SINGLET OXYGEN GENERATION BY FUROCOUMARINS: EFFECT OF DNA AND LIPOSOMES

The quantum yield of singlet oxygen generation by aqueous furocoumarins was measured at 365 nm using the photosensitized inactivation of subtilisin Carlsberg as the probe with the following results: psoralen (0.18), 5-methoxypsoralen (0.013), and 8-methoxypsoralen (0.035). Singlet oxygen formation was significant for dark complexes of 8-MOP with calf thymus DNA and the covalent DNA photoadducts. Incorporation of 8-MOP in sonicated egg phosphatidylcholine liposomes did not inhibit photosensitization of subtilisin Carlsberg and also led to lipid peroxidation, with positive tests for the involvement of singlet oxygen. Peroxidation of the liposomes was inhibited by the presence of α-tocopherol and promoted by the presence of cholesterol in the membranes.     

SINGLET OXYGEN FORMATION BY SENSITIZATION OF FUROCOUMARINS COMPLEXED WITH, OR BOUND COVALENTLY TO DNA

Abstract— The formation of singlet molecular oxygen (¹O₂) by sensitization of the furocoumarins 5-methoxypsoralen (5-MOP), 8-methoxypsoralen (8-MOP) and psoralen complexed with DNA was investigated. From the results it is concluded that 5-MOP complexed with native DNA is able to generate ¹O₂, even in a larger extent than 5-MOP free in solution. Also, with 8-MOP and especially with psoralen, ¹O₂ formation by the complexed compound could be observed. The ¹O₂ formation sensitized by covalently bound furocoumarin was demonstrated with psoralen as a model compound. 4',5'-Dihydropsoralen, a model compound for the UVA light absorbing 4',5'monoadducts of furocoumarins to DNA, is also able to generate ¹O₂.     

PHOTOOXIDATION OF 8-METHOXYPSORALEN WITH SINGLET OXYGEN*

Abstract— The in vitro photooxidation of 8-methoxypsoralen (8-MOP) with singlet oxygen is studied. Irradiation of 8-MOP(295–400 or320–400 nm) in the presence of oxygen for 72 h results in the formation of a product (1.4%) which is identified as 6-formyl-7-hydroxy-8-methoxycoumarin by aid of IR, NMR, MS and co-chromatography with an authentic sample. A study of this reaction in the presence of l,4-diazobicyclo(2,2,2)octane, a singlet oxygen scavenger, indicates the involvement of ¹O₂ in the formation of this compound. In addition to this, formation of a novel dimer of 8-MOP is reported.     

4,4'',6-TRIMETHYLANGELICIN, A NEW VERY PHOTOREACTIVE AND NON SKIN-PHOTOTOXIC MONOFUNCTIONAL FUROCOUMARIN

Abstract— 4,4',6-Trimethylangelicin is a new monofunctional furocoumarin which appears to be a very promising potential agent for the photochemotherapy of psoriasis. Actually, it is capable of photoreacting with DNA to a large extent (four times more than 8-MOP), forming only monoadducts; it produces singlet oxygen to an insignificant extent. Its antiproliferative effect (tested in Ehrlich ascites tunior cells) appears to be several times higher than that induced by the most active angelicins now known and by 8-MOP itself. In spite of this high photosensitized effect, 4,4',6-trimethylangelicin seems to be non-phototoxic on guinea-pig skin and much less mutagenic than 8-MOP in E. coli WP2 uvr -A, a strain in which cross-links show lethality rather than mutations.     

The effect of DNA binding on initial 8-methoxypsoralen photochemistry.

Abstract—Flash photolysis experiments on the complex of 8-methoxypsoralen with calf thymus DNA have shown binding promotes the anaerobic quenching of the 8-MOP triplet state and inhibits the accessibility to oxygen. The results indicate dark psoralen-DNA interactions suppress the singlet oxygen generation observed in prior work.     

