DETECTION OF PYRIMIDINE DIMERS AND MONOADDUCTSINDUCED BY 7-METHYLPYRIDO(3,4-c) PSORALEN AND UVA IN CHINESE HAMSTER V79 CELLS BY ENZYMATIC CLEAVAGE AND HIGH-PRESSURE LIQUID CHROMATOGRAPHY

Abstract The photochemotherapeutically active psoralen derivative 7-methylpyrido(3,4-c) psoralen (MePyPs) has been recently shown to be able to photoinduce monoadducts of the C₄-cycloaddition type as well as pyrimidine dimers in DNA in vitro . In the present study, we report on the induction of these two types of photolesions in mammalian cells in culture. The MePyPs photocycloadducts were quantified in V79 Chinese hamster cells after treatment with MePyPs plus UVA following enzymatic hydrolysis of the DNA by DNase I, S1 nuclease and acidic phosphatase treatments. Concomitantly induced pyrimidine dimers were determined by two methods, high-pressure liquid chromatography and alkaline gel electrophoresis after dimer-specific endonucleolytic cleavage. The results show that, in Chinese hamster cells treated with MePyPs plus UVA, the yield of pyrimidine dimers is approximately 5-10% that of MePyPs-DNA photocycloadducts. Because psoralen monoadditions to DNA alone are generally not considered as being very phototoxic, a synergistic interaction of monoadditions with pyrimidine dimers may be expected to occur in order to explain the high photobiological effectiveness of this psoralen derivative.     

A NEW MONOFUNCTIONAL PYRIDOPSORALEN: PHOTOREACTIVITY and REPAIR IN YEAST

Abstract— The newly synthesized derivative of psoralen, the pyrido (3,4-c) 7 methylpsoralen (MePyPs), acts in combination with 365 nm ultraviolet as a monofunctional agent on yeast DNA. In vivo, its photoaffinity for DNA is much higher than that of the bifunctional agent, 8-methoxypsoralen (8-MOP). The MePyPs photo-induced monoadducts are almost completely removed from wild type cells DNA as efficiently as 8-MOP photo-induced adducts during post-treatment incubation. This process is blocked in excision-repair defective mutants (6 to 10% residual excision in radl- Δ or rad2- Δ ). For an equal number of photoinduced lesions, the DNA single strand breaks which are produced concomitantly to MePyPs or 8-MOP photoadducts excision are rapidly rejoined in the case of 8-MOP whereas they are only partly resealed for the MePyPs treatment. The high photo-toxicity of MePyPs, a promising agent for photo-chemotherapeutic use, is explained in terms of the high photoaffinity for DNA.     

SENSITIVITY OF DNA REPAIR-DEFICIENT STRAINS OF ESCHERICHIA COLI K-12 TO VARIOUS FUROCOUMARINS AND NEAR-ULTRAVIOLET RADIATION

Abstract— Survival curves were obtained for DNA repair-deficient strains of Escherichia coli K-12 ( polA1, uvrB5 , and recA56 ) exposed to near-ultraviolet radiation [black light (BL)] in the presence of the DNA cross-linking agent 8-methoxypsoralen (8-MOP) or in the presence of photosensitizers forming primarily monoadducts with DNA [angelicin; 3-carbethoxypsoralen (3-CPs); 5,7-dimethoxycoumarin (DMC)], and after exposure to blue light (BluL) in the presence of 8-MOP or 3-CPs. An interpretation of these data suggests that DNA polymerase I is required for the major pathway of monoadduct repair, but appears to play little or no role in the repair of 8-MOP cross-links. The uvrB and recA strains were very sensitive, both to the cross-linking agent and to the monoadduct formers. The markedly different results for BL plus DMC or 3-CPs compared to angelicin suggests that the DMC and 3-CPs monoadducts are repaired by a different mechanism than are the angelicin monoadducts, or else DMC and 3-CPs undergo photochemical side reactions that produce DNA lesions other than the expected monoadducts. From photochemical evidence, we predicted that fewer 8-MOP monoadducts should be converted to cross-links by BluL vs BL; this appears to be the case. 3-CPs showed dramatically different biological results when irradiated with BL vs BluL, suggesting that 3-CPs may form more types of photoproducts than the expected monoadducts; BluL, however, appears to favor monoadduct formation.     

