Synthesis and biological evaluation of glucose conjugated phthalocyanine as a second-generation photosensitizer

Photodynamic therapy (PDT) is a treatment method using light and photosensitizers (PSs), which is categorized as a non-invasive surgery treatment for cancers. When the tumor is exposed to a specific light, the PSs become active and generate reactive oxygen species (ROS), mainly singlet oxygen which kills nearby cancer cells. PDT is becoming more widely recognized as a valuable treatment option for localized cancers and pre-cancers of skin as it has no long-term effects on the patient. But, due to the limited penetration rate of light into the skin and other organs, PDT can’t be used to treat large cancer cells or cancer cells that have grown deeply into the skin or other organs. Hence, in this study, our focus centers on synthesizing glucose-conjugated phthalocyanine (Pc) compatible with near-infrared (NIR) irradiation as second-generation photosensitizer, so that PDT can be used in a wider range to treat cancers without obstacles.     

Evaluation of photodynamic treatment using aluminum phthalocyanine tetrasulfonate chloride as a photosensitizer: new approach

Photodynamic therapy (PDT) has been the subject of several clinical studies. Evidence to date suggests that direct cell death may involve apoptosis. T(24) cells (bladder cancer cells, ATCC-Nr. HTB-4) were subjected to PDT with aluminum phthalocyanine tetrasulfonate chloride (AlS(4)Pc-Cl) and red laser light at 670 nm. Morphological changes after PDT were visualized under confocal microscopy. Raman microspectroscopy is considered as one of the newly established methods used for the detection of cytochrome c as an apoptotic marker. Results showed that PDT treated T(24) cells seem to undergo apoptosis after irradiation with 3 J cm(-2). Cytochrome c could not be detected from cells incubated with AlS(4)Pc-Cl using Raman spectroscopy whereas AlS(4)Pc-Cl seems to interfere with the Raman spectrum of cytochrome c.     

Studies on the photochemical and photocytotoxic properties of the new PDT photosensitizer aluminum sulfonated phthalocyanine.

The properties of photosensitization of sulfonated aluminum phthalocyanine (ALSPC), a new photosensitizer of potential use in cancer photodynamic therapy (PDT) was studied on both the molecular and cellular levels. The mechanism of ALSPC photosensitization on the molecular level was investigated by testing its efficiency of singlet oxygen (1O2) production, using the method of tryptophan degradation and that of ESR spectroscopy and observing the enhancing effect of D2O and the quenching effect of NaN3. Results of all these experiments confirmed the important role of the Type II or 1O2 mechanism in ALSPC photosensitization. In our in-vitro experiments, ALSPC's incorporation into cells and its photocytotoxic effect were investigated on a human liver cancer cell line. The cell incorporation was illustrated by the laser-excited fluorescence spectra emitted both from cell homogenate and cell monolayers incubated with ALSPC aqueous solution. The position of fluorescence peak observed, implied that ALSPC exists in the cells mainly as monomers. The efficiency of cell killing of ALSPC photosensitization was estimated by counting surviving cells with the method of trypan blue staining and by the method of radioisotope labelling. Experiments using the latter method also showed DNA damage caused by ALSPC photosensitization.     

Zinc-(II) 2,9,16,23-tetrakis (methoxy) phthalocyanine: potential photosensitizer for use in photodynamic therapy in vitro

Photodynamic therapy (PDT) is an innovative treatment for several types of malignant and non-malignant disease. In the present study, ZnPcOCH(3) was investigated on a human larynx-carcinoma cell line (Hep-2) for its use in PDT. This drug exhibited favourable properties as a photosensitizer in vitro because ZnPcOCH(3) is able to penetrate efficiently in the cytoplasm of cultured cancer cells and is partially localized in lysosomes. The results show that ZnPcOCH(3)-PDT-induced apoptosis by caspase dependent pathway. The new compound shows a good photosensitizing efficiency in vitro on Hep-2 cells, encouraging further in vivo studies.     

