилизированных опухолевых клеток из ранней фазы апоп-тоза в позднюю.

The results of the experimental study of immune response of human skin malignant melanoma cells Mel 226 on photodynamic exposure are represented in the article. Photoinduced apoptosis of skin malignant melanoma was studied in vitro. The study showed that irradiation with the agent fotoditazin at dose of 0.5–2.5 µg/ml (6 and 10 min exposure 30 min before irradiation; irradiation parameters: wavelength of 662 nm, total light dose from 40 to 60 J/cm2) induced early apoptosis. The increase of the time of laser irradiation signiﬁcantly accelerates the conversion of photosensitized tumor cells from early to late apoptosis.

меланома кожи человекаапоптозиммунный ответапоптический индексфотодинамическое воздействиефото-дитазин

human skin malignant melanomaapoptosisimmune responseapoptotic indexphotodynamic exposurefotoditazin

References1

Злокачественные новообразования в России в 2009 году (заболеваемость и смертность) / Под ред. В.И. Чиссова, В.В. Старинского, Г.В. Петровой. – М.: ООО “Антиф”, 2011. – 260 с.

Zlokachestvennye novoobrazovaniya v Rossii v 2009 godu (zabolevae-most' i smertnost') / (Malignant neoplasms in Russia in 2009 (incidence and mortality), by eds. V.I. Chissov, V.V. Starinskii, G.V. Petrova. Mos-cow, OOO Antif Publ., 2011. 260 p.

Филоненко Е.В., Серова Л.Г., Урлова А.Н. Фотодинамическая терапия больных с внутрикожными метастазами меланомы // Biomedical Photonics. – 2015. – Т. 4, № 2. – С. 22-25.

Filonenko E.V., Serova L.G., Urlova A.N. Photodynamic therapy in patients with skin metastases of melanoma, Biomedical Photonics, 2015, Vol. 4, No. 2, pp. 22-25. (in Russian).

Мерабишвилли В.М. Выживаемость онкологических больных. – СПб: ООО “Фирма Коста”, 2006. – 438 с.

Merabishvilli V.M. Vyzhivaemost' onkologicheskikh bol'nykh (Survival rate of cancer patients). Saint Petersburg, OOO Firma Kosta Publ., 2006. 438 p.

Балдуева И.А. Иммунологические особенности взаимоотношения опухоли и организма при меланоме // Практическая онкология. – 2001. – № 4(8). – С. 37-41.

Baldueva I.A. Immune characteristics of tumor–host interaction in melanoma, Prakticheskaya onkologiya, 2001, No. 4(8), pp. 37-41. (in Russian).

Gollnick S., Evans S., Baumann H. Role of cytokines in photodynamic therapy-induced local and systemic inﬂammation // Br. J. Cancer. – 2003. – Vol. 88. – P. 1772-9.

Gollnick S., Evans S., Baumann H. Role of cytokines in photodynamic therapy-induced local and systemic inﬂammation, Br. J. Cancer, 2003, Vol. 88, pp. 1772-9.

Gollnick S., Vaughan L., Henderson B. Generation of eﬀective antitumor vaccines using photodynamic therapy // Cancer Res. – 2002. – Vol. 62. – P. 1604-8.

Gollnick S., Vaughan L., Henderson B. Generation of eﬀective antitumor vaccines using photodynamic therapy, Cancer Res., 2002, Vol. 62, pp. 1604-8.

Gollnick S.O., Brackett C.M. Enhancement of anti-tumor immunity by photodynamic therapy // Immunol Res. – 2010. – Vol. 46(1-3). – P. 216-26.

Gollnick S.O., Brackett C.M. Enhancement of anti-tumor immunity by photodynamic therapy, Immunol Res., 2010, Vol. 46(1-3), pp. 216-26.

Preise D., Oren R, Glinert I., et al. Systemic antitumor protection by vascular-targeted photodynamic therapy involves cellular and humoral immunity // Cancer. Immunol. Immunother. – 2009. – Vol. 58. – P. 71-84.

Preise D., Oren R, Glinert I., Kalchenko V., Jung S., Scherz A., Salomon Y. Systemic antitumor protection by vascular-targeted photodynamic therapy involves cellular and humoral immunity, Cancer. Immunol. Immunother., 2009, Vol. 58, pp. 71-84.