PHOTOBINDING OF PSORALENS TO BACTERIAL MACROMOLECULES IN SITU AND INDUCTION OF GENETIC EFFECTS IN A BACTERIAL TEST SYSTEM. EFFECTS OF SINGLET OXYGEN DIAGNOSTIC AIDS D2O AND DABCO

The photobinding of radiolabeled psoralen and 8-methoxypsoralen (8-MOP) to biological macromolecules under conditions that affect the lifetime of singlet oxygen (¹O₂) is reported. These conditions are: increase of ¹O₂ lifetime in D₂O and ¹O₂ quenching with DABCO. The photobinding to calf thymus DNA was studied in vitro and the covalent photobinding to DNA and other biological macromolecules (RNA, proteins) was also studied in intact bacteria. The results of the DNA photobinding experiments have been related to the induction of genetic damage in a bacterial test system. In addition, laser flash photolysis has been used to measure the effect of D₂O and DABCO on the psoralen and 8-MOP triplet lifetimes. In general D₂O increases the triplet lifetimes and DABCO quenches the triplet states with the probable formation of radicals. The results suggest that the covalent photobinding of 8-MOP to various biological macromolecules in situ is a basis for cell damage occurring at various cellular targets. Analysis of the results of the mutagenicity test suggests that in the presence of D₂O the mechanism of induction of genetic lesions is not changed and therefore largely seems to be independent of singlet oxygen.     

Singlet oxygen generation in PUVA therapy studied using electronic structure calculations

The ability of furocoumarins to participate in the PUVA (Psoralen + UV-A) therapy against skin disorders and some types of cancer, is analyzed on quantum chemical grounds. The efficiency of the process relies on its capability to populate its lowest triplet excited state, and then either form adducts with thymine which interfere DNA replication or transfer its energy, generating singlet molecular oxygen damaging the cell membrane in photoactivated tissues. By determining the spin–orbit couplings, shown to be the key property, in the intersystem crossing yielding the triplet state of the furocoumarin, the electronic couplings in the triplet–triplet energy transfer process producing the singlet oxygen, and the reaction rates and lifetimes, the efficiency in the phototherapeutic action of the furocoumarin family is predicted as: khellin < 5-methoxypsoralen (5-MOP) < 8-methoxypsoralen (8-MOP) < psoralen < 4,5′,8-trimethylpsoralen (TMP) < 3-carbethoxypsoralen (3-CPS), the latter being the most efficient photosensitizer and singlet oxygen generator.     

PHOTOADDITION OF 8-METHOXYPSORALEN TO E. coli DNA POLYMERASE I. ROLE OF PSORALEN PHOTO-ADDUCTS IN THE PHOTOSENSITIZED ALTERATIONS OF POL I ENZYMATIC ACTIVITIES

Abstract— We have previously demonstrated that 8-methoxypsoralen (8-MOP)‡ plus UVA is able to inactivate the three enzymatic activities of E. coli DNA polymerase I and that oxygen is required for these reactions (M. Granger et al. , (1982) Photochem. Photobiol. , 36 , 175–180). We now show that UV-A irradiation produces a covalent incorporation of the psoralen derivative into the enzyme either in the presence or in the absence of oxygen. The excited psoralen binds directly to the protein in an oxygen-independent reaction; no complex was detected in the absence of irradiation. Fluorescence measurements reveal that at least two photoadducts are formed.
The 8-MOP-photomodified enzyme is still fully active but further irradiation leads to an inhibition of the 5'→ 3' polymerase activity whereas the 5'→ 3' exonuclease activity is not affected. A major part of the inhibition reaction is shown to be oxygen-dependent but singlet oxygen quenchers have no effect on the kinetics. This oxygen-dependent reaction is attributed to a photosensitization, due to covalently bound 8-MOP, of neighbouring amino acids through an intermediate reactive oxygen species which is not singlet oxygen. The oxygen-independent reaction is attributed to a direct photosensitization through, for example, a radical mechanism.     