Optimization of the photodynamic inactivation of prions by a phthalocyanine photosensitizer: The crucial involvement of singlet oxygen

Prion disorders are fatal neurodegenerative diseases caused by the autocatalytic conversion of a natively occurring prion protein (PrP^C) into its misfolded infectious form (PrP^TSE). The proven resistance of PrP^TSE to common disinfection procedures increases the risk of prion transmission in medical settings. Herein, we present the effective photodynamic inactivation (PDI) of prions by disulfonated hydroxyaluminum phthalocyanine (AlPcOH(SO₃)₂) utilizing two custom‐built red light sources. The treatment eliminates PrP^TSE signal in infectious mouse brain homogenate with efficiency that depends on light intensity but has a low effect on the overall protein content. Importantly, singlet oxygen (O₂(¹Δ_g)) is the only species significantly photogenerated by AlPcOH(SO₃)₂, and it is responsible for the PDI of prions. More intensive light conditions show not only higher O₂(¹Δ_g) production but also decreases in AlPcOH(SO₃)₂ photostability. Our findings suggest that PDI by AlPcOH(SO₃)₂‐generated O₂(¹Δ_g) represents a promising approach for prion inactivation that may be useful in future decontamination strategies for delicate medical tools.     

Cellular inactivation and antitumor efficacy of a new zinc phthalocyanine with potential use in photodynamic therapy

The aim of the present study was to evaluate the photodynamic efficacy of a novel phthalocyanine derivate 2,3,9,10,16,17,23,24-octakis[(N,N-dimethylamino) ethylsulfanyl]phthalocyaninatozinc(II) (referred here as S1) using MCF-7c3 human breast cancer cells and the LM2 adenocarcinoma subcutaneously implanted in Balb/c mice as experimental models. The S1-l-alpha-dimyristoyl-phosphatidylcholine liposome was selected as the best delivery system because it showed greater internalization into cells (35 nmol/10(6) cells), relative to other liposomes. After 3 h incubation S1 was partially localized in lysosomes, the compartment that represented its primary photodamage site. The S1 treated cultures also revealed a degree of mitochondrial morphology alteration. Indeed, S1 leads to photokilling of the cells with different efficacies indicating that cell photoinactivation was dependent on both the phthalocyanine concentration and the light dose applied. Analyses of morphology and nuclear condensation level indicated that some of the cells exposed to photodynamic therapy were undergoing apoptosis within 8h after treatment. To assess the in vivo effectiveness of S1, animals bearing tumors were treated with 0.2mg/kg S1 followed 24h later by 108 J cm(-2) light at 600-800 nm and 60 mW cm(-2),while other animals served as controls (no treatment, light alone, or S1 alone). All S1 treated tumors and none of the controls exhibited complete or partial responses, and these responses continued for the entire observation period of 12 days. Evaluation of tumor size showed that the treatment effectively delayed tumor growth. Light microscopy investigations of irradiated tumor specimens showed that S1 causes an early direct damage of malignant cells, largely via processes leading to random necrotic pathways.     

A novel photosensitizer for light-controlled gene silencing

We here demonstrate for the first time that 5-carboxytetramethylrhodamine (TAMRA) covalently linked to nuclear localization signal (NLS)-conjugated peptide nucleic acids (PNAs) are photosensitizers (PSs) with the capacity to initiate photochemical damage to endocytic membranes, resulting in release of endocytosed material into cytosol. Our results show that TAMRA/PNA/NLS conjugates work as multifunctional molecules by offering cellular uptake, PNA-directed gene silencing, and the possibility for targeting in a light-controlled manner. In addition to PNA-directed gene silencing, we demonstrate that TAMRA/PNA/NLS molecules may function as a PS for light-controlled release of small interfering RNA molecules from the endocytic pathway when combined with an appropriate carrier. Using these strategies, we could silence the S100A4 gene at both protein and mRNA levels in a light-controlled manner, without any detectable reduction in cell viability. Our data demonstrate the possibility for light-controlled delivery of macromolecules entrapped within endocytic vesicles using multifunctional TAMRA/PNA/NLS molecules as PSs.     