Preise D., Scherz A., Salomon Y. Antitumor immunity promoted by vascular occluding therapy: lessons from vascular-targeted photodynamic therapy (VTP) // Photochem Photobiol Sci. – 2011. – Vol. 10(5). – P. 681-8.

Preise D., Scherz A., Salomon Y. Antitumor immunity promoted by vascular occluding therapy: lessons from vascular-targeted photodynamic therapy (VTP), Photochem Photobiol Sci, 2011, Vol. 10(5), pp. 681-8.

Huang Z., Xu H., Meyers A.D., et al. Photodynamic therapy for treatment of solid tumors-potential and technical challenges //

Huang Z., Xu H., Meyers A.D., Musani A.I., Wang L., Tagg R., Barqawi A.B., Chen Y.K. Photodynamic therapy for treatment of solid tumors-potential and technical challenges, Technol Cancer Res Treat, 2008, Vol. 7(4), pp. 309-20.

Technol Cancer Res Treat. – 2008. – Vol. 7(4). – P. 309-20.

Mroz P., Szokalska A., Wu M.X., Hamblin M.R. Photodynamic Therapy of Tumors Can Lead to Development of Systemic Antigen-Speciﬁc Immune Response, PLoS ONE, 2010, Vol. 5(12), pp. 151-94.

Mroz P., Szokalska A., Wu M.X., Hamblin M.R. Photodynamic Therapy of Tumors Can Lead to Development of Systemic Antigen-Specific Immune Response // PLoS ONE. –2010. – Vol. 5(12). – P. 151-94.

Abels C. Targeting of the vascular system of solid tumours by photodynamic therapy (PDT), Photochem Photobiol Sci, 2004, No. 3, pp. 765-71.

Abels C. Targeting of the vascular system of solid tumours by photodynamic therapy (PDT) // Photochem Photobiol Sci. – 2004. – No. 3. – P. 765-71.

Golab J., Wilczynski G., Zagozdzon R., Stoklosa T., Dabrowska A., Rybczynska J., Wasik M., Machaj E., Olda T., Kozar K., Kaminski R., Giermasz A., Czajka A., Lasek W., Feleszko W., Jakobisiak M. Potentiation of the anti-tumor eﬀects of Photofrin-based photodynamic therapy by localized treatment with G-CSF, Br. J. Cancer., 2000, Vol. 82(8), pp. 1485-91.

Golab J., Wilczynski G., Zagozdzon R., et al. Potentiation of the anti-tumor effects of Photofrin-based photodynamic therapy by localized treatment with G-CSF // Br. J. Cancer. – 2000. – Vol. 82(8). – P. 1485-91.

Van Duijnhoven F.H. The immunological consequences of photodynamic treatment of cancer, a literature review, Immunobiology, 2003, Vol. 207, pp. 105-13.

Van Duijnhoven F.H. The immunological consequences of photodynamic treatment of cancer, a literature review // Immuno-biology. – 2003. – Vol. 207. – P. 105-13.

Akopov A.L., Kazakov N.V., Rusanov A.A., Karlson A. The mechanisms of photodynamic action for treating of cancer patients, Biomedical Photonics, 2015, Vol. 4, No. 2, pp. 9-16. (in Russian).

Акопов А.Л., Казаков Н.В., Русанов А.А., Карлсон А. Механизмы фотодинамического воздействия при лечении онкологических больных // Biomedical Photonics. – 2015. – Т. 4, № 2. – С. 9-16.

Almeida R.D., Manadas B.J., Carvalho A.P., Duarte C.B. Intracellular signaling mechanisms in photodynamic therapy, Biochim. Biophys. Acta., 2004, Vol. 1704, pp. 59-86.

Almeida R.D., Manadas B.J., Carvalho A.P., Duarte C.B. Intracellular signaling mechanisms in photodynamic therapy // Biochim.

Kiesslich T., Plaetzer K., Oberdanner C.B., Berlanda J., Obermair F.J., Krammer B. Diﬀerential eﬀects of glucose deprivation on the cellular sensitivity towards photodynamic treatment-based production of reactive oxygen species and apoptosis-induction, FEBS Le, 2005, Vol. 579, pp. 185-190.

Biophys. Acta. – 2004. – Vol. 1704. – P. 59-86.

