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.

Stabilisation of self-assembled DNA crystals by triplex-directed photo-cross-linking.

The tensegrity triangle is a robust DNA motif that can self-assemble to generate macroscopic three-dimensional crystals. However, the stability of these crystals is dependent on the high ionic conditions used for crystal growth. Here we demonstrate that a triplex-forming oligonucleotide can be used to direct the specific intercalation, and subsequent photo-cross-linking, of 4,5',8-trimethylpsoralen to single or multiple loci within or between the tiles of the crystal. Cross-linking between the tiles of the crystal improves their thermal stability. Such an approach is likely to facilitate the removal of crystals from their mother liquor and may prove useful for applications that require greater crystal stability.

Synthesis of Oligonucleotides Containing 4,5',8-Trimethylpsoralen at the 2'-O Position and Their Cross-Linking Properties with RNAs.

4,5',8-Trimethylpsoralen-conjugated oligonucleotides have been used in the study of photo-cross-linking with target oligonucleotides and in the field of the photodynamic therapy. This unit describes synthetic procedures for oligonucleotides using 2'-O-methylphosphoramidite units and an adenosine phosphoramidite unit containing a 4,5',8-trimethylpsoralen derivative attached at the 2' position of an adenosine sugar moiety via an ethoxymethylene linkage. Procedures for obtaining the photo-cross-linking efficiency of 2'-O-methyloligonucleotides containing a 4,5',8-trimethylpsoralen derivative with a target oligonucleotide under UV irradiation conditions are also described, together with the procedure for preparation of (32)P-radiolabeled RNA.

Trimethylangelicin reduces IL-8 transcription and potentiates CFTR function.

Chronic inflammatory response in the airway tract of patients affected by cystic fibrosis is characterized by an excessive recruitment of neutrophils to the bronchial lumina, driven by the chemokine interleukin (IL)-8. We previously found that 5-methoxypsoralen reduces Pseudomonas aeruginosa-dependent IL-8 transcription in bronchial epithelial cell lines, with an IC(50) of 10 µM (Nicolis E, Lampronti I, Dechecchi MC, Borgatti M, Tamanini A, Bezzerri V, Bianchi N, Mazzon M, Mancini I, Giri MG, Rizzotti P, Gambari R, Cabrini G. Int Immunopharmacol 9: 1411-1422, 2009). Here, we extended the investigation to analogs of 5-methoxypsoralen, and we found that the most potent effect is obtained with 4,6,4'-trimethylangelicin (TMA), which inhibits P. aeruginosa-dependent IL-8 transcription at nanomolar concentration in IB3-1, CuFi-1, CFBE41o-, and Calu-3 bronchial epithelial cell lines. Analysis of phosphoproteins involved in proinflammatory transmembrane signaling evidenced that TMA reduces the phosphorylation of ribosomal S6 kinase-1 and AKT2/3, which we found indeed involved in P. aeruginosa-dependent activation of IL-8 gene transcription by testing the effect of pharmacological inhibitors. In addition, we found a docking site of TMA into NF-κB by in silico analysis, whereas inhibition of the NF-κB/DNA interactions in vitro by EMSA was observed at high concentrations (10 mM TMA). To further understand whether NF-κB pathway should be considered a target of TMA, chromatin immunoprecipitation was performed, and we observed that TMA (100 nM) preincubated in whole living cells reduced the interaction of NF-κB with the promoter of IL-8 gene. These results suggest that TMA could inhibit IL-8 gene transcription mainly by intervening on driving the recruitment of activated transcription factors on IL-8 gene promoter, as demonstrated here for NF-κB. Although the complete understanding of the mechanism of action of TMA deserves further investigation, an activity of TMA on phosphorylating pathways was already demonstrated by our study. Finally, since psoralens have been shown to potentiate cystic fibrosis transmembrane conductance regulator (CFTR)-mediated chloride transport, TMA was tested and found to potentiate CFTR-dependent chloride efflux. In conclusion, TMA is a dual-acting compound reducing excessive IL-8 expression and potentiating CFTR function.

A method for genome-wide analysis of DNA helical tension by means of psoralen-DNA photobinding.

