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.

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.

Photobiological properties of 1-(3'-hydroxypropyl)-4,6,8-trimethylfur.

A new furoquinolinone derivative, 1-(3'-hydroxypropyl)-4,6,8-trimethylfuro[2,3-h]quinolin-2(1H)-one (HPFQ, 4), was prepared, in which the nitrogen atom in position 1 carries a hydroxypropyl chain. The antiproliferative activity of HPFQ was studied in comparison with its analogue 1,4,6,8-tetramethylfuro[2,3-h]quinolin-2(1H)-one (FQ) and 8-methoxypsoralen (8-MOP). By incubation in the dark, HPFQ, although retaining antitopoisomerase II activity, appeared less effective than FQ. Upon UVA irradiation, HPFQ produced little amounts of singlet oxygen, but detectable levels of superoxide anion; like FQ, HPFQ induced numbers of DNA-protein cross-links, but no interstrand cross-links in mammalian cells. The HPFQ phototoxicity was comparable to that of FQ and 8-MOP, while mutagenic activity, scored in two Escherichia coli strains, seemed much less remarkable.

Synthesis and biological activity of (hydroxymethyl)- and (diethylaminomethyl)benzopsoralens.

Some benzopsoralens, carrying a hydroxymethyl or a diethylaminomethyl group at the 3, 5, 8, and 11 positions, were prepared, and their biological activity was compared with that of 4-(hydroxymethyl)benzopsoralen (BP). 5-(Hydroxymethyl)benzopsoralen (7b), 11-(hydroxymethyl)benzopsoralen (7c), and 11-(diethylaminomethyl)benzopsoralen (8c) induced marked antiproliferative effects in mammalian cells by simple incubation in the dark; this activity appeared to be related to their ability to inhibit topoisomerase II. Benzopsoralens appeared to be more active, especially BP and 7c, upon UVA activation. Compounds carrying a methyl group at the 4 position together with a hydroxymethyl or diethylaminomethyl at the 8 position (7d and 8d, respectively) were also effective, although to a lower extent; instead, a substituent at the 3 position canceled all activity. Benzopsoralens did not induce interstrand cross-links in DNA in vitro, as seen in the induction of cytoplasmic <> mutations and double-strand breaks in yeast. This behavior is also compatible with their low mutagenic activity in E. coli WP2 and with the absence of any phototoxicity on the skin. For these features, benzopsoralens seem to be interesting potential drugs for PUVA photochemotherapy and photopheresis. The activity shown in the dark is not sufficient for their possible use as antitumor drugs, but it does offer a new model for the study of topoisomerase inhibitors.

Synthesis and biological properties of a new series of N-pyrido substituted tetrahydrocarbazoles.

A series of methyl and ethyl quaternary pyridiniumtetrahydrocarbazoles was synthesized and studied in comparison with ellipticine, chosen as a reference. In general, their antiproliferative activity, tested in different biological substrates, appeared to be higher than that of the corresponding non-quaternarized compounds. This fact could be attributed to the introduction of a positive charge in the molecule, which can stabilize the molecular complex they form with DNA. In a prokaryotic system, the T2 bacteriophage, both quaternarized and non-quaternarized compounds inhibited its infectivity moderately, in a similar way to ellipticine. This effect seemed to be connected to a direct activity on the virions rather than on the indicator bacteria. In mammalian cells, the pyridiniumtetrahydrocarbazoles were more effective. In particular, they appeared to be very active in inhibiting DNA synthesis in Ehrlich ascites cells; some of them were as effective as ellipticine. However, pyridiniumtetrahydrocarbazoles were less active in comparison with ellipticine when their capacity for inhibiting the clonal growth in Chinese hamster ovary (CHO) cells was tested. A similar picture was obtained studying the formation of chromosome aberrations and of sister chromatid exchanges in the same cells. These different responses can be explained considering that the data on DNA synthesis reflect effects only on DNA replication within a short time, without considering any later consequences; on the contrary, in the long-term tests, other events, which lead to cell killing or genotoxicity, can take place. Pyridiniumtetrahydrocarbazoles damage DNA, inducing double-strand breaks efficiently. These observations, together with the data already obtained on unsubstituted derivatives, suggest the pyridiniumtetrahydrocarbazoles induce antiproliferative and genotoxic effects, very probably by inhibiting topoisomerase II.

