Shea C R, Olack G A, Morrison H, Chen N, Hasan T
Division of Dermatopathology, New York Hospital, Cornell University Medical College, New York.
J Invest Dermatol. 1993 Sep;101(3):329-33. doi: 10.1111/1523-1747.ep12365484.
Doxycycline (DOTC) is a photosensitizing drug whose mechanism of phototoxicity is complicated by the large variety of stable photoproducts formed. To assess the role of a DOTC photoproduct, lumidoxycycline (LuDOTC), in the photosensitization mechanism of DOTC, MGH-U1 human bladder carcinoma cells were treated in vitro with either DOTC or LuDOTC, and irradiated with the 351-nm emission of an argon-ion laser. Both DOTC and LuDOTC were phototoxic and caused radiant-exposure-dependent inhibition of cellular incorporation of tritiated thymidine. On an absorbed-photon basis, DOTC was about five times as phototoxic as LuDOTC. Cellular uptake of DOTC was about five times as great as that of LuDOTC. Epifluorescence microscopy showed localization of LuDOTC predominantly within cellular membranes, particularly of mitochondria, as well as a low level of LuDOTC fluorescence diffusely within the cytoplasm. Epifluorescence microscopy of cells labeled with the mitochondrial probe, rhodamine 123, showed mitochondrial fragmentation and altered mitochondrial membrane integrity after LuDOTC photosensitization; these effects depended on radiant exposure and were partially reversible by 24 h after irradiation. For both DOTC and LuDOTC, phototoxicity was increased by irradiation in the presence of deuterium oxide and decreased in the presence of sodium azide, effects consistent with an important mechanistic role for singlet oxygen, O2(1 delta g), in the injury. In solution, LuDOTC and DOTC had similar quantum yields for generation of O2(1 delta g) as measured by time-resolved spectroscopy and by O2(1 delta g) trapping. LuDOTC was photostable in solution, but DOTC underwent significant photodegradation. These data demonstrate that DOTC photo-products such as LuDOTC have significant photobiologic activity and may play an important role in the phototoxicity mechanism of DOTC.
强力霉素(DOTC)是一种光敏药物,其光毒性机制因形成的多种稳定光产物而变得复杂。为了评估强力霉素光产物鲁米多西环素(LuDOTC)在强力霉素光敏化机制中的作用,对MGH-U1人膀胱癌细胞进行体外处理,分别用强力霉素或鲁米多西环素处理,并用氩离子激光351纳米的发射光进行照射。强力霉素和鲁米多西环素均具有光毒性,并导致氚标记胸腺嘧啶核苷的细胞掺入受到辐射剂量依赖性抑制。以吸收光子为基础,强力霉素的光毒性约为鲁米多西环素的五倍。强力霉素的细胞摄取量约为鲁米多西环素的五倍。落射荧光显微镜显示,鲁米多西环素主要定位于细胞膜内,尤其是线粒体内膜,同时在细胞质中有低水平的鲁米多西环素荧光扩散。用线粒体探针罗丹明123标记的细胞的落射荧光显微镜显示,鲁米多西环素光敏化后线粒体发生碎片化,线粒体膜完整性改变;这些效应取决于辐射剂量,并且在照射后24小时部分可逆。对于强力霉素和鲁米多西环素,在氧化氘存在下照射会增加光毒性,而在叠氮化钠存在下则会降低光毒性,这些效应与单线态氧O2(1Δg)在损伤中的重要机制作用一致。在溶液中,通过时间分辨光谱法和O2(1Δg)捕获法测量,鲁米多西环素和强力霉素产生O2(1Δg)的量子产率相似。鲁米多西环素在溶液中光稳定,但强力霉素会发生显著的光降解。这些数据表明,诸如鲁米多西环素之类的强力霉素光产物具有显著的光生物学活性,并且可能在强力霉素的光毒性机制中发挥重要作用。