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.     

GEOMETRY OF INTERCALATION OF PSORALENS IN DNA APPROACHED BY MOLECULAR MECHANICS*

The results of molecular mechanical calculations on intercalation complexes of 3-carbethoxypsoralen, 5-methoxypsoralen, 8-methoxypsoralen, 7-methylpyrido[3,4-c]psoralen (MepyPs) and 7-methylpyrido[4,3-c]psoralen (2N-MePyPs) with the double stranded duodecanucleotide d(CGCGATATCGCG)2 are presented. In the energy-minimized structures, the psoralens are intercalated with their plane orthogonal to the helix axis. Stacking interactions between the furan ring of the psoralen and the adjacent bases are maximized in most derivatives studied, whereas the effect of the various substituents of the psoralen ring is to specifically push part of the molecule towards either the minor or the major groove, preventing a symmetrical intercalation (with respect to the two strands of the DNA). The relative position of the psoralen ring and of the adjacent thymine foreshadows the formation of furan-side monoadducts in 3-CPs, MePyPs and 2N-MePyPs, whereas the formation of a pyrone-side monoadduct appears as geometrically more favourable in 5-MOP and both furan- and pyrone-side monoadducts can be geometrically envisaged in 8-MOP. A good correlation therefore exists between the more or less favourable equilibrium geometries and the experimentally observed photoreactions. The present study is the first attempt to characterize the geometrical parameters as part of a complex set of geometrical, dynamical and excited state parameters governing the overall DNA-psoralen photoreaction.     

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.     

Repair of furocoumarin-plus-UVA-induced damage and mutagenic consequences in eukaryotic cells

In the presence of near-UV radiation (UVA) furocoumarins (psoralens) photoinduce defined lesions in DNA, i.e. monoadducts and interstrand crosslinks. Their use in photochemotherapy (psoralen plus UVA (PUVA) treatment) and cosmetics raises questions concerning the repairability of these lesions and their genotoxic consequences. We have analysed the repair of psoralen photoadducts in cultured eukaryotic cells, such as yeast and mammalian cells, for furocoumarins of photochemotherapeutic interest. In yeast, the interaction of repair pathways differs in exogenous (plasmid) and endogenous (chromosomal) DNA. The order of mutagenic activity is 4,5',8-trimethylpsoralen greater than 5-methoxypsoralen greater than 8-methoxypsoralen greater than 7-methylpyrido[3,4-c]psoralen greater than 3-carbethoxypsoralen. The mutagenicity is dependent on psoralen functionality, concentration and bioavailability, maximal UVA dose, wavelength, dose (fluence) rate and presence or absence of chemical filters. It probably involves an inducible component. Chromosome breakage occurs during the repair period after PUVA treatment. It appears that the genotoxic effects of psoralens are produced by a specific arrangement of induced photolesions and the interaction of different repair systems.     

