TRANSIENT PHENOMENA IN THE PULSE RADIOLYSIS OF RETINYL POLYENES—7. RADICAL ANIONS OF VITAMIN A AND ITS DERIVATIVES

Abstract— Upon e^--pulse irradiation in nonprotic solvents, all- trans retinol (ROH) and retinylmethyl ether (ROMe) form transient species (τ= 0.5–7μs, λ_max=575–590 nm) identifiable as radical anions. Similar species are also formed upon laser pulse photoexcitation of these retinyl derivatives in the presence of N,N-dimethylaniline in acetonitrile. In contrast, electron transfer or attachment to all- trans retinyl acetate (ROAc) and palmitate (ROPa) results in 'instantaneous' loss of carboxylate anions from electron adducts giving the retinylmethyl radical (R-, λ_max= 395 nm, τ_k > 100 μ,s); the radical anions in these cases are too short-lived to be detected by nanosecond pulse radiolysis. The lifetimes of radical anions of ROH and ROMe are very sensitive to water and alcohols (e.g. k_q = 10⁷ M ^-1 s^-1 with methanol as quencher for ROH^- in tetrahydrofuran). Based on these findings, the spectral dissimilarity of the one-electron reduction products from ROH and ROAc in alcohols and aqueous micelles becomes explainable in terms of fast formation of protonated radical anions (RH(OH), τ_1/2, > 100 μs, λ_max=370–375 nm) in the case of ROH and of retinylmethyl radical via loss of AcO^- from radical anion in the case of ROAc. In tetrahydrofuran, the complexation of ROH^- with cations such as Na⁺ and Bu₄N⁺ affects the relative importance of its major decay modes, namely, protonation and dehydroxylation, the latter process being significantly enhanced by the presence of Na⁺.     

SPECTROPHOTOMETRIC IDENTITY OF THE ENERGY TRANSFER CHROMOPHORES IN RENILLA AND AEQUOREA GREEN-FLUORESCENT PROTEINS

Abstract— Spectral properties of guanidine-denaturated and pronase-digested green-fluorescent proteins (GFP) from two species of bioluminescent coelenterates have been investigated. Spectrophotometric titrations of Renilla and Aequorea GFP, following denaturation in 6 M guanidine HCl at elevated temperature, revealed identical absorption peaks in acid (383–384 nm) and in alkali (447–448 nm) and a single isosbestic point in the visible region at 405 nm. Both proteins exhibited a spectrophotometric pK. of 8.1 in guanidine -HCl. Pronase digestion of the heat-denaturated GFP's generated a methanol-soluble blue-fluorescent peptide with identical fluorescence emission spectra (λ_max= 430 nm, uncorrected; φ_f1= 0.003) for both coelenterate species. These data suggest that the large absorption differences between native Renilla and Aequorea GFP molecules result from unique protein environments imported to a common chromophore.     

THE PHOTOPHYSICAL PROPERTIES OF SOME C15 LUPINE ALKALOIDS:

Abstract Sparteine, the tetracyclic saturated amine alkaloid, is highly fluorescent in n-hexane solution (Φ_f= 0.64; ζ= 63 ns) and has a large Stokes shift [λ_max (abs) = 203 nm; λ_max (fluor) = 325 nm]. Its isomer, α-isosparteine, has similar properties: Φ_f= 0.55; ζ_f= 50 ns; λ_max (fluor) = 338 nm. Oxidized derivatives, such as lupanine, thermopsine, and α-diplospartyrine, are weakly fluorescent. Based on a comparison with spectroscopic and photophysical properties of the monoamine, quinolizidine, it is concluded that the excitation energy is delocalized over the two N-atoms in starteine and a-isosparteine. The self quenching rate constant for sparteine, ca. 1 times 10⁷M^-1 s^-1, is about 100 times smaller than that for quinolizidine, consistent with excited state derealization. The significant fluorescence quenching in lupanine is rationalized by the fact that N-methyl-2-piperidone mfe/molecularly quenches the fluorescence of quinolizidine at nearly the diffusion controlled rate in -hexane. Comparisons are made with the fluorescence properties of other diamines such as N, N'-dimethylbispidine and N, N'-disubstituted piperazines.     

