Dimeric bisbenzimidazoles: Cytotoxicity and effects on DNA methylation in normal and cancer human cells

Cancer cells are characterized by hypermethylation of the promoter regions of tumor suppressor genes. DNA methyltransferase inhibitors reactivate the genes, pointing to DNA methyltransferases as potential targets for anticancer therapy. Dimeric bisbenzimidazoles varying in the length of an oligomeric linker between two bisbenzimidazole residues (DB(n), where n is the number of methylene groups in the linker) were earlier shown to efficiently inhibit methylation of DNA duplexes by murine DNA methyltransferase Dnmt3a. Here, some of the compounds were tested for cytotoxicity, cell penetration, and effect on genomic DNA methylation in F-977 fetal lung fibroblasts and HeLa cervical cancer cells. Within the 0–60 μM concentration range, only DB(11) exerted a significant toxic effect on normal cells, whereas the effects of DB(n) on cancer cells were not significant. DB(1) and DB(3) slightly stimulated proliferation of HeLa and F-977 cells, respectively. DB(1) and DB(3) penetrated into the nuclei of HeLa and F-977 cells and accumulated predominantly in or near the nucleolus, while DB(11) was incapable of nuclear penetration. HeLa cells incubated with 26 μM DB(1) or DB(3) displayed a decrease in methylation of the 18S rRNA gene, which was in the regions of predominant accumulation of DB(1) and DB(3). The same DB(3) concentration exerted a similar effect on F-977 cells. However, the overall genomic DNA methylation level remained unchanged in both of the cell lines. The results indicated that DB(n)-type compounds can be used to demethylate certain genes and are thereby promising as potential anticancer agents.     

DNA Duplexes Containing Altered Sugar Residues as Probes of EcoRII and MvaI Endonuclease Interactions with Sugar-Phosphate Backbone

Abstract

Oligonucleotides containing 1-(β-D-2′-deoxy-threo-pentofuranosyl)cytosine (dCx) and/or 1-(β-D-2′-deoxy-threo-pentofuranosyl)thymine (dT_x) in place of dC and dT residues in the EcoRII and MvaI recognition site CC^A/_TGG were synthesized in order to investigate specific recognition of the DNA sugar-phosphate backbone by EcoRII and MvaI restriction endonucleases. In 2′-deoxyxylosyl moieties of dC_x and dT_x, 3′-hydroxyl groups were inverted, which perturbs the related individual phosphates. Introduction of a single 2′-deoxyxylo-syl moiety into a dC·dG pair resulted in a minor destabilization of double-stranded DNA structure. In the case of a dA·dT pair the effect of a 2′-deoxyxylose incorporation was much more pronounced. Multiple dC_x modifications and their combination with dT_x did not enhance the destabilization effect. Hydrolysis of dC_x-containing DNA duplexes by EcoRII endonuclease was blocked and binding affinity was strongly depended on the location of an altered sugar. A DNA duplex containing a dT_x residue was cleaved by the enzyme, but k_cat/K_M was slightly reduced. In contrast, MvaI endonuclease efficiently cleaved both types of sugar-altered substrate analogs. However it did not cleave conformationally perturbed scissile bonds, when the corresponding unmodified bonds were perfectly hydrolyzed in the same DNA duplexes. Based on these data the possible contributions of individual phosphates in the recognition site to substrate recognition and catalysis by EcoRII were proposed. We observed strikingly non-equivalent inputs for different phosphates with respect to their effect on EcoRII-DNA complex formation.     

Detailed Structure of the Skeleton,Muscles, and Connective-Tissue Elements in the Head of Silver Carp Hypophthalmichthys molitrix (Cyprinidae) in Relationship with the Functional Features of Its Visceral Apparatus

Journal of Ichthyology - The structure of some muscles, ligaments, the aponeurotic system, and osteological traits of the visceral apparatus in silver carp Hypophthalmichthys molitrix is considered...     

