Photochemical, photophysical and photobiological properties of some methylallopsoralens which are potential agents for photochemotherapy.

Two new trimethylallopsoralens, 4,7,4'- and 4,7,5'-trimethylallopsoralen, form molecular complexes with DNA and by successive UVA (320-400 nm) irradiation photobind monofunctionally to the macromolecule. The DNA photobinding rates at 365 nm and photobinding quantum yields at 330 nm are markedly higher for 4,7,4'-trimethylallopsoralen than for 4,7,5'-trimethylallopsoralen. Their capacities to generate singlet oxygen in water and benzene are low, particularly for 4,7,4'-trimethylallopsoralen, and the two trimethylallopsoralens completely lack skin phototoxicity on guinea-pig skin. Both compounds show antiproliferative activity in terms of DNA synthesis inhibition in Ehrlich cells and T2 phage infectivity higher than that displayed by angelicin. In view of its monofunctional character, lack of skin phototoxicity, low singlet oxygen yield and antiproliferative activity, 4,7,4'-trimethylallopsoralen deserves further clinical studies as a potential photochemotherapeutic agent.

New studies on the interaction between 8-methoxypsoralen and DNA in vitro.

Some aspects of the interactions between DNA and 8-methoxypsoralen (8-MOP) in its ground state (complex formation) or in its excited state (photobinding) have been investigated. 8-MOP shows a low affinity towards DNA in the complex formation; this fact minimizes the possible biological consequences deriving from this interaction, when it occurs in vivo. In covalent photobinding to DNA, 8-MOP forms mainly monofunctional adducts, and to a lesser extent bifunctional adducts, showing a behavior similar to that of other linearly condensed furocoumarins (psoralens); the ratio between mono- and bifunctional adducts was found to be 9:1. The covalent photobinding to DNA does not occur at random along the macromolecule, but preferentially at the level of specific receptor sites. The regions having an alternate sequence of A-T seem to be the best receptor sites for the formation of monoadducts while the regions containing an alternate sequence of A-T and C-G appeared to be the preferential sites for the cross-linkage formation.

Methylangelicins: new potential agents for the photochemotherapy of psoriasis. Structure-activity study on the dark and photochemical interactions with DNA.

The interactions both in the ground and in the excited state between various methylangelicins, previously prepared with the aim to increase the low photobiological activity of the parent angelicin 1, and DNA have been studied. In general, the new methylangelicins show an increased capacity to photobind monofunctionally to DNA and a parallel increment of photobiological activity in comparison with the parent 1. This increase appears to be connected with various factors, such as the augmented affinity toward DNA for the dark complex formation and the electronic effect connected with the introduction into 1 of one or two methyl groups. The new compounds, on the basis of their photobiological activity and their lack of skin phototoxicity, appear as possible agents for the photochemistry of skin diseases characterized by cell hyperproliferation.

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.

4'-Methylangelicins: new potential agents for the photochemotherapy of psoriasis.

Three derivatives of angelicin (1) [4'-methyl-, 4,4'-dimethyl-, and 4',5-dimethylangelicin (2a-c)] have been prepared with the aim of obtaining new agents for the photochemotherapy of psoriasis. These compounds form a complex in the dark with DNA that shows an affinity for the macromolecule higher than that of the parent angelicin (1). A correlation between their octanol/water partition coefficients and the association constants of the complexes has been observed. Compounds 2a-c photobind to DNA to a much higher extent than 1 and also more effectively than 8-methoxypsoralen (8-MOP), taken as reference compound. When activated with UV-A, the three compounds strongly inactivate T2 phage and inhibit epidermal DNA synthesis in mice. Moreover, they show a mutagenic activity markedly lower than that of 8-methoxypsoralen on Escherichia coli wild-type strain. Due to its lack of skin phototoxicity, its low mutagenic activity, and its antiproliferative activity, 2c was chosen for clinical evaluation. It proved to be effective in clearing psoriasis in two patients.

New monofunctional reagents for DNA as possible agents for the photochemotherapy of psoriasis: derivatives of 4,5'-dimethylangelicin.