Photobiological properties of 1'-thieno-4,6,4'-trimethylangelicin.

Some photobiological properties of 1'-thieno-4,6,4'-trimethylangelicin (TTMA), a new isoster of 4,6,4'-trimethylangelicin (TMA) were studied in comparison with the parent compound. The TTMA absorbs UVA light and photobinds in vitro to DNA more efficiently than TMA; however, in Ehrlich cells in vivo TTMA linked to DNA to a lesser extent than the parent compound. In general, the formation of damage into DNA is in line with this last result: In fact, TTMA and TMA form equivalent amounts of interstrand cross-links (ISC) both in vitro in linearized PM2 DNA and in vivo in HeLa cells. In this system TTMA induces DNA-protein cross-links (DPC) more efficiently than TMA; on the contrary, no significant amounts of single-strand breaks were detected with both compounds. The antiproliferative activity of TTMA is consistent with these results, being only slightly more pronounced than that of TMA. Experiments carried out using double irradiation demonstrated that these drugs are capable of inducing antiproliferative effects by biphotonic reactions, including the formation of both ISC and DPC. Thus, replacement of the oxygen atom by a sulfur increases the UV absorption of the drug and its capacity to photobind to DNA in vitro but does not yield a comparable enhancement of its photosensitizing properties in vivo; this might be due to various reasons, for instance to an increase in the lipophilic character that could modify the behavior in vivo.

Synthesis and biological properties of some 2H-1-benzopyrano[7,8-b][1,4]benzodioxin-2-ones.

The synthesis of 2H-benzopyrano[7,8-b][1,4]tetrahydrobenzodioxin-2-ones and 2H-benzopyrano [7,8-b][1,4]benzodioxin-2-ones is reported. This class of compounds, prepared with the aim of obtaining new monofunctional photosensitizing drug, appears to be ineffective upon UVA irradiation but shows a moderate but significant activity in the dark.

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 microM 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.

Photobiological properties of a new tetramethylfuroquinolinone.

1,4,6,8-tetramethyl-2H-furo[2,3-h]quinolin-2-one (FQ) is a new isoster of angelicin characterised by an extremely strong photosensitizing activity, which is several times higher than that of 8-MOP and 4,6,4'-trimethylangelicin (TMA). Following treatment with 1.2 microM FQ and a dose as low as 0.05 kJ m(-2) of UVA irradiation, survival (colony forming ability) of HeLa cells was abolished, while TMA and 8-MOP (even at five times the concentration for the latter) were practically ineffective. Upon UVA irradiation FQ induces various types of lesions in mammalian cells in DNA: single-strand breaks (SSBs), many monoadducts and covalent DNA-protein cross-links (DPC), but not interstrand cross-links (ISC). Using the two step irradiation procedure, DPC induced by FQ appeared to be severe lesions, having a high antiproliferative activity; their formation requires the successive absorption of two photons, thus, in this respect, resembling ISC formation. In spite of its higher capacity for damaging DNA, FQ showed a skin-phototoxicity potency very similar to 8-MOP. As some benzopsoralens, FQ induced a certain antiproliferative activity also in the dark, which was accompanied by the formation of double-strand breaks into DNA associated with DPC. This lesion is generally induced by topoisomerase inhibitors. On the basis of these features, FQ can be expected to show useful activities in photochemotherapy and photopheresis. However, before medical use careful studies on its genotoxicity are required.

Angular furoquinolinones, psoralen analogs: novel antiproliferative agents for skin diseases. Synthesis, biological activity, mechanism of action, and computer-aided studies.

