A new pathway in the photoreaction cycle of trans-bacteriorhodopsin and the absorption spectra of its intermediates

The intermediates of trans-bacteriorhodopsin (trans-bR) in the photoreaction cycle were investigated under two different conditions. In a low salt and neutral pH medium (10 mM phosphate buffer, pH 6.6), trans-bR was irradiated with 500 nm light at –190 C, resulting in formation of batho-trans-bR (batho-bR^t). On warming in the dark, batho-bR^t converted to lumi-trans-bR (lumi-bR^t), meta-trans-bR (meta-bR^t) and finally to trans-bR. The intermediates N and O, which had been detected by others by flash photolysis, were not observed. The thermal decay of lumi-bR^t in a high salt and high pH medium (10 mM borate buffer with l M NaCl, pH 10.0) proceeded simultaneously through two pathways; one to meta-bR^t and another to trans-bR. About 72% of lumi-bR^t converted to trans-bR directly and the residue converted to meta-bR^t. By use of this value, the absorption spectra of batho-bR^t (_max: 626 nm), lumi-bR^t (_max: 543 nm) and meta-bR^t (_max: 418 nm) were calculated. A photoreaction cycle of bacteriorhodopsin was proposed on the basis of the above findings.     

Intramolecular photoredox reactions of 1,2-naphthoquinone derivatives

Photoirraditation of substituted 1,2-naphthoquinones gives the corresponding oxacycle via intramolecular redox reaction, which enabled net CH functionalization of the proximal position to the excited carbonyl group of the quinones. The substrate scope and mechanistic insights are described.     

Photoreaction of indole-containing mycotoxins to fluorescent products

Photochemical reaction of the non-fluorescent mycotoxin cyclopiazonic acid (CPA) to fluorescent products was recently reported. Because CPA contains an indole moiety, believed to contribute to the fluorescence, it was of interest to determine whether the effect might be more generally applicable to indole-containing mycotoxins. Three indole-containing tremorgens (penitrem A, paxilline, verruculogen) that have not previously been reported to be fluorescent were rendered fluorescent by exposure to ultraviolet light in a photoreactor. Naturally fluorescent ergot alkaloids, which also contain an indole-moiety, exhibited a diminished response after exposure. This suggests that the phenomenon may be most useful for detection of indole-containing tremorgens that are non-fluorescent, rather than for the enhancement of materials that are already fluorescent, such as the ergot alkaloids. The extent to which fluorescence enhancement was seen was strongly influenced by the reaction environment, in particular the solvent used and whether cyclodextrins were present. In an HPLC format, placement of the photoreactor post-column allowed for the fluorescence detection of penitrem A, paxilline, and verruculogen. The ability to photoreact indole-containing tremorgens and detect them by fluorescence may open up new avenues for detection of these mycotoxins alone or in combination.     

Thermal reversibility and bistability in photochromic diarylethenes

An account is given of the research work in progress in the authors’ laboratory on the photochromic behaviour (photocyclization) of diarylethenes structurally constrained to the cis geometry. Depending on the aromaticity of the aryl groups, the photoreaction can be thermoreversible, photoreversible or both. Examples of different photochromic behaviours of two series of photochromic diarylethenes (dipyrrolylperfluorocyclopentenes, which are thermally and photochemically reversible, and dithienyldithiolthiones, which are thermally stable and photoreversible) are investigated here by steady state and time-resolved spectroscopy to obtain information about their photochemistry and the competitive relaxation paths of their electronically excited states.     