The helical tension of chromosomal DNA is one of the epigenetic landmarks most difficult to examine experimentally. The occurrence of DNA crosslinks mediated by psoralen photobinding (PB) stands as the only suitable probe for assessing this problem. PB is affected by chromatin structure when is done to saturation; but it is mainly determined by DNA helical tension when it is done to very low hit conditions. Hence, we developed a method for genome-wide analysis of DNA helical tension based on PB. We adjusted in vitro PB conditions that discern DNA helical tension and applied them to Saccharomyces cerevisiae cells. We selected the in vivo cross-linked DNA sequences and identified them on DNA arrays. The entire procedure was robust. Comparison of PB obtained in vivo with that obtained in vitro with naked DNA revealed that numerous chromosomal regions had deviated PB values. Similar analyses in yeast topoisomerase mutants uncovered further PB alterations across specific chromosomal domains. These results suggest that distinct chromosome compartments might confine different levels of DNA helical tension in yeast. Genome-wide analysis of psoralen-DNA PB can be, therefore, a useful approach to uncover a trait of the chromosome architecture not amenable to other techniques.

'RNA walk' a novel approach to study RNA-RNA interactions between a small RNA and its target.

In this study we describe a novel method to investigate the RNA-RNA interactions between a small RNA and its target that we termed 'RNA walk'. The method is based on UV-induced AMT cross-linking in vivo followed by affinity selection of the hybrid molecules and mapping the intermolecular adducts by RT-PCR or real-time PCR. Domains carrying the cross-linked adducts fail to efficiently amplify by PCR compared with non-cross-linked domains. This method was calibrated and used to study the interaction between a special tRNA-like molecule (sRNA-85) that is part of the trypanosome signal recognition particle (SRP) complex and the ribosome. Four contact sites between sRNA-85 and rRNA were identified by 'RNA walk' and were further fine-mapped by primer extension. Two of the contact sites are expected; one contact site mimics the interaction of the mammalian Alu domain of SRP with the ribosome and the other contact sites include a canonical tRNA interaction. The two other cross-linked sites could not be predicted. We propose that 'RNA walk, is a generic method to map target RNA small RNAs interactions in vivo.

Trioxsalen derivatives with lipoxygenase inhibitory activity.

Trioxsalen (TRX) is a 4,5',8-trimethylated psoralen analog presenting interesting biological activities when irradiated with UVA light. A series of TRX derivatives, which where obtained by its chemical modification and incorporation of a variety of unsaturated functions at position 4' of the psoralen ring-system, were evaluated for their antioxidant activity and their inhibitory activity on soybean lipoxygenase (LOX) and lipid peroxidation. The reducing properties of the compounds were evaluated using the 1,1-diphenyl-2-picrylhydrazyl (DPPH) free radical scavenging assay and found to be very low, in the range 0-14%, with the exception of the hydroxamic acid 6 which showed almost identical activity to BHT. TRX derivative 3 significantly inhibited LOX, with IC(50) 9.4 muM. With the exception of TRX, all tested analogs inhibited lipid peroxidation in the range of 35-91%. The most potent compound, namely TRX derivative 3, was studied for its anti-inflammatory activity in vivo on rat paw edema induced by carrageenan, and was found to be of almost identical activity to indomethacin. The results of the biological tests are discussed in terms of structural characteristics.

Efficient processing of TFO-directed psoralen DNA interstrand crosslinks by the UvrABC nuclease.

Photoreactive psoralens can form interstrand crosslinks (ICLs) in double-stranded DNA. In eubacteria, the endonuclease UvrABC plays a key role in processing psoralen ICLs. Psoralen-modified triplex-forming oligonucleotides (TFOs) can be used to direct ICLs to specific genomic sites. Previous studies of pyrimidine-rich methoxypsoralen-modified TFOs indicated that the TFO inhibits cleavage by UvrABC. Because different chemistries may alter the processing of TFO-directed ICLs, we investigated the effect of another type of triplex formed by purine-rich TFOs on the processing of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) ICLs by the UvrABC nuclease. Using an HMT-modified TFO to direct ICLs to a specific site, we found that UvrABC made incisions on the purine-rich strand of the duplex approximately 3 bases from the 3'-side and approximately 9 bases from the 5'-side of the ICL, within the TFO-binding region. In contrast to previous reports, the UvrABC nuclease cleaved the TFO-directed psoralen ICL with a greater efficiency than that of the psoralen ICL alone. Furthermore, the TFO was dissociated from its duplex binding site by UvrA and UvrB. As mutagenesis by TFO-directed ICLs requires nucleotide excision repair, the efficient processing of these lesions supports the use of triplex technology to direct DNA damage for genome modification.