With the aim of obtaining new potential photochemotherapeutic agents, having increased antiproliferative activity and decreased undesired effects, we have prepared some new furoquinolinones. Two of them have been studied in detail: 1,4,6,8-tetramethyl-2H-furo[2,3-h]-quinolin-2-one (8), and 4,6,8,9-tetramethyl-2H-furo[2,3-h]quinolin-2-one (10). These compounds form a molecular complex with DNA, undergoing intercalation inside the duplex macromolecule, as shown by linear flow dichroism. The complexed ligands, by subsequent irradiation with UV-A light, photobind with the macromolecule forming only monocycloadducts with thymine with cis-syn configuration. In order to evaluate the electronic effects induced by the nitrogen atom in position 1 of 8, semiempirical calculations have been performed on both 4,6,4'-trimethylangelicin (TMA) and 8. The results obtained do not clearly differentiate between the two molecules which, at this level of approximation, show the possibility of photoreaction with both the 3,4- and 8,9-olefinic bonds for 8 and the 3,4- and 4',5'-bonds for TMA. In the lower energy conformation of intercalated 8, the furan ring is turned toward the minor groove of the polynucleotide, in such a way that photoreaction of this ring with thymine is favored. These compounds unexpectedly inhibit DNA and RNA synthesis in Ehrlich cells, in the dark. They also show a strong photoantiproliferative activity, 2 orders of magnitude higher than 8-methoxypsoralen (8-MOP), the most used drug for photochemotherapy. Their mutagenic activity on Escherichia coli is similar to that of TMA and 8-MOP. On the basis of these results, the compounds should deserve evaluation of their activity in the treatment of hyperproliferative skin diseases.

Antiproliferative activity of some unsubstituted angular analogoues of ellipticine.

With the aim of obtaining further knowledge on the antiproliferative activity of pyrroloquinolines and isoquinolines, we prepared four unsubstituted angular pyridotetrahydrocarbazoles having a fourth non-aromatic ring, via modified Fischer synthesis. These compounds may be considered as simpler analogues of ellipticine. They induced evident antiproliferative effects in Ehrlich ascites and in CHO cells in vitro, but were ineffective on T2 bacteriophage. These compounds formed molecular complexes with DNA in vitro, while in CHO cells in vivo, they induced double-strand breaks in DNA and DNA-protein cross-links. These data suggest that these ellipticine analogoues are capable of inhibiting topoisomerase II, as the parent compound does. The most active derivative was 2N-5H-6,7,8,9-tetrahydropyrido[2,3-a]carbazole, which represents an interesting model for the study of new antitumor drugs.

DNA damage and topoisomerase II inhibition induced by a benzopsoralen derivative.

The ability of 4-hydroxymethyl-4',5'-benzopsoralen (HMBP) to damage DNA of Chinese hamster ovary cells (CHO) and to inhibit the activity of topoisomerase II in vitro has been studied. This compound is characterized by a fourth ring condensed at the furan-side in the psoralen molecule. Contrary to other known furocoumarin derivatives, HMBP induces chromosomal aberrations in mammalian cells without UVA activation. The lesions induced in the dark by HMBP in DNA were studied by alkaline and neutral elution in CHO cells; comparable amounts of single-strand breaks and DNA-protein cross-links as well as the formation of double-strand breaks were detected. Moreover, HMBP appeared to inhibit the activity of mammalian topoisomerase II in vitro, in both the catenation and the decatenation assay. In these experiments the drug was effective only when it was pre-incubated with DNA substrate. These results are also consistent with the cytotoxic and mutagenic activity of HMBP in the dark, as tested on V79 Chinese hamster cells (V79/HGPRT system).

4,6,4'-Trimethylangelicin induces interstrand cross-links in mammalian cell DNA.

4,6,4'-Trimethylangelicin, a well-known effective photosensitizer described as a pure monofunctional reactant with DNA, can induce interstrand cross-links in mammalian cell DNA in vivo (about 15% relative to 8-methoxypsoralen), as observed using alkaline elution and Chinese hamster ovary cells. Experiments performed using the two-step irradiation method and HeLa cells support these data. In contrast with 4,6,4'-trimethylangelicin, 4'-methylangelicin and 4,4'-dimethylangelicin do not form interstrand cross-links. These results are consistent with those recently reported by Chen et al. (X. Chen, J. Kagan, F. Dall'Acqua, D. Averbeck and E. Bisagni, J. Photochem. Photobiol. B: Biol, 22 (1994) 51-57) using pBR322 and M13 DNA. The cross-linking ability of 4,6,4'-trimethylangelicin does not seem to be related to a particular feature of these DNAs but to the compound itself.

Pyrroloquinolinone methylderivatives, furocoumarin analogues: synthesis and biological activity.