Oberdanner C.B., Kiesslich T., Krammer B., Plaetzer K. Glucose is required to maintain high ATP-levels for the energy-utilizing steps during PDT-induced apoptosis, Photochem Photobiol., 2002, Vol. 76, pp. 695-703.

Kiesslich T., Plaetzer K., Oberdanner C.B., et al. Differential effects of glucose deprivation on the cellular sensitivity towards photodynamic treatment-based production of reactive oxygen species and apoptosis-induction // FEBS Le. – 2005. – Vol. 579. – P. 185-190

Filonenko E.V. Fluorescence diagnostics and photodynamic therapy: justiﬁcation of applications and opportunities in oncology, Biomedical Photonics, 2014, Vol. 3, No. 1, pp. 3-7. (in Russian).

Oberdanner C.B., Kiesslich T., Krammer B., Plaetzer K. Glucose is required to maintain high ATP-levels for the energy-utilizing steps during PDT-induced apoptosis // Photochem Photobiol. – 2002. – Vol. 76. – P. 695-703.

Wyld L., Reed M.W., Brown N.J. Diﬀerential cell death response to photodynamic therapy is dependent on dose and cell type, Br. J. Cancer., 2001, Vol. 84, pp. 1384-86

Филоненко Е.В. Флюоресцентная диагностика и фотодинамическая терапия – обоснование применения и возможности в онкологии // Biomedical Photonics. – 2014. – Т. 3, № 1. – С. 3-7.

Reed M., Miller F., Weiman T., Tseng M.T., Pietsch C.G. The eﬀect of photodynamic therapy on the microcirculation, J. Surg. Res., 1988, Vol. 45, pp. 452-9.

Wyld L., Reed M.W., Brown N.J. Differential cell death response to photodynamic therapy is dependent on dose and cell type // Br. J. Cancer. – 2001. – Vol. 84. – P. 1384-86.

Oleinick N., Morris R., Belichenko I. The role of apoptosis in response to photodynamic therapy: What, where, why and how, Photochem. Photobiol. Sci., 2002, Vol. 1, pp. 1-7.

Reed M., Miller F., Weiman T., et al. The effect of photodynamic therapy on the microcirculation // J. Surg. Res. – 1988. – Vol. 45. – P. 452-9.

Hayle A.K., Ward T.H., Moore J.V. DNA damage and repair in Gorlin syndrome and normal ﬁbroblasts aer aminolevulinic acid photodynamic therapy: a comet assay study, Photochem. Photobiol., 2003, Vol. 78, pp. 337-41.

Oleinick N., Morris R., Belichenko I. The role of apoptosis in response to photodynamic therapy: What, where, why and how // Photochem. Photobiol. Sci. – 2002. – Vol. 1. – P. 1-7.

McNair F.I., Marples B., West C.M., Moore J.V. A comet assay of DNA damage and repair in K562 cells aer photodynamic therapy using haematoporphyrin derivative, methylene blue and meso-tetrahydroxyphenylchlorin, Br J Cancer, 1997, Vol. 75, pp. 1721-9.

Hayle A.K., Ward T.H., Moore J.V. DNA damage and repair in Gorlin syndrome and normal fibroblasts aer aminolevulinic acid photodynamic therapy: a comet assay study // Photochem.

Woods J.A., Traynor N.J., Brancaleon L., Moseley H. The eﬀect of photo-frin on DNA strand breaks and base oxidation in HaCaT keratinocytes: a comet assay study, Photochem. Photobiol., 2004, Vol. 79, pp. 105-13.

Photobiol. – 2003. – Vol. 78. – P. 337-41.

McNair F.I., Marples B., West C.M., Moore J.V. A comet assay of DNA damage and repair in K562 cells aer photodynamic therapy using hematoporphyrin derivative, methylene blue and meso-tetrahydroxyphenylchlorin // Br J Cancer. – 1997. – Vol. 75. – P. 1721-9.

Woods J.A., Traynor N.J., Brancaleon L., Moseley H. The effect of photofrin on DNA strand breaks and base oxidation in HaCaT keratinocytes: a comet assay study // Photochem. Photobiol. – 2004. – Vol. 79. – P. 105-13.

The authors declare that there are no conflicts of interest present.