Specific apoptosis induction in human papillomavirus-positive cervical carcinoma cells by photodynamic antisense regulation.

Human papillomavirus type 18 (HPV18) is frequently detected in cervical cancer cells. The viral proteins E6 and E7 are expressed consistently and have oncogenic activities. The E7 protein binds to a tumor suppressor, the retinoblastoma gene product (pRB), however, leading to the stabilization of tumor suppressor, p53 protein. On the other hand, another viral product, E6, forms complexes with p53 and abrogates its function, resulting in tumor progression. These facts imply that the E6 oncogene is one of the ideal targets for directed gene therapy in HPV-positive cervical cancer. In this study, we tried photodynamic antisense regulation of the antiapoptotic E6 expression using a photocross-linking reagent, 4,5',8-trimethylpsoralen, conjugated oligo(nucleoside phosphorothioate) (Ps-S-Oligo). This photodynamic antisense strategy effectively elicited the apoptotic death of HPV18-positive cervical cancer cells through the selective repression of E6 mRNA and consequent stabilization of p53 protein. E7-mediated signals potentially activated the p53 function and mobilized the p53 pathway to deliver pro-apoptotic signals to the cancer cells, leading to the suppression of in vivo tumorigenesis. An extremely low concentration of cisplatin in addition to Ps-S-Oligos further up-regulated p53 activity, provoking massive apoptotic induction. These results suggest that the photodynamic antisense strategy has the great therapeutic potential in HPV-positive cervical cancers.

Psoralen conjugates for visualization of genomic interstrand cross-links localized by laser photoactivation.

DNA interstrand cross-links are formed by chemotherapy drugs as well as by products of normal oxidative metabolism. Despite their importance, the pathways of cross-link metabolism are poorly understood. Laser confocal microscopy has become a powerful tool for studying the repair of DNA lesions that can be detected by immunofluorescent reagents. In order to apply this approach to cross-link repair, we have synthesized conjugates of 4,5',8-trimethylpsoralen (TMP) and easily detected compounds such as Lissamine rhodamine B sulfonyl chloride (LRB-SC), biotin, and digoxigenin. These conjugates are activated by UVA, and we have analyzed the intracellular localization of DNA damage and DNA reactivity by confocal and immunofluorescence microscopy. The LRB-SC-TMP conjugate 2 appeared mainly in the mitochondria, while the biotin-TMP conjugate 4 preferentially localized in the cytoplasm. Adducts formed by UVA and digoxigenin conjugates of TMP 7a and 4,5'-dimethylangelicin (DMA) 7b, which forms only monoadducts, were largely localized to the nucleus. Exposure of cells incubated with 7a and 7b to a 364 nm UV laser directed toward defined nuclear regions of interest resulted in localized adduct formation which could be visualized by immunofluorescence. Repair-proficient cells were able to remove the photoadducts, while repair-deficient cells were unable to repair the damage. The results indicated that the digoxigenin-TMP conjugate 7a and digoxigenin-DMA conjugate 7b can be used for studying the repair of laser localized DNA monoadducts and cross-links.

Enhanced repair of DNA interstrand crosslinks in S phase.

Hela cells synchronized in G1 and S phases of the cell cycle were transfected with pEGFP crosslinked with trioxsalen. Twelve hours later the number of fluorescent cells was determined by fluorescent microscopy. Cells in S phase have repaired 0.2-0.3 ICL/kb over the 12h period, while cells in G1 phase repaired interstrand crosslinks much more poorly. The crosslinked plasmids were efficiently recruited to the nuclear matrix both in G1 phase and S-phase, which showed that the poor repair of G1 cells was a result of a lack of DNA replication rather than of a lack of matrix attachment.

Spectral study of interactions of 4,8,4'-trimethylpsoralen and 4,4'-dimethylangelicin dyes with DNA.