Searching new photochemotherapeutic agents, a series of methylpirroloquinolinones were prepared by a new synthetic pathway, thus univocally obtaining the title compounds. The photobiological activity of some of these compounds was assayed; upon UVA activation, a marked capacity of inhibiting macromolecular synthesis in Ehrlich cells was observed, which appeared to be markedly high testing protein synthesis. Pyrroloquinolinones induced a strong inhibition of the clonal growing capacity of HeLa cells cultivated in vitro. Studying DNA photodamage in HL60 cells high amounts of single strand breaks and DNA-protein cross-links were detected. Pyrroloquinolines inhibited T2 bacteriophage infectivity, but induced no significant amounts of revertants in E. coli WP2 TM9, a strain very sensitive to DNA damage. On the contrary, 8-MOP, tested in the same experimental conditions exhibited an evident photomutagenecity. These data suggest that pyrroloquinolines induced antiproliferative effects by a mechanism in which DNA-photobinding practically does not takes place, and therefore different from that shown by known furocoumarins. Pyrroloquinolinones showed also a moderate antiproliferative activity in the dark.

2,6-Dimethyl-9-methoxy-4H-pyrrolo[3,2,1-ij]quinolin-4-one, a new compound with unusual photosensitizing properties.

Some photobiological properties of 2,6-dimethyl-9-methoxy-4H-pyrrolo[3,2,1-ij]quinolin-4-one (PQ) have been studied in comparison with 8-methoxypsoralen (8-MOP). In Ehrlich cells, PQ induced a moderate inhibition in DNA and RNA syntheses in the dark, which appeared to be more pronounced upon UVA irradiation. In contrast to 8-MOP, in the presence of UVA, PQ also affected protein synthesis. Likewise marked antiproliferative effects were also observed in the study of the clonal growth of CHO cells cultivated in vitro. Using alkaline elution and CHO cells, a moderate formation of single-strand breaks (SSBs) and of DNA-protein cross-links (DPCs) was observed by incubation in the dark; upon UVA irradiation the amount of both lesions increased greatly, whereas no inter-strand cross-links (ISCs) were formed. As expected, 8-MOP did not damage DNA in the dark, but induced SSBs, ISCs and DPCs in the presence of UVA. The induction of SSBs by both compounds seems to be directly related to a photochemical event rather than to incisions during DNA repair. As the induction of ISCs, and also the formation of DPCs by 8-MOP and UVA, appears to be based on a two-step reaction involving photo-bound 8-MOP-DNA moieties. In contrast, the formation of DPCs by PQ and UVA seems to involve photosensitization by free PQ molecules connected with SSB and DPC formation rather than with a DNA photo-binding activity. The PQ activity observed in the dark could probably be ascribed to a moderate inhibition of topoisomerases.

Preparation and properties of monomethoxy poly(ethylene glycol) doxorubicin conjugates linked by an amino acid or a peptide as spacer.

Polymeric doxorubicin prodrugs were prepared linking monomethoxy poly(ethylene glycol), 5000 D molecular weight, to the doxorubicin amino group, using an amino acid or a peptide as a spacer arm. As spacers glycine, L-phenylalanine, L-tryptophan and glycil-L-valil-L-phenylalanine were used. The conjugates showed enhanced stability to alkaline degradation compared to the free doxorubicin. Towards Ehrlich solid tumor in mice the glycin spaced derivative was devoid of activity, whereas the phenylalanine and tryptophan derivatives were 20% and 16% active and the tripeptide one 50% active with respect to free doxorubicin. On the other hand the derivatization was accompanied by a great decrease of toxicity in mice with respect to the free drug. Doxorubicin was not released from conjugates by chymotrypsin incubation or in plasma.

Furocoumarin sensitization induces DNA-protein cross-links.

The capacity of some linear and angular furocoumarins to induce DNA-protein cross-links by UVA (320-400 nm) irradiation has been evaluated in Chinese hamster ovary cells. Two linear furocoumarins, psoralen and 8-methoxypsoralen appeared to be capable of inducing DNA-protein cross-links to a noticeable extent. 4'-Methylangelicin and 4,4'-dimethylangelicin formed only reduced amounts of DNA-protein cross-links, while angelicin and 4,6,4'-trimethylangelicin seemed to be unable to induce significant levels of this lesion. The biological significance of this damage remains to be elucidated, but it might have an important role in furocoumarin sensitization. In the examined compounds, the capacity for inducing DNA-protein cross-links appears to be a property of the skin phototoxic furocoumarins. This result suggests the hypothesis of a connection between this damage and the formation of skin erythemas.