PHOTOCHEMISTRY OF RETINOCHROME

Abstract— Retinochrome is a photopigment found in the visual cells of cephalopods. It has been considered to act as a supplier of the 11- cis -retinal required for synthesis of rhodopsin, because its all-trans chromophore is isomerized to 11- cis form in the light. Light and thermal reactions of squid retinochrome were investigated by low-temperature spectrophotometry.
On irradiation with green light at liquid-nitrogen temperature, retinochrome (λ_max 496 nm, – 190°C) is converted mainly to an intermediate lumiretinochrome (λ_max 475 nm, – 190°C), its chromophore being changed to 11- cis -retinal. On irradiation with blue light at - 190°C, retinochrome is changed to a photosteady–state mixture (λ_max 487 nm, – 190°C) composed mainly of retinochrome and lumiretinochrome, since lumiretinochrome is partially regenerated back to retinochrome. Similarly, irradiation of lumiretinochrome with blue light also results in the same photosteady-state mixture, which can be completely reverted to lumiretinochrome on re-irradiation with green light.
Lumiretinochrome is stable at a wide range of temperatures from – 190°C to about – 20°C. Above – 20°C, it is further converted, thermally, into metaretinochrome (λ_max 470 nm), which is the same bleached product as has been observed on irradiation of retinochrome at room temperatures. Thus, the light-bleaching process of retinochrome is rather simple compared with that of rhodopsin.     

THE PHOTOCHEMICAL INTERACTION BETWEEN THE TRIPLET STATE OF 8-METHOXYPSORALEN AND THE MELANIN PRECURSORL–3, 4 DIHYDROXYPHENYLALANINE

Abstract— The photochemical interaction between 8-methoxypsoralen (8-MOP) and the melanin precursorL–3,4-dihydroxyphenylalanine(dopaH₂) has been studied using laser flash photolysis. Triplet excited 8-MOP was thus found to abstract electrons from dopaH₂ ( k ∼ 2 × 10⁹ dm³ mol^-1 s^-1) to form semireduced 8-MOP and semioxidised dopaH₂.The technique of pulse radiolysis was used to establish separately the spectra of (a) the semi-reduced form of 8-MOP at pH 6.5 and (b) the semioxidised forms of dopaH₂ at pH 6.5, 5.8, 4.6 and 3.3. The corresponding λ_max and extinction coefficients found were: for 8-MOP at pH 6.5, λ_max= 350 nm (= 9050 dm³ mol^-1 cm^-1); for dopa at pH 6.5, λ_max= 305 nm (ε= 12000 dm³ mol^-1 cm^-1) and for dopaH at pH 3.3, λ= 305 nm (ε= 5900 dm³ mol^-1 cm^-1).     

REFLECTANCE SPECTROSCOPY FOR THE CHARACTERIZATION OF PHOTOCHROMISM IN THE CRYSTALLINE STATE

Abstract— The Kubelka-Munk theory for diffuse reflectance has been applied to a quantitative study of photochromism in the crystalline state. For three systems investigated it was found possible to assign first order rate constants to the thermal relaxation process and estimate the pre-exponential factor A and the activation energy E_a in Arrhenius equation. For the fading of the red photocolored form, Λ_max=490 mμ, of benzaldehyde phenylhydrazone A = 1.4×10⁸ min^-1 and E_a= 15.7 kcal mole^-1. For the fading of the blue photocolored form, Λ_max=590 mμ, of 2–(2,4-dinitrobenzyl)pyridine A= 5×10¹⁴ min^-1 E_a =23.3 kcal mole^-1, Cinnamaldehyde semicarbazone showing 'reversed phototropy' has a photoactivated state, Λ_max=400 mμ, which in dark is transformed into a strongly absorbing yellow species, Λ_max= 430 mμ with A = 14 × 10¹⁰ min^-1 and E_a= 18.7 kcal mole-¹.     

PHOTOPRODUCTS OF CHLORPROMAZINE WHICH CAUSE RED BLOOD CELL LYSIS

A mechanism for chlorpromazine (CPZ) phototoxicity has been proposed that attributes the response to formation of stable, toxic photoproducts which cause cell membrane disruption. We have characterized these toxic photoproducts as dimers and higher multimers of CPZ. Chlorpromazine solutions (3 or 10 mA/) were irradiated with a medium pressure Hg lamp filtered to exclude λ < 280 nm. Five low mol wt photoproducts were separated by high performance liquid chromatography. Two were identified as CPZ-sulfoxide and promazine. Higher mol wt photoproducts were separated by Sephadex G-50 chromatography into 3 broad bands which were characterized by their absorption and fluorescence spectra. Band A (mol wt > 800) had λ_max^abs= 263 nm, λ_max^fl= 490 nm and Band B (mol wt = 350-800) had λ_max^abs= 255 nm, λ_max^fl= 450 nm. Based on the mol wt of CPZ, Band A contained trimers and higher mol wt compounds and Band B was composed of dimeric structures. BandC(λ_max^abs= 255,310 nm; λ_max^fl= 445 nm) was composed of CPZ (mol wt = 315) and the low mol wt photoproducts. Red blood cell lysis was used as an assay for the ability of photoproducts to cause membrane disruption. Bands A and B, but not Band C, caused cell lysis. These data indicate that the CPZ photoproducts which cause cell membrane disruption are dimers (Band B) and higher multimers (Band A).     