Method to overcome photoreaction,a serious drawback to the use of dichlorofluorescin in evaluation of reactive oxygen species

Non-fluorescent dichlorofluorescin (DCFH) was converted to fluorescent products by photo-irradiation during observations with spectrofluorometer and fluorescence microscopy. Photo-irradiation of DCFH at 250, 300, 330, 400, 500, or 600 nm generated fluorescent dichlorofluorescein (DCF), an oxidation product of DCFH, and an unrecognized fluorescent product. The ratio of the unknown product to DCF varied from 0.15 to 8.21 depending on wavelength. Although reactive oxygen species scavengers, such as catalase, superoxide dismutase, and sodium azide, did not suppress the increase in non-specified fluorescence, reagents such as ascorbic acid, mercaptopropionyl glycine, and methoxycinnamic acid, in a cell-free system, almost completely suppressed it with little effect on the fluorescence of DCF. Meanwhile, ascorbic acid also suppressed non-specified fluorescence in cells, but not completely. At low concentrations of DCFH, the speed of increasing fluorescence was considerably retarded, to such a degree that the fluorescence increase in cells during fluorescence microscopic observation was negligible. The addition, at the time of evaluation, of the above reagents to cell-free systems and, in cell systems, reducing the concentration of DCFH, effectively suppressed the photoreaction of DCFH.     

Fabrication of a cell-adhesive protein imprinting surface with an artificial cell membrane structure for cell capturing

We proposed a new molecular imprinting procedure based on molecular integration for the purpose of cell capture. We selected the cell-adhesive protein fibronectin (FN) as the imprinting protein for preparing templates and evaluated selective cell adhesion on the FN imprinting substrate. Silica beads with a diameter of 15 μm were used as the stamp matrix and FN molecules were adsorbed as a monolayer. The FN recognition sites were constructed by integrating a surfactant as the ligand and immobilizing it with new biocompatible photoreactive phospholipid polymer composed of 2-methacryloyloxyethyl phosphorylcholine (MPC) units. As control substrates, imprinting procedures were carried out using albumin (BSA imprinting substrate) and without imprinting protein (non-imprinting substrate). The binding of FN from the cell culture medium with the fetal calf serum was achieved on the FN imprinting substrate, and induced the cell adhesion. On the other hand, on the non-imprinted and BSA imprinting substrates, the FN scarcely bound from the cell culture medium, and subsequent cell adhesion could not be observed on the substrate. These results indicate that the FN binding sites were well constructed by arranging the ligand surfactant to a suitable position and immobilized by the photoreactive MPC polymer. The MPC polymer prevented the nonspecific adsorption of proteins from the cell culture medium. We concluded that this procedure is convenient and can be potentially used for the preparation of surfaces for cell engineering devices.     

Effects of chloride on the absorption spectrum and photoreactions of halorhodopsin

The absorption maximum of halorhodopsin in a membrane fraction prepared from the cells of Halobacterium halobium under low-salt conditions shifted to longer wavelenghts upon addition of NaCl (Ogurusu, T., Maeda, A., Sasaki, N. and Yoshizawa, T. (1981) J. Biochem. (Tokyo) 90, 1267–1273). This bathochromic shift was due to chloride, not sodium. Bromide and iodide were also effective. The bathochromic shift of the absorption maximum was not accompanied by any change in the isomer composition of retinal in halorhodopsin. The same ionic species were essential for the formation of the hypsochromic photoproduct at −75°C. These effects of NaCl on halorhodopsin are discussed in terms of the presence of the two forms of halorhodopsin, a form binding chloride and a chloride-free form.     

Further characterization of the photoreaction center from Ectothiorhodospira sp. detection of the H subunit by monoclonal antibodies

Abstract The photoreaction center isolated from Ectothiorhodospira sp. is known to contain polypeptides L,M and C (a four heme c cytochrome) in a 1:1:1 molar ratio. As a test for the presence of a H subunit, Western blots of the chromatophore and photoreaction center polypeptides were reacted with a monoclonal antibody directed against the H subunit of Rhodospirillum rubrum . The chromatophores but not the isolated photoreaction center cross-reacted with this antibody. It is concluded that the H polypeptide is lost during the purification of the photoreaction center which, in its native state, therefore contains four polypeptides including a genuine H subunit.