Marek Gniazdowski

Effects of anticancer drugs on transcription factor-DNA interactions

DNA-interacting anticancer drugs are able to affect the propensity of DNA to interact with proteins through either reversible binding or covalent bond formation. The effect of the drugs on transcription factor interactions with DNA is reviewed. These effects can be classified as (i) competition between a drug and regulatory protein for target sequences; (ii) weakening of this interaction; (iii) enhancement of this interaction by chemical modification of the DNA and the creation of non-natural binding sites; and (iv) a ‘suicide’ mechanism, which is observed when a transcription factor induces changes in DNA structure, allowing a drug to bind to a target sequence. Several new strategies – the antigene approach with oligonucleotides, peptide nucleic acids or locked nucleic acids, and sequence-specific polyamides – are also reviewed.

Some properties of the irreversible complexes of nitracrine (Ledakrin, C-283) with polynucleotides

In the presence of sulfhydryl compounds an anticancer drug nitracrine (NA), 1-nitro-9-aminoalkylacridine derivative forms strong, probably covalent complexes with DNA. It has been found that it binds with similar efficiency to RNA and DNA exhibiting a certain preference for single-stranded structure. At NA/polynucleotide ratio of 0.15 and nucleic acids concentration 100 microgram/ml the numbers of drug molecules bound per 10(3) nucleotides were about 10--13 for native calf thymus DNA, 19--28 for denatured DNA and 23--36 for RNA. Some base specificity to guanine is observed both in polydeoxyribo- and polyribonucleotides. The complexes of NA with DNA and double-stranded synthetic polynucleotides exhibit decreased transcriptional template activity in bacterial RNA synthesis in vitro system except poly(A) synthesis on poly(dA) x poly(dT) which is insensitive to the drug. The drug binding in vitro leads to cross-link formation in DNA as shown by means of ultraviolet spectrophotometry and hydroxylapatite chromatography of heat-denatured NA-DNA complexes. The amount of the double bonds introduced by the drug is however relatively low as compared with cross-linking of irradiated 8-methoxy-psoralen-DNA (MOP-DNA) complexes.

Effects of anticancer drugs on transcription in vitro.

Abstract The effects of DNA interacting drugs on: (1) total RNA synthesis catalyzed by E.coli and T7 RNA polymerase; (2) synthesis of the initiating dinucleotide (pppApU) by E .coli RNA polymerase (“abortive initiation“); (3) elongation of RNA chains synthesized by T7 RNA polymerase on pT7-7 plasmid DNA bearing T7 RNA polymerase promoter ϕ 10 with human Cu/Zn superoxide dismutase coding sequence, (4) interaction of transcription factor Sp1 and its binding site were studied. Intercalating ligands which form quickly dissociating complexes with DNA (anthracyclines, proflavine, ethidium bromide) are compared with the slowly dissociating drug of d(G · C ) specificity (actinomycin D), the non-intercalating, d(A · T ) specific pyrrole antibiotics (netropsin and distamycin A) and covalently binding to DNA 1-nitroacridine derivative (nitracrine). The obtained results indicate that rapidly dissociating ligands, proflavine and ethidium bromide, inhibit total RNA synthesis in vitro and the abortive initiation to a similar extent while they do not induce discrete elongation stops of RNA polymerase. Actinomycin D and nitracrine exhibit a high inhibitory effect on total RNA synthesis and induce stops of RNA polymerase while not affecting abortive initiation. Pyrrole antibiotics primarily inhibit the initiation, while no elongation stops are induced. Actinomycin D inhibits complex formation between nuclear proteins and the Sp1 binding site. Netropsin, ethidium bromide, proflavine and other intercalating acridines do not affect Sp1 binding. The results indicate that the effects primarily depend on sequence specificity and secondarily on the dissociation rate of ligands from their complexes with DNA.

Interactions of Novel Morpholine and Hexamethylene Derivatives of Anthracycline Antibiotics with DNA

Abstract Doxorubicin (DOX), daunorubicin (DRB), epidoxorubicin (EDOX) and their analogues with a 3′-NH2 group in daunosamine form a covalent bond with a 2-NH2 group of guanine via a methylene group from formaldehyde (CH2O). It is assumed that a Schiff base type intermediate is formed between CH2O and the 3′-NH2 group in the reaction. This reaction is supposed to occur in the cell. New analogues of anthracyclines with formamidine functionality bound to C-3′ of daunosamine and containing the bulky morpholine (DRBM, DOXM and EDOXM) or hexamethyleneimine rings attached are studied in our laboratory. These substituents decrease the association of the drugs to DNA and potentially hinder the formation of Schiff base-intermediates. Our experiments indicate that the formation of the covalent complexes by DRB, DOX and EDOX under these conditions is confirmed by a high enhancement (17-40x) of the inhibition of overall RNA synthesis by E. coli RNA polymerase on T7 DNA. DRBM and DOXM exhibit a lower enhancement of the inhibition by CH2O (7-13x). The other analogues show a 1.6-3x increase of inhibition. Hence, their covalent binding is lower than that of the parent compounds. These conclusions are confirmed by spectrophotometric estimations following removal of non-covalently associated drugs. Electrophoretic analysis of drug-DNA complexes formed in the presence of CH2O indicates that DRBM and DOXM as their parent compounds induce labile cross-links in DNA. Comparison of the results obtained at the subcellular level with cytotoxicity estimations indicates that there is a correlation between cytotoxicity of the anthracyclines on L1210 cells and transcriptional template activity of drug-DNA complexes formed in the presence of CH2O (r = 0.64; n = 9). These data confirm a notion that covalent attachment of anthracyclines to DNA is an essential event leading to cytotoxicity.