MUTAGENIC EFFECTS PHOTOINDUCED IN MAMMALIAN CELLS IN VITRO BY TWO MONOFUNCTIONAL PYRIDOPSORALENS

Abstract— The photobiological activity of the two monofunctional pyridopsoralens pyrido (3,4-c) psoralen (PyPs) and 7-methyl pyrido (3,4-c) psoralen (MePyPs) was studied in mammalian cells in vitro taking 8-methoxypsoralen (8-MOP) as a reference compound.
In the presence of 365-nm irradiation (UVA) MePyPs was found to be more effective than 8-MOP in terms of DNA photobinding capacity and inhibition of cell cloning ability in Chinese hamsterV–79 cells. As a function of UVA dose and of the number of total photoadducts induced MePyPs produced a higher frequency of 6-thioguanine resistant mutants than 8-MOP. PyPs showed an intermediate response for cell killing and mutation induction. At equal cytotoxic levels both monofunctional pyridopsoralens exhibited the same mutagenic activity as the Afunctional furocoumarin 8-MOP.
The antiproliferative effect being taken as indicative for an efficient photochemotherapeutic activity against psoriasis, the inhibition of cloning capacity induced by MePyPs plus UVA was studied in parallel on human skin fibroblasts. Such cells were more sensitive to 8-MOP photoadditions thanV–79 cells and even more so to MePyPs photoadditions. Data obtained on the rate of DNA semi conservative synthesis on both cell lines following treatments with the two compounds are in line with these observations.     

DIFFERENT EFFECTS OF RAD GENES OF SACCHAROMYCES CEREVISIAE ON INCISIONS OF INTERSTRAND CROSSLINKS AND MONOADDUCTS IN DNA INDUCED BY PSORALEN PLUS NEAR UV LIGHT TREATMENT

Abstract— The RAD1, RAD2, RAD3 and RAD4 genes of Saccharomyces cerevisiae are required for incising DNA containing UV induced pyrimidine dimers or psoralen plus 360 nm light induced interstrand crosslinks. We have now determined if these genes are also required for incising DNA at psoralen plus 360 nm light induced monoadducts. For distinguishing between incision breaks occurring at crosslinks and at monoadducts. we have used the cdc9-2 mutant, defective in DNA ligase activity at the restrictive temperature, and the radl-2 cdc9-2, rad2-5 cdc9-2 , rad3-2 cdc9-2 and rad4-4 cdc9-2 double mutant combinations. We conclude that the radl, rad2 , and rad4 mutants are defective in incising DNA both at crosslinks and monoadducts, whereas the rad3 mutant is proficient in incising DNA at monoadducts but not at crosslinks.     

EFFECT OF MOLECULAR STRUCTURE ON THE PHOTOPHYSICAL PROPERTIES, THE PHOTOREACTIVITY WITH DNA AND THE PHOTOBIOLOGICAL ACTIVITY OF MONOFUNCTIONAL PYRIDOPSORALENS

Abstract— 7-Methyl-pyrido[4,3-c]psoralen (2N-MePyPs) has been synthesized in order to investigate the possible effect of the position of the pyridine-nitrogen atom on the photoreactivity towards DNA and the photobiological activity of pyridopsoralens, a new family of psoralen derivatives. In comparison to its isomer, 7-methyl-pyrido[3,4-c]psoralen (MePyPs), 2N-MePyPs shows a 2.5 times lower DNA photobinding capacity. Photobiological experiments with diploid yeast ( Saccharomyces cerevisiae ) reveal that this compound differs strikingly from its isomer MePyPs. It has only a weak antiproliferative potential and, per unit dose, a lower capacity than MePyPs for the induction of nuclear genotoxic effects. With respect to these latter features, 2N-MePyPs resembles the monofunctional furocoumarin 3-CPs.     

Mechanism of action of 4-hydroxymethyl-1,6,8-trimethylfuro[2,3-h]quinolin-2(1H)-one, a very active angular furocoumarin-like sensitizer

The molecular structure of 1,4,6,8-tetramethylfuro[2,3-h]quinolin-2(1H)-one (FQ), a recent furocoumarin-like photosensitizer, has been modified with the aim of reducing its strong genotoxicity, by replacing the methyl group at 4 position with a hydroxymethyl one, and so obtaining 4-hydroxymethyl-1,6,8-trimethylfuro[2,3-h]quinolin-2(1H)-one (HOFQ). This modification gave rise to a strong reduction of lipophilicity and dark interaction with DNA. The formation of monoadducts (MA) was deeply affected, whereas the induction of bifunctional adducts between DNA and proteins (DPC(L>0)) was replaced by an efficient production of DNA-protein cross-links at zero length (DPC(L=0)), probably via guanine damage. Because of its angular molecular structure, HOFQ does not form interstrand cross-links (ISC): therefore, DPC(L=0) and MA represent the main lesions induced by HOFQ in DNA. In comparison with FQ (which induces MA and DPC(L>0)) and 8-methoxypsoralen (8-MOP) (MA, ISC, DPC(L>0)), HOFQ seems to be a more selective agent. In fact, contrary to FQ and 8-MOP, HOFQ, together with a noticeable antiproliferative activity, shows low levels of point mutations in bacteria and of clastogenic effects in mammalian cells. HOFQ is also an efficient apoptosis inducer, especially in comparison with 8-MOP, when tested at equitoxic experimental conditions; this property might be correlated with the complete HOFQ inability of inducing skin erythemas, a well-known side effect of classic furocoumarin photosensitization.     