DNA damage induced by 4,6,8,9-tetramethyl-2H-furo[2,3-h]quinolin-2-one, a new furocoumarin analog: photochemical mechanisms

Some photochemical and photobiological properties of 4,6,8,9-tetramethyl-2H-furo[2,3-h]quinolin-2-one (HFQ) were studied in comparison with its isomer 1,4,6,8-tetramethyl-2H-furo[2,3-h]quinolin-2-one (FQ) and 8-methoxypsoralen (8-MOP). The HFQ photobinds to DNA forming furan-side monoadducts (MAHFQ) that have molecular structure very similar to those of FQ (MAFQ). Unlike MA8-MOP and MAFQ, MAHFQ no longer photoreact. The HFQ, like FQ, produces moderate amounts of singlet oxygen but no superoxide anions. The HFQ and FQ induce numbers of DNA-protein cross-links (DPC), much more plentiful than those of 8-MOP (about two and seven times, respectively) but no interstrand cross-links. The mechanism of DPC formation was studied in vivo in mammalian cells by alkaline elution and in vitro using a new test mixing histones and DNA from calf thymus. The latter is a very useful technique for the double irradiation protocol. The DNA (or histones) are separately exposed to a first UVA dose in the presence of the sensitizer; then, after its unbound molecules have been removed, histones (or DNA) are added to assemble the chromatin-like complex that is irradiated again. According to in vitro and in vivo methods, DPC appear to be formed by FQ and 8-MOP by a biphotonic process that starts with monoadduct induction in DNA, followed by their conversion into DPC. In the resulting lesions, the sensitizer molecule forms a covalent bridge between the two macromolecules (DPC at length greater than zero). Instead, HFQ induces DPC by a monophotonic process; thus, HFQ is probably not a physical part of the bridge between DNA and proteins, which may be linked together directly, like DPC at zero length induced by UVC.     

BENZO- and TETRAHYDROBENZO-PSORALEN CONGENERS: DNA BINDING and PHOTOBIOLOGICAL PROPERTIES

Four new benzo- and tetrahydrobenzo-psoralens have been examined in their reversible interaction toward DNA and in their DNA-photobinding properties. These compounds were also examined for their ability to produce singlet oxygen and in vivo skin photosensitization reaction. Fluorescence and equilibrium dialysis measurements show that the complexation ability of benzoderivatives is remarkably high. Binding is less effective in the case of the tetrahydrocongeners. All compounds photoreact quite effectively to DNA. The photoadducts were obtained by enzymatic hydrolysis of drug-modified DNA and were characterized by high performance liquid chromatographic elution techniques. The 3,4 position represents the unique photoreactive site for benzopsoralens. Denaturation-renaturation experiments confirm that the benzoderivatives are purely monofunctional, while the tetrahydrocongeners form interstrand cross-links, even though to a remarkably lesser extent than 8-methoxypsoraien (8-MOP). The new compounds, in the presence of long-wavelength ultraviolet radiation, are very moderately effective in forming reactive oxygen species; they are ineffective in promoting oxidation of tyrosine and 3-(3,4-dihydroxyphenyl)alanine to do-pachrome and melanin. Skin photosensitizing experiments on guinea pigs indicate that benzo- and tetrahydroben-zopsoralen derivatives are almost devoid of any phototoxic effects. Thus, this class of compounds appears to be interesting for the development of new, less phototoxic chemotherapeutic agents that interact with DNA better than 8-MOP.     

THE INTERACTION OF MELANIN WITH 8-METHOXYPSORALEN: EFFECT ON RADIATIVE and NONRADIATIVE TRANSITIONS. A FLUORESCENCE and PULSED PHOTOACOUSTIC STUDY

Abstract –The interaction of 8-methoxypsoralen (8-MOP) with synthetic eumelanin was investigated using static and time-resolved fluorescence and pulsed photoacoustic calorimetry. Due to the strong overlap of the absorption bands of melanin and 8-MOP, a method is presented to account for the systematic errors introduced by the optical filter effect exerted by each absorbing species in the fluorescence and the photoacoustic measurements. As a preliminary step to the understanding of the nonradiative behavior of the psoralen-melanin complexes, the photoacoustic parameters of 8-MOP in various solvents were determined. Spectroscopic data indicate the absence of interaction at the ground-state level, whereas the singlet excited state of 8-MOP is quenched by the pigment; the average fluorescence lifetimes are independent of the melanin concentration, thus indicating a static quenching mechanism. The photoacoustic data show that the quenching process involves an increased intersystem crossing probability, which is almost unaffected by the presence of oxygen, as expected for a molecule essentially acting as a type I photosensitizing agent.     