With the aim of obtaining new agents for the photochemotherapy of psoriasis, we have prepared monofunctional reagents for DNA by starting from 4,5'-dimethylangelicin (2), an angular furocoumarin, and introducing in a 4'-(hydroxymethyl) (3), 4'-(methoxymethyl) (4), or 4'-(aminomethyl) group (5), in way analogous to what other authors have done previously on trioxsalen, a DNA bifunctional reagent. These new compounds form complexes with DNA in the ground state and by successive irradiation (UV-A) undergo monofunctional photoaddition to the macromolecule. Photobinding to DNA was highest for 3 and gradually lower for 4 and 5, respectively. These compounds do not form interstrand photocross-linkages in DNA and do not show any skin phototoxicity. Fluorimetric studies show that their 4',5' double bond is involved in the photoaddition to DNA. Their photobiological activity evaluated on Ehrlich ascites tumor cells and on T2 phages was strictly connected with their photobinding to DNA. The effect of the introduction of hydroxymethyl and methoxymethyl groups in angular 2 is somewhat similar to that previously described for trioxsalen: the introduction of an aminomethyl group in 2 markedly increases the affinity in the dark for DNA but under UV-A irradiation strongly inhibits photobinding to the macromolecule. By contrast, in the analogous derivative of trioxsalen both the affinity for DNA in the dark and the photobinding to DNA increased.

6-Methylangelicins: a new series of potential photochemotherapeutic agents for the treatment of psoriasis.

The possible presence of methylpsoralens as undesired inquinants in synthetic methylangelicins has been avoided through a synthetic pathway starting from umbelliferones carrying a methyl group in the 6-position. The new 6-methylangelicins show a high affinity toward DNA, forming in the dark a molecular complex; the complexed angelicins under UV-A irradiation photobind effectively to the macromolecule, forming only monoadducts. The new compounds show an evident antiproliferative activity by inhibiting DNA synthesis on Ehrlich cells; great differences, however, can be seen between the various compounds. All the compounds are lacking of skin erythemogenic activity. Some of the new 6-methylangelicins, evaluated in terms of mutagenic activity, demonstrate to be less effective than 8-methoxypsoralen (8-MOP), used for a comparison. On the basis of antiproliferative activity, lack of skin phototoxicity, and low mutagenicity, two compounds have been chosen for clinical evaluation. The compounds tested on seven psoriatic patients by topical application and UV-A irradiation proved to be more effective than 8-MOP, used in the same conditions.

Dark and photochemical interactions of dimethyltetrahydrobenzoangelicin with DNA.

A study of dark interaction and photoreaction between 4,6-dimethyltetrahydrobenzoangelicin (THBA) and DNA is described. 4,6-Dimethyltetrahydrobenzoangelicin is a furocoumarin derivative in which 4' and 5' carbons are linked by a four-methylene bridge. In spite of the bulky aliphatic ring, THBA forms a complex with DNA in the dark and, on UVA irradiation, reacts with pyrimidine bases of DNA yielding monoadducts only involving its furan side double bond. Two main photoproducts form: they derive from a C4-cycloaddition to thymine and cytosine, respectively, and account for 56% and 39% of the total photoreaction yield. Both show cis-syn configuration. Two other isomers, one with thymine and one with cytosine, formed with so much lower yield (ca 3 and 1%, respectively) that their structure could not be assigned. Furthermore, in spite of its angular structure, THBA induces a small number of crosslinks in DNA.

Acridizinium salts as a novel class of DNA-binding and site-selective DNA-photodamaging chromophores.

It was demonstrated that the interaction of the aminoacridizinium salts 2a-2d with DNA depends on the substitution pattern of the chromophore. Spectrophotometric and fluorometric titrations of the acridizinium salts 2a-2d with natural and synthetic polynucleotides reveal that the degree of interaction of the acridizinium salts 2a-2d with the nucleic acid differs significantly. The binding mode of the dyes with DNA was evaluated by circular dichroism and linear dichroism spectroscopy and compared with the parent system 2c. Whereas the 9-aminoacridizinium (2a) mainly intercalates into DNA, the salts 2b-c show a higher degree of association to the DNA backbone. The intercalated aminoacridizinium 2a caused few strand breaks upon UVA exposure, whereas the salts 2b-2d exhibit relatively efficient DNA-damaging properties. All acridizinium salts showed a sequence-selective strand cleavage for guanine-rich DNA regions.

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.

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.

4-tert-butylperoxymethyl-9-methoxypsoralen as intercalating photochemical alkoxyl-radical source for oxidative DNA damage.