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

4,6,8,9-Tetramethyl-2H-furo[2,3-h]quinolin-2-one (HFQ) and its isomer FQ (1,4,6,8-tetramethyl-2H-furo[2,3-h]quinolin-2-one) showed very strong antiproliferative activity in mammalian cells, about two times greater than 8-methoxypsoralen (8-MOP). Both compounds induced DNA-protein cross-links (DPC) but not interstrand cross-links. The FQ generated DPC in a biphotonic process, yielding a new kind of diadduct, whereas HFQ induced DPC by a monophotonic one, probably without its physical participation in the covalent bridge. These lesions gave different toxic responses. Sensitization of FQ led to extensive DNA fragmentation and to a number of chromosomal aberrations. Conversely, HFQ seemed to be completely inactive and 8-MOP gave intermediate results. A strict relationship between DPC formation and induction of chromosomal aberrations was observed. The HFQ did not induce light skin erythemas, whereas FQ was more phototoxic than 8-MOP, thus suggesting that FQ lesions, DPC in particular, may be implicated in skin phototoxicity. Ehrlich ascites cells, a transplantable mouse tumor, inactivated by furoquinolinone sensitization and injected into healthy mice, protected them from a successive challenge by viable tumor cells. This response appeared to be based on an immune mechanism. Comparable amounts of base substitution revertants were scored when testing furoquinolinones and 8-MOP in bacteria but no DPC were detected. This suggests that classic mutagenesis tests on bacteria are insufficient to give adequate information on furocoumarin genotoxicity. Given its features, HFQ can be regarded as an interesting new agent for psoralen plus UVA photochemotherapy and photopheresis.     

TRIPLET EXCITED STATES OF 4'',5''-PHOTOMONOADDUCTS OF 3- CARBETHOXYPSORALEN and 8-METHOXYPSORALEN WITH DNA NUCLEOSIDES

Abstract— Triplet absorption spectra, triplet extinction coefficient and intersystem crossing for 4',5'-monocycloadducts of 3-carbethoxypsoralen (3-CPs) with thymidine (dThd) and uridine (dUrd) in ethanol have been investigated in order to elucidate whether their triplet state properties could be the limitating step for a further photoreaction of 3-CPs monoadducts with DNA nucleosides. The comparison between the triplet characteristics of 4',5'-monoadducts of 3-CPs and those of 8-methoxypsoralen (8-MOP) shows that the quantum yield is much higher in the case of 3-CPs than for 8-MOP. The monofunctionality of 3-CPs cannot therefore be ascribed to the triplet excited states properties of its monoadducts. It is likely that steric hindrance introduced by the bulky carbethoxy group remains a reasonable explanation.     

