Ultraviolet-mediated antibiotic activity of thiophene compounds of Tagetes

Two intensely mauve UV fluorescent compounds isolated from Tagetes root were found to be phototoxic to Candida albicans. By chromatography on alumina followed by gel filtration on Sephadex LH-20, the compounds were identified as 5-(3-buten-1-ynyl)-2,2′-bithienyl and α-terthienyl.     

Phototoxic effects of fluorescent protein KillerRed on tumor cells in mice

KillerRed is known to be a unique red fluorescent protein displaying strong phototoxic properties. Its effectiveness has been shown previously for killing bacterial and cancer cells in vitro. Here, we investigated the photototoxicity of the protein on tumor xenografts in mice. HeLa Kyoto cell line stably expressing KillerRed in mitochondria and in fusion with histone H2B was used. Irradiation of the tumors with 593 nm laser led to photobleaching of KillerRed indicating photosensitization reaction and caused significant destruction of the cells and activation of apoptosis. The portion of the dystrophically changed cells increased from 9.9% to 63.7%, and the cells with apoptosis hallmarks from 6.3% to 14%. The results of this study suggest KillerRed as a potential genetically encoded photosensitizer for photodynamic therapy of cancer. (© 2013 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Cell damage and reactive oxygen species production induced by fluorescence microscopy: effect on mitosis and guidelines for non-invasive fluorescence microscopy

The green fluorescent protein (GFP) and other intrinsically fluorescent proteins (IFPs) are popular reporters because they allow visualization of cellular constituents in living specimens. IFP technology makes it possible to view dynamic processes in living cells, but extended observation, using fluorescence microscopy (both wide-field and confocal), can result in significant light energy exposure. Therefore, it is possible that cells experience light-induced damage that alters cell physiology and confounds observations. To understand the impact that extended viewing has on cells, we obtained quantitative information about the effect of light energy dose and observation conditions on tobacco BY-2 cell physiology. Our results show a non-linear relationship between the excitation light intensity and mitotic arrest, and the frequency of mitotic arrest is dependent on the presence of an IFP that absorbs the excitation light. Moreover, fluorescence microscopy induces the production of reactive oxygen species (ROS), as assayed using BY-2 cells loaded with oxidation-sensitive dyes, and the level of ROS production increases if the cells express an IFP that absorbs the excitation light energy. The dye oxidation follows sigmoidal kinetics and is reversible if the cells are exposed to low irradiation levels. In addition, the dye oxidation rate shows a non-linear relationship to the excitation light intensity, and a good correlation exists between photobleaching, mitotic arrest, and dye oxidation. The data highlight the importance of ROS scavenging for normal mitotic progression, and provide a reference for judiciously choosing conditions that avoid photobleaching that can lead to ROS accumulation and physiological damage.     

Solubilization and bio-conjugation of quantum dots and bacterial toxicity assays by growth curve and plate count

Quantum dots (QDs) are fluorescent semiconductor nanoparticles with size-dependent emission spectra that can be excited by a broad choice of wavelengths. QDs have attracted a lot of interest for imaging, diagnostics, and therapy due to their bright, stable fluorescence. QDs can be conjugated to a variety of bio-active molecules for binding to bacteria and mammalian cells. QDs are also being widely investigated as cytotoxic agents for targeted killing of bacteria. The emergence of multiply-resistant bacterial strains is rapidly becoming a public health crisis, particularly in the case of Gram negative pathogens. Because of the well-known antimicrobial effect of certain nanomaterials, especially Ag, there are hundreds of studies examining the toxicity of nanoparticles to bacteria. Bacterial studies have been performed with other types of semiconductor nanoparticles as well, especially TiO(2), but also ZnO and others including CuO. Some comparisons of bacterial strains have been performed in these studies, usually comparing a Gram negative strain with a Gram positive. With all of these particles, mechanisms of toxicity are attributed to oxidation: either the photogeneration of reactive oxygen species (ROS) by the particles or the direct release of metal ions that can cause oxidative toxicity. Even with these materials, results of different studies vary greatly. In some studies the Gram positive test strain is reportedly more sensitive than the Gram negative; in others it is the opposite. These studies have been well reviewed. In all nanoparticle studies, particle composition, size, surface chemistry, sample aging/breakdown, and wavelength, power, and duration of light exposure can all dramatically affect the results. In addition, synthesis byproducts and solvents must be considered. High-throughput screening techniques are needed to be able to develop effective new nanomedicine agents. CdTe QDs have anti-microbial effects alone or in combination with antibiotics. In a previous study, we showed that coupling of antibiotics to CdTe can increase toxicity to bacteria but decrease toxicity to mammalian cells, due to decreased production of reactive oxygen species from the conjugates. Although it is unlikely that cadmium-containing compounds will be approved for use in humans, such preparations could be used for disinfection of surfaces or sterilization of water. In this protocol, we give a straightforward approach to solubilizing CdTe QDs with mercaptopropionic acid (MPA). The QDs are ready to use within an hour. We then demonstrate coupling to an antimicrobial agent. The second part of the protocol demonstrates a 96-well bacterial inhibition assay using the conjugated and unconjugated QDs. The optical density is read over many hours, permitting the effects of QD addition and light exposure to be evaluated immediately as well as after a recovery period. We also illustrate a colony count for quantifying bacterial survival.     