We describe the synthesis of a novel psoralen peroxide 1 that generates on irradiation (350 nm) alkoxyl radicals, namely tert-butoxyl radicals, as confirmed by electron spin resonance studies with the spin trap 5,5-dimethyl-pyrroline-N-oxide. The radical source intercalates into the DNA, which has been demonstrated by linear-flow-dichroism measurements. Thus, the alkoxyl radicals are formed advantageously directly in the DNA matrix. In supercoiled pBR322 DNA, the generation of strand breaks by the photochemically or metal-catalyzed generated alkoxyl radicals is demonstrated. Photosensitization by the psoralen chromophore was excluded because similar substances that do not release radicals caused no DNA damage, nor were the photoproducts of the peroxide 1 active. With calf thymus DNA, 8-oxoGua and small amounts of guanidine-releasing products, e.g. oxazolone, were observed. However, in these reactions the photoproduct also displayed some DNA-oxidizing capacity.

Studies on the interaction between steffimycins and DNA.

The complexes formed between steffimycins and DNA were studied using various physicochemical techniques. The binding process has been followed spectrophotometrically or fluorimetrically. The binding parameters n and K, evaluated according to McGhee and Von Hippel, show a good affinity of these antibiotics for the macromolecule. Flow dichroism measurements showed that in the complex with DNA, the antracycline moiety of the steffimycins is intercalated between two base pairs of the macromolecule. The binding experiments with various polydeoxyribonucleotides and with various DNA samples, having different base pair compositions, suggest that an alternate sequence of A-T, such as that of poly[d(A-T)] . poly[d(A-T)], represents a good receptor site for the binding of steffimycins to DNA. The lack of in vivo activity of these antibiotics is discussed.

Receptor sites in DNA for the dark and photochemical interactions with 4,5'-dimethylangelicin, a potential agent for the photochemotherapy.

The study of the interactions in the ground state between 4,5'-dimethylangelicin, an angular furocoumarin, and various synthetic and natural DNA samples have evidenced the presence in the macromolecule of preferred sequences suitable for binding the small ligand. They are represented by an alternate sequence of purine and pyrimidine bases in each strand of the macromolecule, without difference between the two base pairs A-T and C-G. The study of the photochemical interactions between the same DNA samples and the 4,5'-dimethylangelicin shows that preferred sites are present in the macromolecule for the covalent addition of the furocoumarin to the macromolecule too. These sites however have more strict requirements than those useful for dark binding; they are in fact represented by alternate sequences of A-T in each strand such as those present in poly [d(A-T)] . poly-[d(A-T)]. Moreover fluorescence studies made on the same DNA samples irradiated in the presence of the furocoumarin suggest that the alternate C-G regions favour formation of 4'-5'-fluorescent adducts.

In vitro phototoxic properties of new 6-desfluoro and 6-fluoro-8-methylquinolones.

A representative set of potent antibacterial 6-desfluoro-8-methylquinolones, in which the C-6 fluorine atom is replaced by -NH(2) or -H, and their 6-fluoro counterparts, were investigated to evaluate their phototoxic potential and to explore the mechanism behind their phototoxicity. The capacity to photosensitize biological substrates (lipids, proteins, DNA) has been analyzed, as well as their photocytotoxicity on red blood cells and 3T3 murine fibroblasts. The results obtained show that the quinolones studied are able to photosensitize red blood cell lysis in an oxygen-dependent way and induce a high decrease in cell viability after UVA irradiation. A major correlation with phototoxicity lies in the structure of the individual antibacterials and their hydrophobicity; in particular, 6-amino derivatives are less phototoxic than corresponding unsubstituted and fluorinated compounds. Cellular phototoxicity was inhibited by the addition of free radical and hydroxyl radical scavengers (BHA, GSH and DMTU), suggesting the involvement of a radical mechanism in their cytotoxicity. A good correlation was observed between lipid peroxidation and phototoxicity, indicating that the test compounds exert their toxic effects mainly in the cellular membrane. Preliminary experiments on pBR322 DNA show that these derivatives do not photocleave DNA, differently from the two photogenotoxic fluoroquinolones, ciprofloxacin and lomefloxacin, used as reference compounds.

6-Aminoquinolones: photostability, cellular distribution and phototoxicity.