The Lack of Efficacy of 4,6,4'-Trimethylangelicin to Induce Immune Suppression in an Animal Model for Photopheresis: a Comparison with 8-MOP

Photopheresis is an extracorporeal form of photochemo-therapy with 8-methoxypsoralen (8-MOP) and UVA (PUVA). Patients ingest 8-MOP and then a psoralen-rich buffy coat is obtained by centrifugation and mixed with saline. This mixture is recirculated through a UVA radiation field and then reinfused. Photopheresis appears to be effective for several T cell-mediated disorders, because the treatment results in a specific immune response against the pathogenic clone of T cells involved. With PUVA therapy, the whole body of the patient is exposed to UVA, after ingestion of 8-MOP. Upon UVA exposure 8-MOP binds to, amongst others, DNA and induces DNA monoadducts and interstrand cross-links. As a result of these photoadducts photocarcinogenicity is a risk in PUVA. In PUVA for psoriasis, it proved that angular furocoumarins, although almost incapable of inducing DNA cross-links (less carcinogenic), are still effective. In order to determine if monoadducts induced by photopheresis could also be effective we used, specifically, 4,6,4'-trimethylangelicin (TMA). In this report, we compare the photodegradation of both TMA and 8-MOP under conditions relevant to the in vivo situation, as well as the effect both compounds have on the viability of rat lymphocytes as measured with the 3–(4,5-dimethylthia-zol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay. We show that TMA did not induce immunosuppression in vivo , even after extensive irradiation. In addition a dose dependency of 8-MOPNVA versus the induced immune suppression was carried out. It was shown that there is a log doselresponse correlation of r = 0.9205.     

Molecular dosimetry of 8-MOP + UVA-induced DNA photoadducts in Saccharomyces cerevisiae: correlation of lesions number with genotoxic potential

Acid hydrolysis of purified DNA extracted from cells of a haploid repair-proficient (RAD) yeast strain that had been treated with 8-MOP + UVA revealed the existence of two major and one minor thymine photoproduct. At survival levels of the RAD strain between 100% and 1% furanside monoadducts constituted the major DNA lesion, followed by diadducts that, at the lowest survival level, nearly reached 50% of the thymine photoproducts; pyrone-side monoadducts were only detectable at the highest UVA exposure dose applied and clearly constitute a minority photoproduct. The number of induced diadducts was verified by determination of interstrand cross-links via denaturation and renaturation of 8-MOP + UVA-treated DNA from RAD and rad2 yeast strain. 8-MOP + UVA was shown to induce two types of locus-specific mutations: reversion of the lys1-1 ochre allele was between 20- to 50-fold higher than that of the his4-38 frameshift allele. Mutant yield for the lys 1-1 reversion was the same in RAD and excision repair-deficient rad2-20 strains whereas frameshift mutagenesis was about eightfold higher in the rad2-20 background.     

Isolation and Characterization of Two Furan-side Photoadducts of 7-Methylpyrido[3,4-c] Psoralen to the Sugar Moiety of 2-Deoxyadenosine†

Abstract. The UVA-mediated photoreaction of the monofunctional 7-methylpyrido[3,4-c]psoralen (MePyPs) with 2′-deoxy-adenosine was investigated in the dry state. Two main 7-methylpyrido[3,4-c]psoralen monoadducts to 2′-deoxy-adenosine were isolated by HPLC and characterized by soft ionization mass spectrometry (fast atom bombardment) and extensive ¹H NMR analyses including correlation spectroscopy, total correlation spectroscopy and nuclear Overhauser effect measurements. The two unusual photoadducts exhibit a covalent bond between the C-4′ of the furan moiety of the psoralen on one hand and either the C-l' or the C-4′ of the furanose ring of the purine nucleoside on the other hand. The furan-side monoadducts appear to be specific for both 2′-deoxy-adenosine and MePyPs. They are likely to result from the recombination of the 4′,5′-dihydrofuran-4′-yl radical of MePyPs with 2′-deoxyadenosyl carbon-centered sugar radicals at either the 1′ or the 5′ position.     