Strategies for improving antitumor activity utilizing IL-2: Preclinical models and analysis of antitumor activity of lymphocytes from patients receiving IL-2

Conclusions Considerable enthusiasm remains for the successful utilization of the immune system for the immunotherapy of human cancers. Immunotherapeutic maneuvers have been able to mediate impressive antitumor responses for some patients with advanced and refractory malignancies. Unfortunately, the number of patients who benefit from current immunotherapies is low, while the toxicity for many of the patients receiving these treatments is high. It is becoming quite clear that the development of successful immunotherapeutic strategies will involve a carefully chosen combination of immunotherapeutic modalities or of immunotherapy combined with either surgery, radiation therapy, or chemotherapy. The use of an IL-2 based regimen which is clinically tolerable and can provide significant immune activation continues to remain central to many of these treatment approaches. Preclinicalin vitro and animal model systems can evaluate promising treatment strategies, including combination approaches. As an effective immunotherapeutic approach will likely require use of a combination of biologically active agents, the scheduling of these therapies may have profound importance both for optimal antitumor responses as well as clinical tolerance.     

Photodynamic therapy of cancer: Search for ideal photosensitizer

Photodynamic therapy (PDT) is a minimally invasive and promising new modality to combat cancer. The method is based on selective accumulation of sensitizers in tumor cells. The high degree of selectivity offered by this modality has been applied for fluorescent diagnostics of cancer. Photosensitization of a tissue-localized sensitizer in the presence of oxygen generates cytotoxic reactive oxygen species results in the selective destruction of tumor. The PDT’s major advantages compared to traditional methods of cancer treatment are better selectivity, and low toxicity of administered drugs. This review highlights basic principles of this method, mechanisms underlying damage of tumor tissue and first and second generations of sensitizers. Future developments in PDT will include the development of new methods of treatment and diagnostics of tumor diseases.     

Flavoprotein miniSOG as a genetically encoded photosensitizer for cancer cells

Background

Genetically encoded photosensitizers are a promising optogenetic instrument for light-induced production of reactive oxygen species in desired locations within cells in vitro or whole body in vivo. Only two such photosensitizers are currently known, GFP-like protein KillerRed and FMN-binding protein miniSOG. In this work we studied phototoxic effects of miniSOG in cancer cells.

Methods

HeLa Kyoto cell lines stably expressing miniSOG in different localizations, namely, plasma membrane, mitochondria or chromatin (fused with histone H2B) were created. Phototoxicity of miniSOG was tested on the cells in vitro and tumor xenografts in vivo.

Results

Blue light induced pronounced cell death in all three cell lines in a dose-dependent manner. Caspase 3 activation was characteristic of illuminated cells with mitochondria- and chromatin-localized miniSOG, but not with miniSOG in the plasma membrane. In addition, H2B-miniSOG-expressing cells demonstrated light-induced activation of DNA repair machinery, which indicates massive damage of genomic DNA. In contrast to these in vitro data, no detectable phototoxicity was observed on tumor xenografts with HeLa Kyoto cell lines expressing mitochondria- or chromatin-localized miniSOG.

Conclusions

miniSOG is an excellent genetically encoded photosensitizer for mammalian cells in vitro, but it is inferior to KillerRed in the HeLa tumor.

General significance

This is the first study to assess phototoxicity of miniSOG in cancer cells. The results suggest an effective ontogenetic tool and may be of interest for molecular and cell biology and biomedical applications.     

Hydogen peroxide-dependent photocytotoxicity by phloxine B,a xanthene-type food colorant

Background

Phloxine B (PhB; 2′,4′,5′,7′-tetrabromo-4,5,6,7-tetrachloro-fluorescein), an artificial xanthene colorant, has been used as a red coloring agent in drugs and cosmetics as well as foods in some countries. However, little effort has been devoted to the study of this colorant as a potentially useful medicinal agent.