Absorption and fluorescence spectra for six new synthetic dyes of 4,8,4'-trimethylpsoralen and 4,4'-dimethylangelicin derivatives containing various terminal substituents at 5'-position have been investigated in different environments using a wide range of the DNA/ligand concentrations. Various spectral and binding characteristics of the DNA-ligand systems have been determined. General principles characterizing mechanisms responsible for changes in the fluorescent properties of nucleotide-specific dyes have been proposed; they take into consideration chemical structure of the dyes, properties of the environment, and degree of sorption on substrate.

Photoreaction of skin-sensitizing trimethyl psoralen with lipid membrane models.

The concerted photoreaction between trimethyl psoralen (TMP) and isomeric model compounds of oleic acid methyl ester (OAME) and eadilic acid methyl ester (EAME) are explored using density functional theory. The S(1) surfaces all reveal large barriers (25-31 kcal/mol) to reach the decay channels, whereas the S(2) surfaces differ considerably between the furan and pyrone side adducts. For the pyrone side adducts, a small barrier to reach the intersection between the S(1) and S(2) states is found, followed by a small second barrier on the S(1) surface to the low-lying decay channel. For the furan-side adducts, no such intersection between S(1) and S(2) is seen, which thus prevents these products from being formed in high yields. The photoinduced cycloaddition is more favorable between OAME and the pyrone side double bond of TMP than for any of the other systems, which agrees with the experimental findings that this is formed in the highest yield. The computed UV absorption spectra of TMP and the TMP(pyrone)-OAME cycloadduct agree well with the experimental spectra.

Synthesis and properties of photo-reactive antisense oligonucleotides containing 2'-O-psoralen-conjugated adenosine.

In order to selectively regulate mRNA having a point mutation, the photo-reactive antisense oligonucleotides were developed. Two types of photo-reactive oligonucleotides containing adenosine whose 2'-OH was modified with 4,5',8-trimethylpsoralen (psoralen) were synthesized (2'-Ps-oligo). One contains psoralen via a methylene linkage (2'-Ps-met), and the other via an amidomethylene linkage (2'-Ps-amd). 2'-Ps-oligos were then subjected to the photo-cross-linking reaction. 2'-Ps-met cross-linked to the complementary RNA and scarcely did to the RNA having a single mismatch base. Contrarily, 2'-Ps-amd did not cross-link to both RNA strands. These results suggest the structure of the linkage might affect the efficiency of the photo-cross-linking.

Tandem mass spectrometry for the determination of the sites of DNA interstrand cross-link.

Formation of DNA interstrand cross-link is implicated in the mechanism of anticancer activity of some drugs. Here we examined the fragmentation of deprotonated ions of double-stranded oligodeoxynucleotides (ODNs) that are covalently held together with either a mitomycin C or a 4,5',8-trimethylpsoralen. Our results showed that, upon collisional activation, the covalently-bound duplex ODNs cleaved to give a series of wn and [an-base] ions; the sites of interstrand cross-linking could be determined from the mass shifts of some product ions. In addition, compared with the product-ion spectra acquired on an ion trap, those obtained from sustained off-resonance irradiation-collisionally activated dissociation (SORI-CAD) on a Fourier transform mass spectrometer offered high mass-resolving power, which facilitated unambiguous assignment of product ions and made it an effective method for locating the cross-linking sites.

Nucleosome positioning in the human c-Fos promoter analyzed by in vivo footprinting with psoralen and ionizing radiation.

We performed detailed footprinting analysis of nucleosome positioning in the c-FOS promoter of living human fibroblasts. The translational position was determined by terminal transferase-dependent PCR with 4,5',8-trimethylpsoralen. The rotational position was determined by ligation-mediated PCR with ionizing radiation. In the middle of the c-FOS promoter, a nucleosome was positioned not only translationally but also rotationally. The comparison of the results of our in vivo footprinting with those of a previous report on the in vitro footprinting of reconstituted nucleosomes revealed that the major in vivo translational position was approximately 70 bp upstream of the in vitro position, whereas the rotational position was unchanged. The in vivo translational position appears to be strongly influenced by the presence of transcription factors, which may function as boundaries, while the rotational position appears to be determined predominantly by the DNA sequence. We also investigated the influence of the transcriptional activation of the c-FOS gene on the positioning of this nucleosome. Although it is well-known that there are rapid changes in general nuclease sensitivity and chemical modifications of histone in the c-FOS gene upon activation, we could not detect any change in the translational or rotational position of this nucleosome. The nucleoprotein complex in the c-FOS promoter containing the positioned nucleosome and several transcription factors seems to be structurally unaltered upon activation, despite the rapid chemical modifications of the nucleosome and some of the transcription factors.