THE INTERACTION OF MELANIN WITH 8-METHOXYPSORALEN: EFFECT ON RADIATIVE AND NONRADIATTVE TRANSITIONS. A FLUORESCENCE AND PULSED PHOTOACOUSTIC STUDY

Abstract: The interaction of 8-methoxypsoralen (8-MOP) with synthetic eumelanin was investigated using static and time-resolved fluorescence and pulsed photoacoustic calorimetry. Due to the strong overlap of the absorption bands of melanin and 8-MOP, a method is presented to account for the systematic errors introduced by the optical filter effect exerted by each absorbing species in the fluorescence and the photoacoustic measurements. As a preliminary step to the understanding of the nonradiative behavior of the psoralen-melanin complexes, the photoacoustic parameters of 8-MOP in various solvents were determined. Spectroscopic data indicate the absence of interaction at the ground-state level, whereas the singlet excited state of 8-MOP is quenched by the pigment; the average fluorescence lifetimes are independent of the melanin concentration, thus indicating a static quenching mechanism. The photoacoustic data show that the quenching process involves an increased intersystem crossing probability, which is almost unaffected by the presence of oxygen, as expected for a molecule essentially acting as a type I photosensitizing agent.     

RNA-protein cross-links induced by sensitization with a pyrroloquinolinone derivative, a furocoumarin analogue

The capacity of 2,6-dimethyl-9-methoxy-4H-pyrrolo [3,2,1-ij] quinolin-4-one (PQ), a furocoumarin analogue, of inhibiting protein synthesis in Ehrlich cells upon UVA irradiation was investigated. Using 8-methoxypsoralen (8-MOP) as a reference, we observed that in our short-term test the block of RNA synthesis do not affect protein synthesis, which is driven by pre-synthesised molecules of m-RNA; actually 8-MOP, studied at 100 μM concentration, practically abolished RNA synthesis without affecting significantly protein synthesis. Studying PQ sensitization in HL60 cells by alkaline elution and protein precipitation, the formation of covalent RNA-protein cross-links was observed. 8-MOP, assayed in severe experimental conditions, induced only moderate amounts of such lesion. On the basis of the data obtained in experiments carried out using various scavengers or exposing cells to UVA light in a nitrogen atmosphere, this damage appeared to be due to singlet oxygen formation, which is generated by PQ to a large extent. These results are consistent with the data obtained by H. Singh and J.A. Vadasz (Singlet oxygen: a major reactive species in the furocoumarin photosensitized inactivation of E. coli ribosomes, Photochem. Photobiol., 28 (1978) 539–545) on E. coli ribosomes. The lower activity we observed with 8-MOP might be attributed to a different sensitivity of whole mammalian cells in comparison with isolated ribosomes.     

FORMATION OF SINGLET MOLECULAR OXYGEN BY 8-METHOXYPSORALEN*

Abstract— The formation of singlet molecular oxygen (^lO₂) by energy transfer from the excited 8-meth-oxypsoralen (8-MOP) molecule was investigated. This was done in several ways: (a) In the reaction of irradiated 8-MOP with the ¹O₂ acceptor 2-methyl-2-pentene, the characteristic oxidation products were identified. (b) The rate of the 8-MOP sensitized photooxidation of 3, 4-dihydroxy phenylalanine (dopa), which appeared to be also a useful ¹O₂ acceptor, was larger in D₂O than in H₂O. (c) The β-values for reaction of ¹O₂with dopa in the presence of 8-MOP or of methylene blue as ¹O₂ generators were in accordance with each other. The consequences of ¹O₂ formation by 8-MOP sensitization is discussed for the clinical use of this compound.     