Methods

We investigated the daily light-induced photocytotoxicity of PhB in two human leukemia cells, HL-60 and Jurkat, and its underlying mechanisms by in vitro experiments using antioxidants.

Reuslts and conclusions

PhB inhibited cell proliferation more preferentially to HL-60 cells than to Jurkat cells. Co-treatment of catalase completely blocked the photocytotoxicity by PhB in HL-60 cells, whereas the effect of histidine was only partial, suggesting that hydrogen peroxide (H₂O₂), rather than singlet oxygen, might be a prerequisite for the PhB-induced HL-60 cell death. Actually, PhB produced a significant amount of H₂O₂ in the media as well as in the cells in concentration- and light-dependent manners. Furthermore, methionine, a hypochlorous acid (HOCl) scavenger, also significantly attenuated the cytotoxicity in HL-60 cells, but not in Jurkat cells, indicating the involvement of myeloperoxidase (MPO)-dependent hypohalous acid formation during the photocytotoxicity. In vitro experiments revealed that halogenated tyrosine was generated from the reaction of bovine serum albumin with PhB and HL-60 cell lysate. The present findings suggested that PhB induced a differential photodynamic action in the MPO-containing leukemia cells through an H₂O₂-dependent mechanism.

General significance

Our findings provide new insights into the molecular mechanisms underlying the PhB-induced apoptosis and also evaluated PhB as a promising PDT agent.     

藻红蛋白光敏剂研究进展

光动力学治疗法作为一种新的肿瘤治疗方法,近年来发展十分迅速。从红藻中提取的藻红蛋白可以作为光动力学治疗法的一种新的光敏剂。本概述了我国红藻藻红蛋白资源概况、光疗法和光敏剂作用机理及其研究发展历史与现状,重点阐述了藻红蛋白光敏剂的应用现状、前景和发展趋势,并认为藻红蛋白是光动力学治疗法中一种非常有前景的光敏剂。藻红蛋白在490nm有吸收光谱,而发射光谱位于560nm;藻红蛋白能特异性地聚集在肿瘤细胞周围,吸收周围环境光能并传递给氧分子,使氧分子转化为具有强氧化性的多线态氧,从而可以大量杀死肿瘤细胞。     

Nebulization as a tool for photosensitizer delivery to the respiratory tract

To this day, any photosensitizers for the photodynamic treatment of pulmonary illnesses have been administered intravenously. There is, however, an intrinsic difficulty in reaching the target cells or bacteria in the respiratory system. Nebulization could overcome distribution problems and alleviate side effects by delivering the photosensitizers directly to the lungs. In this study, we evaluated the viability of three photosensitizers (indocyanine green, the chlorine Photodithazine, and the porphyrin Photogem) was evaluated comparatively in a jet nebulizer. Quantitative analysis was performed by looking at the droplet size, extent of nebulization, output over time and stability of the solutions. All of the tested photosensitizers were found to be adequately nebulized. We also demonstrated the delivery of indocyanine green to the pulmonary tract and its activation with infrared light in a murine model using extracorporeal detection of fluorescence. This was an important step toward clinical implementation of the extracorporeally illuminated photodynamic inactivation of pneumonia, recently demonstrated in vivo by this research group.      

Inside Cover: Optimization of the photodynamic inactivation of prions by a phthalocyanine photosensitizer: The crucial involvement of singlet oxygen (J. Biophotonics 8/2019)

Photodynamic inactivation of prions by disulfonated hydroxyaluminum phthalocyanine. Further details can be found in the article by Marie Kostelanska, Jaroslav Freisleben, Zdenka Backovska Hanusova, et al. ( e201800430 ).

     

Butylcycloheptylprodigiosin and undecylprodigiosin are potential photosensitizer candidates for photodynamic cancer therapy

Molecular Biology Reports - Prodiginines are bacterial red polypyrrole pigments and multifaceted secondary metabolites. These agents have anti-proliferative, immunosuppressive, antimicrobial, and...     