2-substituted 1H-pyrrolo [3,2-h] quinoline derivatives: synthesis and aspects of their biological activity.

Certain 2-substituted 1H-pyrrolo [3,2-h] quinolines have been prepared and their biological activity in mammalian cells and in some microorganisms have been studied. These compounds represent a simplified ellipticine heterocyclic moiety: in addition they have a different ring condensation, leading to an angular molecular structure instead of a linear one. In mammalian cells all compounds appeared to be able of inducing an antiproliferative effect and an extensive DNA fragmentation, similarly to ellipticine, even if to a reduced extent. The new derivatives behaved in a comparable way also on some microorganisms, such as T2 bacteriophage (which appears to be less sensitive than mammalian cells) and in mutagenesis tests carried out with E. coli WP2 TM9 and S. typhimurium TA 98, which are reverted by base substitution and frame-shift mutagens, respectively. Similarly to the reference compound, all ellipticine analogues appeared to be no mutagenic. The obtained results suggest that they induce the antiproliferative activity in mammalian cells mainly as topoisomerase inhibitors, similarly to ellipticine itself. Therefore, they represent an interesting model to design new potential anticancer drugs.

Photobiological activity of certain new methylazapsoralens.

The photobiological activity of a series of psoralen isosters carrying a nitrogen atom at 8 position, new potential drugs for the photochemotherapy of hyperproliferative skin diseases, have been studied; the more active derivatives appeared to be 5,4'-dimethyl-8-azapsoralen and 3,4,4'-trimethyl-8-azapsoralen which induced a strong inhibition of DNA synthesis in Ehrlich ascites cells, very similar to that provoked by 8-methoxypsoralen, the furocoumarin at present used in photochemotherapy. Such compounds induced a small amount of inter-strand DNA cross-links and were non phototoxic when assayed on guinea-pig skin; however, both derivatives appeared to be highly mutagenic in E. coli WP2 TM6. This strain contains the plasmid R46 and it is proficient in DNA repair, and therefore monoadducts do not should be mutagenic in such a strain. Because the first steps of excision, which remove monoadducts, and of the main cross-link repair use the same enzymes (produced by the uvrABC complex), in the presence of a great number of monofunctional lesions, it is possible that there are not sufficient enzyme molecules for removing cross-links according this pathway, which could be repaired by a second one, uvrABC independent and based on glycosilase activity, which works at reduced levels and is much less accurate.

Biological properties of some benzopsoralen derivatives.

The biological activity of some benzopsoralen derivatives, prepared with the aim of obtaining new drugs for photochemotherapy, has been studied. The more interesting compounds are 4-hydroxymethyl-4',5'-benzopsoralen and 4-hydroxymethyl-4',5'-tetrahydro-benzopsoralen, which were found to be active in the dark also: DNA and RNA synthesis were both inhibited in Ehrlich cells, even if in a partially reversible fashion, while protein synthesis remained unaffected. In Chinese hamster ovary cells cultured in vitro, the clonal growth was strongly inhibited by incubation in the dark with both drugs, while a number of chromosomal aberrations was observed in the fraction of growing cells. Using alkaline elution, DNA strand breaks were detected. In addition, in the presence of aphidicolin, a specific inhibitor of DNA polymerase, the clonal growing capacity was completely restored; in contrast, the number of DNA strand breaks remained unchanged. All these results suggest that DNA topoisomerases are probably the target of these two benzopsoralens. These compounds are also good sensitizers; by UV-A irradiation they have a good capacity to produce singlet oxygen, but they appeared to be unable to induce erythemas on guinea-pig skin. Under UV-A light, they induced a strong inhibition of DNA synthesis in Ehrlich cells. Thus, benzopsoralens appear to be capable of inducing strong antiproliferative effects by two different mechanisms, by UV-A irradiation and in the dark.