PHOTOCHROMISM OF 2,6-DINITRODIPHENYL ETHERS ENHANCED IN THE PRESENCE OF A HOST BIOMOLECULE*

Abstract— The photochromic behavior of 2,6-dinitrodiphenyl ethers is described. In the course of a study for the photoaffinity labeling of the binding site for thyroxine on human prealbumin, it was found that the thyroxine analog 3-[4-(4-hydroxy-3,5-diiodophenoxy)-3,5-dinitrophenyl]propionic acid (1), on irradiation with >350nm light in the presence of prealbumin, gave a pink species (λ_max 508 nm). In the absence of prealbumin, no color formation was observed. Irradiation of 3-[4-(4-hydroxyphenoxy-3,5-dinitrophenyl]propionic acid (2) and 3-(4-phenoxy-3,5-dinitrophenyl)propionic acid (3), analogs of 1, in acetonitrile, aqueous bicarbonate, or ethanol gave a colored species (λ_max 500–520 nm depending on the solvent) in the absence of a host molecule. In the presence of β-cyclodextrin, which may be considered a model for a binding site on a protein, photocoloration occurred at a faster rate than in the absence of ß-cyclodextrin. For both 2 and 3 , the colored species underwent thermal back reaction to the starting compound. The activation energy for the thermal back reaction was estimated to be about 40 kj/mol.     

POTENTIAL PHOTOSENSITIZERS FOR PHOTODYNAMIC THERAPY—II. PHOTOPHYSICAL PROPERTIES OF [26] PORPHYRIN

Abstract— –Photophysical properties of [26] porphyrin (26 P) were investigated in chloroform. The quantum yields of fluorescence, of S₁→ T₁ intersystem crossing and singlet oxygen formation were measured. The purity, stability, the strong absorption in the red (δ_max= 783 nm; ε_max= 28 000 M ¹ cm^-1) and the ability of singlet oxygen formation recommend 26 P as potential photosensitizer for tumor therapy.     

FLUORESCENCE DETECTION OF AN 8-METHOXYPSORALEN METABOLITE IN HUMAN INTERSTITIAL FLUID

Abstract— A fluorescent method has been used to study the suction blister fluid of human volunteers collected after 8-methoxypsoralen (8-MOP) oral intake. A fluorescent chromophore with spectral characteristics (Λ_max= 390 nm, Λ_max=470nm) distinct from 8-MOP has been detected. Our results suggest the existence of a metabolite form of 8-MOP within the patients's skin prior to any UV irradiation. This form might result in the opening of the4–5' double bond of the 8-MOP molecule.     

HALORHODOPSIN and PHOTOSENSORY BEHAVIOR IN Halobacterium halobium MUTANT STRAIN L-33

Halobacterium halobium , strain L-33, which is deficient in bacteriorhodopsin (BR) but synthesizes increased amounts of halorhodopsin (HR), shows behavioral responses upon changes in fluence rate with visible light or with UV light. The observations support the earlier report (Schimz et al. , 1982). that BR is not essential for photosensing in H. halobium. In the UV-range, changes in light intensity elicit the maximal response at λ= 370 nm. In the visible range, changes in light intensity show the maximal response at Δ= 565 nm and a secondary peak at Δ= 590 nm. The latter corresponds to the absorption maximum of HR (Δ_max= 588 nm). This light-energy converting retinal pigment of H. halobium thus appears to contribute to photosensory behavior.     

FLUORESCENCE SPECTRA OF BLOWFLY METAXANTHOPSINS

Abstract— The main visual pigment of blowflies (xanthopsin, Vogt, 1983 Z. Naturforsch. 38c ,329–333) photoconverts into two thermostable metaxanthopsin states M and M'(e.g. Stavenga et al. , 1984 Photochem. Photobiol. 40 ,653–659). The fluorescence spectra of the two photoproducts were studied by microspectrofluorometry in vivo. The emission spectra of M and M'are very similar and peak at 660 nm. The excitation spectra of M and M'have peak wavelengths at Λ_max ' 584 nm and = 568 nm respectively.     