4, 4'', 5''-TRIMETHYL-8-AZAPSORALEN, A NEW-PHOTOREACTIVE AND NON-SKIN-PHOTOTOXIC BIFUNCTIONAL BIOISOSTER OF PSORALEN

Photochemical and photobiological properties of a new isoster of psoralen, 4,4',5'-trimethyl-8-azapsoralen (4,4',5'-TMAP), have been studied. This compound shows a high DNA-photobinding rate, higher than that of 8-methoxypsoralen (8-MOP), forming both monoadducts and inter-strand cross-links. The yield of cross-links, however, is markedly lower than that of 8-MOP. Antiproliferative activity of 4,4',5'-TMAP, in terms of DNA synthesis inhibition in Ehrlich ascites tumor cells, is higher than that of 8-MOP. Mutagenic activity on E. coli WP2 R46+ cells appeared similar to or even lower than that of 8-MOP. This new compound applied on depilated guinea pig skin and irradiated with UVA did not show any skin-phototoxicity. On the basis of these properties 4,4',5'-TMAP appears to be a potential photochemotherapeutic agent.     

3-CARBETHOXYPYRANOCOUMARIN, A PHOTOREACTIVE DERIVATIVE OF XANTHYLETIN WITH INTERESTING PHOTOBIOLOGICAL PROPERTIES

Abstract— The photobiological activity of the newly synthesized pyranocoumarin derivative 3-carbethoxypyranocoumarin, so-called 3-carbethoxyhomopsoralen (3-CHPs) was studied in comparison to the known bifunctional furocoumarin 8-methoxypsoralen {8-MOP) and to the monofunctional furocoumarin 3-carbethoxypsoralen (3-CPs) in the presence of 365 nm irradiation using two eukaryotic cell systems, the yeast Saccharomyces cerevisiae and cultured normal human skin fibroblasts. 3-Carbethoxyhomopsoralen is shown to be a photobiologically active compound capable of effectively photoinducing cytoplasmic "petite" mutants (mitochondrial damage), nuclear reversions and mitotic gene conversion in the diploid yeast strain D₇. Per unit dose it is more effective than 8-MOP and 3-CPs for the induction of cytoplasmic "petite" mutants but less effective than 8-MOP for the induction of nuclear reversions and mitotic gene conversion. A very moderate effect on cell survival is accompanied by a relatively strong genetic activity per viable cell. In human fibroblasts 3-CHPs produces a stronger inhibition of DNA synthesis than 8-MOP and 3-CPs at low doses of 365 nm radiation. During post-treatment incubation human fibroblasts recovered more easily from DNA synthesis and growth inhibitions photoinduced by 3-CHPs than from those photoinduced by 8-MOP. The results are in accord with the notion that 3-CHPs is a highly photoreactive monofunctional compound inducing easily repairable lesions with a low lethal but significant mutagenic potential.     

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.     

SOME PROPERTIES OF THE TRIPLET EXCITED STATE OF THE PHOTOSENSITIZING FUROCOUMARIN: 3-CARBETHOXYPSORALEN

Abstract— 3-Carbethoxypsoralen (3-CPs) has been tested in the photochemotherapy of psoriasis. It only forms monoadducts with DNA and is being considered as a non-carcinogenic alternative to 8-MOP which itself forms DNA crosslinks that arc difficult to repair. Using laser flash photolysis or pulse radiolysis, the triplet state of 3-CPs, a possible intermediate in photosensitization, has been generated in several solvents: ethanol, water and benzene. The triplet lifetime, extinction coefficient and quantum efficiency of formation have been measured. Triplet reactivities towards (i) the solvents used, (ii) 3-CPs, (iii) oxygen, (iv) tryptophan and (v) tyrosine, leading, respectively, to photoadditions with water, ethanol and 3-CPs, to ¹O₂, semioxidized tryptophan and semioxidized tyrosine, (vi) thymine and (vii) uracil have been investigated. The dark binding of 3-CPs to DNA has been studied by comparing the reactivity of e_aq^- with free 3-CPs, free DNA and the 3-CPs DNA complex. Some photophysical and photochemical properties of 4',5'di-hydro-3-carbethoxypsoralen(DH–3-CPs), model of the main fluorescent photo-product of 3-CPs, have also been investigated. Biological consequences of the photochemical properties of 3-CPs andDH–3-CPs have been studied in a cellular system (haploid yeast).