Structure elucidation of DNA interstrand cross-link by a combination of nuclease P1 digestion with mass spectrometry.

DNA interstrand cross-link reagents are among the most powerful agents for cancer treatment. Here we report a combined nuclease P1 digestion/mass spectrometry method for the structure elucidation of duplex oligodeoxynucleotides (ODNs) containing an interstrand cross-link. Our results demonstrate that nuclease P1 digestion of a double-stranded ODN containing an interstrand cross-link (ICL) of 4,5',8-trimethylpsoralen or mitomycin C gives a tetranucleotide bearing the cross-linked nucleobase moiety. Product ion spectra of the deprotonated ions of the tetranucleotides provide information about the structure of the cross-link. Furthermore, product-ion spectra of tetranucleotides containing two orientation isomers of mitomycin C interstrand cross-link are distinctive. We believe that the method described in this paper can be generally applicable for investigating the structures of other DNA ICLs.

Amino acids in SRS1 and SRS6 are critical for furanocoumarin metabolism by CYP6B1v1, a cytochrome P450 monooxygenase.

CYP6B1v1 is the principal cytochrome P450 monooxygenase (P450) that detoxifies dietary furanocoumarins in the guts of Papilio polyxenes, the black swallowtail caterpillar. Sequence alignments and structure comparisons of CYP6B1v1 with the mouse CYP2A5 and bacterial CYP102 proteins, which are also capable of metabolizing the linear furanocoumarin xanthotoxin (8-methoxypsoralen), suggested that Phe116, His117, Val368 and Phe484 might be active site residues. In a homology model developed for CYP6B1v1, the side chains of Phe116 and His117 located in the B'-C loop of SRS1 are predicted to be positioned above the haem plane, while the side chain of Phe484 located in SRS6 is predicted near the entrance of the catalytic pocket. Site-directed mutagenesis of residues Phe116, His117 and Phe484 indicated that these residues represent several of those that determine this protein's stability and substrate specificity. Whereas all aromatic mutants of Phe116 and Phe484 generated CO-difference spectra with maxima at 450 nm indicative of correctly configured monooxygenases, aromatic mutants of Phe116 exhibited reduced reactivities toward some furanocoumarins and aromatic mutants of Phe484 eliminated all reactivities toward furanocoumarins. All single and double aliphatic mutants of Phe116, His117 and Phe484 and aromatic mutants of His117 generated carbon monoxide (CO) difference spectra with maxima at 420 nm (P420) indicative of incorrectly configured monooxygenases. These studies define residues Phe116, His117 and Phe484 as determinants of this insect P450's catalytic site integrity and residues Phe116 and Phe484 as determinants of its substrate specificity. Conservation of Phe116 and His117 in an array of lepidopteran CYP6B proteins implies that these amino acids serve a similar function in other monooxygenases of the insect CYP6B subfamily.

Mapping psoralen cross-links at the nucleotide level in mammalian cells: suppression of cross-linking at transcription factor- or nucleosome-binding sites.

We have developed a new genomic sequencing method for detecting, with resolution at the nucleotide level, the interstrand DNA cross-links induced by 4,5',8-trimethylpsoralen along single-copy genes in mammalian cells. The cross-links (diadducts) initially formed are converted into monoadducts by alkali reversal prior to the use of terminal transferase-dependent PCR (TD-PCR). After alkali reversal, but not before, the DNA strands can be separated and used as templates for gene-specific primer extension, which is the first step in the TD-PCR procedure. The converted psoralen adducts block primer extension, and the prematurely terminated single-stranded products are then amplified by TD-PCR and visualized on a sequencing gel. Adducts formed by angelicin, a psoralen derivative that forms only monoadducts, were also investigated by use of TD-PCR. Comparison of the adduct distribution patterns of in vivo-treated DNA with those of in vitro-treated DNA revealed that the binding of transcription factors inhibited both psoralen cross-linking and angelicin monoadduct formation in the c-JUN and c-FOS promoters in living human cells. Adduct formation was also inhibited in the region of a putative positioned nucleosome in the c-FOS promoter. These methods should be of general use for study of in vivo protein-DNA interactions and DNA repair.