Photosensitizing proteins for antibacterial photodynamic inactivation

Translational biophotonics Pub Date : 2020-02-26 DOI:10.1002/tbio.201900031

Cormac Hally, Pietro Delcanale, S. Nonell, C. Viappiani, S. Abbruzzetti

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引用次数: 15

Abstract

We review recent applications of water-soluble proteins as carriers for photosensitizing molecules in antimicrobial photodynamic therapy (aPDT). The low water solubility of photosensitizers and their tendency to aggregate often impair their photophysics, thus resulting in lower bioavailability of the compounds. Taking advantage of the spontaneous interaction between water soluble proteins endowed with hydrophobic cavities and the otherwise insoluble photosensitizing compounds, it is possible to obtain efficient delivery systems to be applied inaPDT. These self-assembled structures are endowed with good photosensitizing and fluorescence emission properties (comparable to those of monomerized photosensitizers) with high biocompatibility and warrant good bioavailability of the photoactive drug. The proteins used so far comprise serum albumins, β -lactoglobulin, and apomyoglobin, while photosensitizers considered up to now have been hypericin, curcumin, Zn-protoporphyrin IX, and Zn-phthalocyanine. Furthermore, mutants of fluorescent proteins derived from GFP-like systems or from flavin binding proteins complete the array of available photosensitizing proteins for aPDT.

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用于抗菌光动力失活的光敏蛋白

本文综述了近年来水溶性蛋白作为光敏分子载体在抗菌光动力治疗(aPDT)中的应用。光敏剂的低水溶性及其聚集倾向往往损害其光物理特性，从而导致化合物的生物利用度降低。利用具有疏水空腔的水溶性蛋白与其他不溶性光敏化合物之间的自发相互作用，可以获得用于apdt的有效递送系统。这些自组装结构具有良好的光敏性和荧光发射特性(可与单体光敏剂相媲美)，具有较高的生物相容性，保证了光活性药物的良好生物利用度。迄今为止使用的蛋白质包括血清白蛋白、β -乳球蛋白和无肌红蛋白，而目前考虑的光敏剂有金丝桃素、姜黄素、zn -原卟啉IX和zn -酞菁。此外，来自gfp样系统或黄素结合蛋白的荧光蛋白突变体完成了可用的aPDT光敏蛋白阵列。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Translational biophotonics

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审稿时长

15 weeks