A novel approach to a bifunctional photosensitizer for tumor imaging and phototherapy

Optical imaging has attracted a great attention for studying molecular recognitions because minute fluorescent tracers can be detected in homogeneous and heterogeneous media with existing laboratory instruments. In our preliminary study, a clinically relevant photosensitizer (HPPH, a chlorophyll-a analog) was linked with a cyanine dye (with required photophysical characteristics but limited tumor selectivity), and the resulting conjugate was found to be an efficient tumor imaging (fluorescence imaging) and photosensitizing agent. Compared to HPPH, the presence of the cyanine dye moiety in the conjugate produced a significantly higher uptake in tumor than skin. At a therapeutic/imaging dose, the conjugate did not show any significant skin phototoxicity, a major drawback associated with most of the porphyrin-based photosensitizers. These results suggest that tumor-avid porphyrin-based compounds can be used as "vehicles" to deliver the desired fluorescent agent(s) to tumor. The development of tumor imaging or improved photodynamic therapy agent(s) by itself represents an important step, but a dual function agent (fluorescence imaging and photodynamic therapy) provides the potential for tumor detection and targeted photodynamic therapy, combining two modalities into a single cost-effective "see and treat" approach.     

Synthesis,G-quadruplexes DNA binding,and photocytotoxicity of novel cationic expanded porphyrins

Intensive reports allowed the conclusion that molecules with extended aromatic surfaces always do good jobs in the DNA interactions. Inspired by the previous successful researches, herein, we designed a series of cationic porphyrins with expanded planar substituents, and evaluated their binding behaviors to G-quadruplex DNA using the combination of surface-enhanced raman, circular dichroism, absorption spectroscopy and fluorescence resonance energy transfer melting assays. Asymmetrical tetracationic porphyrin with one phenyl-4-N-methyl-4-pyridyl group and three N-methyl-4-pyridyl groups exhibit the best G4-DNA binding affinities among all the designed compounds, suggesting that the bulk of the substituents should be matched to the width of the grooves they putatively lie in. Theoretical calculations applying the density functional theory have been carried out and explain the binding properties of these porphyrins reasonably. Meanwhile, these porphyrins were proved to be potential photochemotherapeutic agents since they have photocytotoxic activities against both myeloma cell (Ag8.653) and gliomas cell (U251) lines.     

Synthesis, spectral properties, and antitumor activity of a new axially substituted phthalocyanine complex of zirconium(IV) with citric acid

The new axially substituted phthalocyanine (pc) complex of zirconium(IV) with citric acid is reported. It has been shown that the replacement of two Cl-atoms with two citric acid fragments takes place as the result of the reaction between [ZrCl2(pc)] and citric acid. The complex [Zr(citrate)2(pc)] was formed. The spectroscopic properties of the synthesized compound in DMSO, RPMI 1640 medium with and without fetal calf serum (FCS), H2O, and buffer (Tris) solutions have been described. Antitumor activity of this compound has been studied. The cytostatic activity was observed in the concentration range of 6.1-9.0x10(9) molecules [Zr(citrate)2(pc)]/cell and occurred in 4-6 h after treatment with [Zr(citrate)2(pc)] solution.     

Asymmetrical,water-soluble phthalocyanine dyes for covalent labeling of oligonucleotides

Two new water-soluble, porphyrazine (Pz) dyes containing an isothiocyanate function for covalent linking have each been prepared by cross condensation of two different aromatic dinitriles, one containing carboxylates for solubilizing purposes and the other containing a nitro group for conversion into the labeling function. The initial mononitrotricarboxylato Pzs have been purified to homogeneity from the mixture of Pz congeners formed in the condensation reaction by anion exchange chromatography. The phthalocyanine dye 1 has an absorption maxima at 683 nm while the trinaphthoporphyrazine dye 2 has an absorption maxima at 755 nm, due to the increased size of the aromatic system. Both dyes were successfully conjugated to oligonucleotide primers, showing their potential for use in near-infrared-based DNA diagnostic applications.