FLUORESCENCE OF AZINES

Abstract— A comparison of the transient absorption spectra from the photolysis of disulfides in solution suggests that C-S bond breakage is a common primary photolytic process. This process becomes more important as the resulting carbon centered radical is stabilized by increasing alkyl substitution or resonance interaction with an aromatic system. The perthiyl radical product is characterized by λ_max∽380 nm,ε₃₈₀∽1700 M ⁻¹ cm⁻¹ and decays by second order kinetics with k ₂∽3.7×10⁸ M ⁻¹ s⁻¹ in water.
In the presence of O₂, the photolysis of disulfides which produce the thiyl radical give transient absorptions in the 500–600 nm region. Possible identities of these transients are discussed.     

CHEMILUMINESCENCE AND FLUORESCENCE OF THE EUROPIUM IONS-ADENINE NUCLEOTIDES SYSTEM AND ITS POSSIBLE BIOLOGICAL SIGNIFICANCE

Abstract— Chemiluminescence of the Eu(II)/Eu(III)-adenine nucleotide-H₂O₂ system and fluorescence of the Eu(III)-adenosine triphosphate system have been investigated. The spectral distribution of the chemiluminescence emission has shown an occurrence of three main bands (Λ=470–480,590–620 and ca. 700 nm). The energy transfer process from the adenosine triphosphate molecules to the Eu(III) ions has been observed in the fluorescence spectrum. The examined chemiluminescence and fluorescence spectra show that these both kinds of emission originate from the ⁵ D _***τ⁷F_*** ( n =1–4) transitions in the Eu(III) ions.     

QUANTUM EFFICIENCY AND PHOTOSENSITIVITY OF THE RHODOPSIN ⇌ METARHODOPSIN CONVERSION IN CRAYFISH PHOTORECEPTORS

Photosensitivity (K_λ) of a visual pigment is the product of the molecular absorption coefficient (α_λ) and the quantum efficiency for photoconversion (γ). Among the invertebrates, many visual pigments are stable not only in the rhodopsin (R) conformation but also as the photoproduct, metarhodopsin (M), We here employ a method for determining the photosensitivities of the two stable pigments of a rhodopsin-metarhodopsin pair, using kinetic analysis of fluorescence from metarhodopsin combined with measurements of spectral absorption made before and after saturation at the isosbestic wavelength of the pigment pair. A curve fitting technique, in which a theoretical function is scaled for best fit to the measured absorption spectrum of the photosteady-state mixture, yields values for the photosensitivity of rhodopsin at λ._max, the ratio of quantum efficiencies for rhodopsin—metarhodopsin interconversion, and the fractional composition of the steady-state mixture. With knowledge of the molecular extinction coefficient, the absolute values of quantum efficiency can be calculated. For crayfish ( Orconectes, Procambarus ) rhodopsin, measured in isolated rhabdoms, K_max= 1.05 x 10^-16 cm² at 535 nm with >7λR→M0.69. These values are similar to the photosensitivity and quantum efficiency of bleaching of vertebrate rhodopsins in digitonin solution (Dartnall, 1972). For the metarhodopsin, K_max= 1.02 x 10^-16 cm² at 510 nm, and λ_M-R= 0.49.     

A FLASH PHOTOLYSIS STUDY OF 5-METHOXYINDOLE

Abstract— The microsecond flash photolysis of 5-methoxyindole in aqueous solutions has been studied at γ_exc≥ 290 nm. Transients identified in this time realm in neutral solutions are: e_aq^-, the 5-methoxyindole radical cation (γ_max≅ 440 nm), the neutral transient with γ_max≅ 530 nm) and an unidentified oxygen sensitive transient with γ_max≅ 435 nm. Radical cations and e^-_aq are shown to be produced in equal amounts consistent with a photoionization process as the only source of both transients. H⁺ quenching of fluorescence and radical cation production gives equivalent Stern-Volmer constants indicating that photoionization occurs from the fluorescent state. The unidentified oxygen sensitive transient exhibits a pK _a of2–2.5 and is quenched at lower pH values indicating that it also has a fluorescent state precursor.     

PHOTOCHEMICAL BEHAVIOR AND EMISSION CHARACTERISTICS OF 9-VINYLANTHRACENE

9-Vinylanthracene (9-VA) is an efficient fluorescer of fluorescence quantum yield = 0.91 0.03 in methanol (_ex= 365 nm). This is consistent with its low photochemical quantum yields _c (_cx= 365 nm) of 0.005 in the absence of azobisisobutyronitrile (AIBN) radical initiator and _c= 0.02 in the presence of 10^-2 M dm^-3 AIBN. 9-Vinylanthracene was shown to behave as a 9-substituted anthracene undergoing photodimerization rather than the typical vinyl aryl monomer photopolymerization. The photodimer formation is supported by spectroscopic techniques. 9-Vinylanthracene undergoes efficient fluorescence quenching in the presence of AIBN. Stern-Volmer plots indicate a collisional mechanism. 9-Vinylanthracene crystals as well as polycrystalline films give excimeric emission (_max= 510 nm, _cx= 380 nm) which is considerably red shifted ( ca. 100 nm) compared with molecular emission.     