Inhibition of RNA Synthesis in vitro by Acridines - Relation between Structure and Activity

Abstract The effects of acridine derivatives (proflavine and 2,7-dialkyl derivatives, diacridines and triacridines, 9-aminoacridine carboxamides, and 9-anilinoacridine, amsacrine and its congeners) on overall RNA synthesis in vitro, on synthesis of initiating oligonucleotides and the binding of the enzyme to DNA were studied. The primary mechanism of action is related to inhibition of the enzyme binding to DNA. The acridines (intercalating or non-intercalating and bis-intercalating ligands) assayed here differ in the properties of their complexes with DNA. Correlation is generally observed between inhibition of RNA synthesis in vitro and cytotoxicity in cell cultures for di- and triacridines and 9-aminoacridine carboxamide derivatives. No relationship was found between the effect on RNA polymerase system and biological effects for amsacrine and its derivatives in contrast to the other series of acridines studied here. The aniline ring seems to decrease the inhibitory potency of a ligand. The discrepancy between the biological effect and RNA synthesis inhibition may be due to a different mechanism of cytotoxicity action of amsacrine which is a potent topoisomerase II poison.

DNA binding, cytotoxicity and inhibitory effect on RNA synthesis of two new 1-nitro-9-aminoacridine dimers.

Two 1-nitro-9-aminoacridine dimers were prepared: one bearing a spermine flexible linking chain, compound 4, the other a rigid dipiperidine-type linker, compound 7. Both dimers elicited a higher affinity constant for DNA than the parent monomeric drug nitracrine 2. This affinity was several orders lower than what was found for other dimeric compounds having the same linkers and no nitro group on the acridine ring (3, 5, 6 and 8). Bisintercalation was evidenced for compound 4 by viscosimetric measurements. In the absence of dithiothreitol, an inhibitory effect of RNA synthesis in vitro was observed for all the tested compounds except 2 and 7. In the presence of dithiothreitol, 4 and 7 formed irreversible complexes with DNA of decreased template properties. The level of the dimers binding was lower than that of the parent compound 2. Cross-links were detected by means of hydroxylapatite chromatography in a complex of the dimer bearing a flexible linking chain, compound 4 with DNA, while the compound 7-DNA complex eluted in the single-stranded DNA region. The extent of cytotoxicity of the two 1-nitro-9-aminoacridine dimers against L1210 cultured cells was different.

Inhibition of DNA-dependent RNA synthesis by 8-methoxypsoralen

The effect of the photobinding of 8-methoxypsoralen to phage T7 DNA on different steps of RNA synthesis in vitro was assayed. Total RNA synthesis is reduced to a few percent and the transcript size is decreased, as shown by means of gel filtration on a Sepharose 4B column when DNA of the adduct content of six drug molecules per 10(3) nucleotides is used. The initiation of RNA chains seems to be less affected, as inferred from an abortive initiation assay. Synthesis of pppApU on DNA of the same adduct content is inhibited to 34% of the corresponding controls, while the overall RNA synthesis is inhibited to 6%. The amount of the enzyme needed for maximal retention of DNA, the kinetics of its binding and the decay of the polymerase-DNA complex at high ionic strength (or on decrease of the temperature) are similar with DNA either irradiated in the absence of the drug or DNA bearing six 8-methoxypsoralen molecules per 10(3) nucleotides. It is concluded from this study that 8-methoxypsoralen partially inhibits initiation and blocks movement of RNA polymerase along the template, inducing premature termination. It does not appear to influence the binding of the enzyme to DNA.

In vitro binding of nitracrine to DNA in chromatin.

Abstract In the presence of sulfhydryl compounds nitracrine, an anticancer drug, binds covalently to DNA . The accessibility of DNA in chromatin both to nitracrine and to 8-methoxypsoralen. which was used as a reference compound in this study, when assayed in NaCl concentrations from 0 to 2 m show similar characteristics. The initial decrease reaches a minimum at 0.15 m NaCl above which dissociation of non-histone proteins and histones at higher ionic strengths is demonstrated by an increase in accessible sites. The relative accessibility of DNA in chromatin to nitracrine is, however, lower than that found for 8-methoxypsoralen. Partial dissociation of chromatin with 0.7 m NaCl increases the accessibility of DNA in chromatin when assayed in the absence of NaCl but has no apparent influence when estimated at ionic strength close to physiological conditions.