MUTAGENIC AND RECOMBINOGENIC ACTION OF DNA MONOADDUCTS PHOTOINDUCED BY THE BIFUNCTIONAL FUROCOUMARIN 8-METHOXYPSORALEN IN YEAST (Saccharomyces cerevisiae)

Abstract— For the same furocoumarin 8-MOP and the same total number of photoadditions, the genetic activity of DNA monoadducts and a mixture of mono- and biadducts photoinduced by the bifunctional furocoumarin 8-methoxypsoralen (8-MOP) is compared in the yeast Saccharomyces cerevisiae. In the presence of 8-MOP, 405 nm irradiation induces only monoadducts, whereas 365 nm irradiation induces mono- and biadducts (interstrand cross-links) in DNA. This is shown by heat denaturation-renaturation experiments on calf thymus DNA treated in vitro and by alkaline step elution analysis of DNA from treated yeast cells. For the same photobinding of tritiated 8-MOP to DNA in diploid yeast, about 20 times higher doses are needed with 405 nm than with 365 nm irradiation. Re-irradiation experiments reveal that part of the monoadducts induced by 8-MOP and 405 nm irradiation can be effectively converted into DNA interstrand cross-links by exposures to 365 nm radiation after washing-out of unbound 8-MOP molecules. 8-MOP and 405 nm irradiation induce per lethal hit cytoplasmic "petite" mutations in yeast as efficiently as the monofunctional furocoumarin 3-carbethoxypsoralen (3-CPs) and 365 nm irradiation, both treatments being much more efficient than 8-MOP and 365 nm irradiation. At equal survival, treatments with 8-MOP and 405 nm radiation are clearly less efficient than treatments with 8-MOP and 365 nm radiation for the induction of forward ( CAN *) and reverse ( HIS +) mutations in haploïd yeast and for the induction of mutations ( ILV +) and genetically aberrant colonies including mitotic crossing-over in diploid yeast. The two treatments are equally efficient for the induction of mitotic gene conversion. At equal photobinding of 8-MOP, the monoadducts induced by 405 nm irradiation are found less effective than the mixture of mono-and biadducts induced by 365 nm irradiation for the induction of cell killing, mutations and mitotic recombination.     

8-METHOXYPSORALEN-PHOTOINDUCED DNA CROSSLINKS AS DETERMINED IN YEAST BY ALKALINE STEP ELUTION UNDER DIFFERENT REIRRADIATION CONDITIONS. RELATION WITH GENETIC EFFECTS

Abstract— DNA damage induced by 8-methoxypsoralen (8-MOP) plus near UV light (UVA) was analyzed in diploid yeast using the alkaline step elution technique. The presence of 8-MOP and UVA induced DNA interstrand cross-links was revealed by the increase of DNA retained on elution filters as compared to untreated controls. The fraction of DNA retained on filters increased linearly with UVA dose. The amount of cross-links was estimated from the fraction of DNA retained on filters using a dose of -radiation leading to a number of DNA strand breaks at least equivalent to the number of 8-MOP induced photoadducts.
When 8-MOP treated cells were exposed to monochromatic light, 365 nm light induced monoadducts and cross-links whereas 405 nm light induced only monoadducts. When submitting 8-MOP plus 405 nm light treated cells to 365 nm irradiation, after removal of unbound 8-MOP by washing, a portion of 8-MOP plus 405 nm light induced monoadducts was converted into cross-links. The amount of monoadducts transformed into cross-links was dependent on the dose of 365 nm irradiation up to a maximum likely to correspond to the number of suitably positioned furan-side monoadducts that could be converted into biadducts. When 8-MOP plus 365 nm light treated cells were reirradiated with 365 nm light, following the same protocol, the maximum level of cross-linking obtainable in yeast was lower than that obtained with 8-MOP in a 405 nm plus 365 nm reirradiation protocol.
In the presence of 8-MOP single exposures to 405 nm light were found to be only slightly genotoxic. However, when followed by second exposures to 365 nm light, a dose-dependent increase in genetic effects, i.e. mutation and gene conversion, was observed in parallel to the induction of DNA crosslinks. These results stress again the prominent role of DNA cross-links in the genotoxicity of 8-MOP.     