Photodynamic effects of protoporphyrin on the cellular level—Anin vitro approach

Summary The purpose of this study was characterizing the phototoxic action of protoporphyrin and cellular protection mechanisms, as studied on the cellular level. In this process, active oxygen is involved. As a biological system, rat hepatocyte shortterm and primary cultures were used. Phototoxicity of protoporphyrin could be observed, after previous absorption of protoporphyrin to membrane structures. Damaging of several cell organelles occurred, such as mitochondria and lysosomes. Peroxisomes were not affected. Coated vesicles located at the periphery of the cells’ interior suggested that protoporphyrin absorption is mediated by an active uptake (endocytosis), as well as passive diffusion. Lipid peroxidation played a role in protoporphyrin photoxicity. Cellular protection mechanisms such as superoxide dismutase and the scavenger glutathione (GSH) protected the cells from active oxygen toxicity. In conclusion, protoporphyrin entered the cells by diffusion and endocytosis. Previous adsorption to the membrane structures was necessary for the expression of protoporphyrin phototoxicity. However, active oxygen itself could not be demonstrated. Lipid peroxidation was involved in cell-damaging processes. Mechanisms of protoporphyrin phototoxicity on the cellular level were studied. Rat hepatocyte primary and short-term cultures proved to be suitablein vitro systems for studying biochemical and morphological effects on the cellular level. This article is based on PhD research carried out at the Department of Veterinary Pharmacology, Pharmacy and Toxicology, Utrecht University, The Netherlands.     

Characterization of radicals arising from oxidation of commercially-important essential oils

Inappropriate use of essential oils may entail risks to human health due to mutational events, carcinogenic effects, genetic damages and sensitizing effect caused by generation of reactive oxygen species. In order to detect radicals that are expected to form during their oxidation, we measured the electron spin resonance (ESR) spectra of a standard reaction mixture (I) containing 25?μM flavin mononucleotide, 0.018% several essential oils (or 0.015% geraniol), 1.9 M acetonitrile, 20?mM phosphate buffer (pH 7.4), 0.1 M α-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN) and 1.0?mM FeSO₄(NH₄)₂SO₄ irradiated with 436?nm visible light (7.8 J/cm²). The ESR peak heights of the standard reaction mixture (I) of the essential oils increased in the following order: tea tree?>?palmarosa?>geranium?>?clary sage?>?petitgrain?>?lavender?>?bergamot?>?frankincense?>?ravintsara?>?ylang ylang?>?lemongrass?>?niaouli?>?eucalyptus globulus?>?peppermint. The ESR peak height of the standard reaction mixture (I) of geraniol, a main component of palmarosa, was comparable to the one of palmarosa (97?±?19% of palmarosa). Furthermore, high performance liquid chromatography (HPLC)-ESR analyses of the standard reaction mixture (I) of palmarosa and geraniol gave the same peaks. The results suggest that the radicals formed in the standard reaction mixture (I) of palmarosa are derived from geraniol. HPLC-ESR-mass spectrometry analyses detected m/z 294 ions, 4-POBN/5-hydroxy-3-methyl-3-pentenyl radical adducts and m/z 320 ions, 4-POBN/C₇O₂H₉ radical adducts in the standard reaction (I) of geraniol. The 5-hydroxy-3-methyl-3-pentenyl and C₇O₂H₉ radicals may be implicated in the sensitizing effect of palmarosa.     

Introns reduce transitivity proportionally to their length, suggesting that silencing spreads along the pre-mRNA

Endogenes rarely support transitive silencing, whereas most transgenes generally allow the spread of silencing to occur along the primary target. To determine whether the presence of introns might explain the difference, we investigated the influence of introns in the primary target on 3'–5' silencing transitivity. When present in a transgene, an intron-containing endogene fragment does not prohibit the spread of silencing across this fragment, indicating that introns do not preclude silencing transitivity along endogenes. Also, a multiple intron-containing genomic gene fragment that had previously been shown not to support transitivity in an endogenous context could support transitivity when present in a transgene. Nevertheless, genomic intron-containing fragments delayed the onset and diminished the efficiency of transitive silencing of a secondary target compared with the corresponding cDNA fragments. Remarkably, transitivity was impaired proportionally with the length of the pre-mRNA, and not of the mRNA. The latter result suggests that the RNA dependent RNA polymerase-based spreading of silencing progresses along the non-spliced rather than the fully processed mature mRNA.     

Photobleaching and phototoxicity of KillerRed in tumor spheroids induced by continuous wave and pulsed laser illumination

The purpose of this study was to evaluate photobleaching of the genetically encoded photosensitizer KillerRed in tumor spheroids upon pulsed and continuous wave (CW) laser irradiation and to analyze the mechanisms of cancer cell death after the treatment. We observed the light‐dose dependent mechanism of KillerRed photobleaching over a wide range of fluence rates. Loss of fluorescence was limited to 80% at light doses of 150 J/cm² and more. Based on the bleaching curves, six PDT regimes were applied for irradiation using CW and pulsed regimes at a power density of 160 mW/cm² and light doses of 140 J/cm², 170 J/cm² and 200 J/cm². Irradiation of KillerRed‐expressing spheroids in the pulsed mode (pulse duration 15 ns, pulse repetition rate 10 Hz) induced predominantly apoptotic cell death, while in the case of CW mode the cancer cells underwent necrosis. In general, these results improve our understanding of photobleaching mechanisms in GFP‐like proteins and show the importance of appropriate selection of treatment mode for PDT with KillerRed.

Representative fluorescence image of two KillerRed‐expressing spheroids before and immediately after CW irradiation.