A LASER FLASH PHOTOLYSIS STUDY OF PYRENE-1-ALDEHYDE. INTERSYSTEM CROSSING EFFICIENCY, PHOTOREACTIVITY AND TRIPLET STATE PROPERTIES IN VARIOUS SOLVENTS

Abstract— Triplet-and singlet-related photoprocesses of pyrene-1-aldehyde (PA) in various solvents have been investigated in detail using 337.1 and 355 nm laser flash photolysis in conjunction with time-correlated determination of fluorescence lifetimes (τ_F) and steady-state photochemical and absorption-emission spectral measurements. In benzene, the lowest triplet of PA (43 < E_T < 46 kcal/mol) has a lifetime of about 50 µs (τ_T) and displays the absorption maximum at 443 nm with a maximum extinction coefficient (ε_max) of 21000 M ^-1cm^-1; the corresponding ketyl radical has a sharp absorption maximum at 428 nm (ε_max≥ 25000 M ^-1cm^-1). The quantum yields (φ_T) of lowest triplet occupation are high in nonprotic solvents (0.6–0.8), decrease in protic solvents (alcohols) as the polarity of the latter is increased, and maintain a complementary relationship with the quantum yields (φ_F) of fluorescence. Quantum yields (φ_PC) of loss of PA due to photoreactions in some solvents have also been determined under conditions of steady irradiation at 366 nm; φ_PC is in the range 0.1–0.2 in electron-rich olefinic solvents such as cyclohexene and tetramethylethylene. These results concerning τ_F, τ_T, φ_F. φ_T and φ_PC as well as the effects of 1,2,4-trimethoxybenzene and 2,5-dimethyl-2,4-hexadiene as quenchers for fluorescence, triplet yield, and photochemistry are discussed in the light of possible state orders for PA in polar and nonpolar environments.     

BIOLUMINESCENCE OF THE BRITTLE STAR OPHIOPSILA CALIFORNICA

The light-emitting principle of the brittle star Ophiopsila californica has been isolated and purified. It was found to be a green-fluorescent photoprotein (molecular weight 45000) which emits green light (λ_max 500 nm) when H₂O₂ is added, independently of the presence or absence of O₂. The green fluorescence (emission maximum 500 nm, excitation maximum 440 nm) spectrally coincided with the H₂O₂-triggered luminescence, indicating that the green fluorescent chromophore is the light-emitter of the photoprotein luminescence.     

SENSITIZATION BY LUMAZINE PROTEINS OF THE BIOLUMINESCENCE EMISSION FROM THE REACTION OF BACTERIAL LUCIFERASES

Abstract— Lumazine protein from Photobacterium phosphoreurn blue shifts the in vitro bioluminescence spectra in the reactions using each of the 4 main types of bacterial luciferases: P. phosphoreum, P. leiognathi, Vibrio harveyi and V. fischeri . For the reaction initiated with FMNH₂ and tetradecanal at 2°C, this "sensitizing" property of lumazine protein differs quantitatively between the luciferases. An interaction constant characterizing each type of luciferase may be derived from a reciprocal plot of the spectral shift against the lurnazine protein concentration. The weakest interaction constant is in the V. fischeri reaction, 180 μM. For the V. harveyi reaction the interaction is in the range 6–9 μ M , and for both Photobacterium reactions it is 2–3 μM. A concentration of only 0.6 μ M of lumazine protein is sufficient to cause an observable change in the Photobacterium bioluminescence spectra. For the V. harveyi case the interaction constant is near to the equilibrium K _d for the luciferase-lumazine protein complex, observed directly by Visser and Lee. Both constants are decreased markedly by increase in phosphate concentration so that it is concluded that, with V. harveyi luciferase, sensitization occurs within this protein-protein complex. For P. phosphoreum luciferase, however, the equilibrium complex is too weak to correspond to the sensitizing interaction and it is concluded that the rate-limiting process is a protein-protein bimolecular collision. As judged from their molecular weight around 20000, spectral properties, and ability to blue shift the bioluminescence spectra, lumazine proteins are identified in a second strain of P. phosphoreum and in P. leiognathi .