Three selected aminoquinolones endowed with a potent antibacterial (compounds 1 and 2) and antiviral activity (compound 3) have been evaluated for their phototoxic properties in vitro. Photostability studies of these compounds indicate that compound 3 is photostable whereas compound 1 and in particular, compound 2 are rapidly photodegraded upon UVA irradiation, yielding a toxic photoproduct. Intracellular localization of these compounds has been evaluated by means of fluorescence microscopy using tetramethylrhodamine methyl ester and acridine orange, which are specific fluorescent probes for mitochondria and lysosomes, respectively. No co-staining was observed with lysosomal stain for all the test compounds. On the contrary compound 3 was found to be specifically incorporated in mitochondria. The compounds exhibited remarkable phototoxicity in two cell culture lines: human promyelocytic leukaemia (HL-60) and human fibrosarcoma (HT-1080). The quinolone-induced photodamage was also evaluated measuring the photosensitizing cross-linking in erythrocyte ghost membranes, the strand breaks activity and oxidative damage on plasmid DNA. The results show that these derivatives are able to photoinduce crosslink of erythrocytes spectrin, whereas do not significantly photocleavage DNA directly, but single strand breaks were observed after treatment of photosensitized DNA with two base excision repair enzymes, Fpg and Endo III respectively.

8-Azapsoralen derivatives: isolation and characterization of the furan-side cycloadducts with DNA.

The formation of C4-cycloadducts by photoreaction of eight methyl derivatives of 8-azapsoralen with DNA was studied. The main reaction involves the furan ring of the compounds and the 5,6 double bond of thymine giving cis-syn adducts, although a minor amount of a cycloadduct with cytosine was also isolated for 4,4'-dimethylazapsoralen. The role of the nitrogen atom appears to depend on the electronic effect, leading to a decrease in the reactivity of the pyrone ring. As with psoralens, the methyl groups increase both the lipophilicity and, with the exception of the 5,4',5'-trimethyl derivative, the photoreactivity. However, methyl groups do not appear to influence the chemistry of the photoaddition.

Genetic effects and repair of DNA photo-adducts induced by 8-methoxypsoralen and homopsoralen (pyranocoumarin) in diploid yeast.

The relationship between DNA mono- and di-adducts and genetic effects induced by the pyranocoumarin 8,8-desmethylxanthyletine (homopsoralen) HP and 365 nm radiation (UVA) was investigated in the diploid yeast strain D7 (Saccharomyces cerevisiae) taking 8-methoxypsoralen (8-MOP) as a reference compound. The number of DNA cross-links (CLs) induced was determined using alkaline step elution analysis. The induction and removal of total photo-adducts was followed using radioactively labelled compounds. HP showed the same photobinding capacity as 8-MOP. As a function of UVA dose, it was less effective than 8-MOP for the induction of CLs and genetic effects. However, as a function of CLs induced, HP was shown to be more effective for the induction of lethal effects and mitotic recombination than 8-MOP but equally effective for the induction of mutations. The results suggest that, although CLs are recognized as genetically effective lesions, at a given number of CLs, HP induced mono-adducts efficiently contribute to the induction of lethal effects and mitotic recombination but less to the induction of mutations. Using a re-irradiation protocol, HP was brought to yield the same relative amounts of CLs at the same number of total adducts as single UVA exposures with 8-MOP. In these conditions, mutation induction and the kinetics for the removal of photo-adducts were the same for both agents indicating that not only the removal of adducts but also mutation induction are highly dependent on the relative level of CLs induced.

Characterization of psoralen-oleic acid cycloadducts and their possible involvement in membrane photodamage.

By UVA irradiation of an ethanol solution of psoralen and oleic acid, four main photoproducts have been isolated and characterized: two have cis,cis structure; the other two are trans,cis. The same adducts have been isolated from the photoreaction of psoralen with beta-oleoyl-gamma-stearoyl-1-alpha-phosphatidylcholine followed by enzymatic hydrolysis with phospholipase A2. The four isomers stimulate protein kinase C to almost the same extent.

Psoralen-fatty acid cycloadducts activate protein kinase C (PKC) in human platelets.

The C4-photocycloadduct psoralen-linolenic acid activates protein kinase C (PKC), in human platelets, which in turn phosphorylates 47 kDa protein, representing its major substrate in these cells. This behaviour is similar to that shown by diacylglycerol, a main second messenger responsible of various biological effects, e.g. of melanogenesis.