THE PHOTOTOXICITY OF 8-M-ETHOXYTHIONEPSORALEN AND 6-M-ETHYLTHIONECOUMARIN

The phototoxicity of 8-methoxythionepsoralen (8-MOTP) and 6-methylthione coumarin (6-MTC) when activated by UV-A has been investigated using a variety of Escherichia coli strains, Haemophilus influenzae transforming DNA and Escherichia coli pBR322 plasmid DNA. The results demonstrate that 8-MOTP is a strictly oxygen independent photosensitizer that is about 500-fold less efficient in forming lesions leading to equivalent lethality than is the parent compound from which it is derived (8-MOP). As is true for 8-MOP, 8-MOTP is capable of inducing histidine independent mutations in E. coli and inactivating transforming DNA consistent with DNA being a target for lesions induced by this molecule in the presence of UV-A. 6-MTC is a strongly oxygen dependent photosensitizer activated by UV-A when tested with either E. coli cells or transforming DNA in contrast to the parent compound (6-methylcoumarin; 6-MC) which is not phototoxic when treated with UV-A. These results imply that the membrane may be an important target leading to lethality. 6-MTC in the presence of UV-A can inactivate pBR322 plasmid and Haemophilus influenzae transforming DNA activity in vitro suggesting that DNA is a potential target for this molecule when activated by UV-A.     

Mitochondrial alterations in fanconi anemia fibroblasts following ultraviolet A or psoralen photoactivation

The genetic disease Fanconi anemia (FA), generally considered to be a DNA repair defect, has also been related to a deficiency in cellular defense against reactive oxygen species (ROS). Results show that mitochondrial matrix densification occurs rapidly and transiently in FA fibroblasts following 8-methoxypsoralen (8-MOP) photoreaction or ultraviolet A (320 to 380 nm) (UVA) irradiation. This effect is oxygen dependent because it is more important under 20 than under 5% oxygen tension. In contrast, in normal fibroblasts very little, if any, densification of mitochondrial matrix is induced by treatments even at the highest oxygen tension. The changes in matrix density in FA cells are accompanied by some modifications in transmembrane potential, linked to a Fenton-like reaction, and in mitochondrial cardiolipin content, differing from the responses of normal cells. These data are indicative of some sort of membrane damage induced by 8-MOP photoreaction and UVA irradiation, to which FA cells appear to be particularly sensitive.     

PHOTOSENSITIZED FORMATION OF 8-HYDROXY-2'-DEOXYGUANOSINE AND DNA STRAND BREAKAGE BY A CATIONIC meso-SUBSTITUTED PORPHYRIN

Abstract Cationic porphyrins, known to have a high affinity for DNA, are useful tools with which to probe a variety of interactions with DNA. In this study we have examined both DNA strand scission and oxidative DNA base damage, measured by 8-hydroxy-2'-deoxyguanosine (8-OHdG) formation, using a photoactivated cis-dicationic por-phyrin. The data demonstrated a dose-dependent formation for each type of DNA damage. Inhibition of strand scission and 8-OHdG formation with the singlet oxygen scavenger 1,3-diphenylisobenzofuran and with MgCl₂ and no apparent effect by D₂O suggests that a singlet oxygen mechanism generated in close proximity to the DNA may be responsible for the damage. However, a nearly complete inhibition of 8-hydroxy-2'-deoxyguanosine formation in 75% D₂O and the substantial enhancement of 8-hydroxy-2'-deoxyguanosine formation in a helium atmosphere by photoactivated porphyrin rules out singlet oxygen as a primary mechanism for this process. These data indicate that distinct mechanisms lead to 8-OHdG formation and strand scission activity.     

Tracing the Photoaddition of Pharmaceutical Psoralens to DNA

The psoralens 8-methoxypsoralen (8-MOP), 4,5′,8-trimethylpsoralen (TMP) and 5-methoxypsoralen (5-MOP) find clinical application in PUVA (psoralen + UVA) therapy. PUVA treats skin diseases like psoriasis and atopic eczema. Psoralens target the DNA of cells. Upon photo-excitation psoralens bind to the DNA base thymine. This photo-binding was studied using steady-state UV/Vis and IR spectroscopy as well as nanosecond transient UV/Vis absorption. The experiments show that the photo-addition of 8-MOP and TMP involve the psoralen triplet state and a biradical intermediate. 5-MOP forms a structurally different photo-product. Its formation could not be traced by the present spectroscopic technique.