Human Xip1 (C2orf13) is a novel regulator of cellular responses to DNA strand breaks

DNA strand breaks arise continuously as the result of intracellular metabolism and in response to a multitude of genotoxic agents. To overcome such challenges to genomic stability, cells have evolved genome surveillance pathways that detect and repair damaged DNA in a coordinated fashion. Here we identify the previously uncharacterized human protein Xip1 (C2orf13) as a novel component of the checkpoint response to DNA strand breaks. Green fluorescent protein-tagged Xip1 was rapidly recruited to sites of DNA breaks, and this accumulation was dependent on a novel type of zinc finger motif located in the C terminus of Xip1. The initial recruitment kinetics of Xip1 closely paralleled that of XRCC1, a central organizer of single strand break (SSB) repair, and its accumulation was both delayed and sustained when the detection of SSBs was abrogated by inhibition of PARP-1. Xip1 and XRCC1 stably interacted through recognition of CK2 phosphorylation sites in XRCC1 by the Forkhead-associated (FHA) domain of Xip1, and XRCC1 was required to maintain steady-state levels of Xip1. Moreover, Xip1 was phosphorylated on Ser-116 by ataxia telangiectasia-mutated in response to ionizing radiation, further underscoring the potential importance of Xip1 in the DNA damage response. Finally, depletion of Xip1 significantly decreased the clonogenic survival of cells exposed to DNA SSB- or double strand break-inducing agents. Collectively, these findings implicate Xip1 as a new regulator of genome maintenance pathways, which may function to organize DNA strand break repair complexes at sites of DNA damage.     

Role of the hypothalamus in originating disorders of exploratory behavior and learning in rats with excised nuclei of the locus coeruleus

Open-field behaviour and emotionally differently reinforced learning were studied in male Wistar rats with bilaterally ablated Locus coeruleus. Histochemical analysis of the hypothalamic structures was carried out. Decrease of investigating activity and attention was found as well as disturbances of learning with emotionally-negative (painful) reinforcement. By means of histochemical methods, fluorescence characteristic for catecholamines was found to decrease sharply in paraventricular and supraoptic hypothalamic nuclei, eminentia medialis and the posterior lobe of the hypophysis.     

Interaction of EcoRII restriction and modification enzymes with synthetic DNA fragments. X. Hydrolysis of substrates with structural abnormalities

Interaction of the EcoRII restriction endonuclease with a set of 30-membered substrates having structural anomalies in the recognition site (decreases CCT/AGG) and in adjacent sequences has been studied. A nick in the centre of the EcoRII recognition site between dC and dA residues slows down hydrolysis of the nonmodified strand, whereas the modified one is not cleaved. Removal of the phosphate group from the nick in this substrate does not alter the rate of the cleavage. The absence of one of the phosphate groups in the flanking sequence at a two-base-pair "distance" from the recognition site slows down the enzymatic hydrolysis. Removal of dA or dT out of the EcoRII recognition site blocks the enzymatic reaction. It appears that EcoRII does not interact with the phosphate group between dC and dA residues in the recognition site. Suggestions are made concerning possible contacts of the EcoRII restriction endonuclease with dA- and dT-residues of the recognition site and with the sugar-phosphate backbone of the adjacent nucleotide sequences.     

Change in the cleavage site of synthetic substrates of SsoII restriction endonucleases upon introduction of non-nucleotide inserts in the recognition segment]

The cleavage of synthetic DNA duplexes containing 1,3-propanediol, 1,2-dideoxy-D-ribofuranose or 9-[1'-hydroxy-2'-(hydroxymethyl)ethoxy]methylguanine (glG) residues instead of one of dG residues or one of the nucleosides of the central base pair of the recognition site by SsoII restriction endonuclease (decreases CCNGG) has been studied. It is found that the non-nucleotide insertions (except for glG) result in a change of the SsoII cleavage site and an increase of the efficiency of the cleavage. The novel noncanonical cleavage occurs at the phosphodiester bond adjoining the non-nucleotide insert from the 5'-end.     

Formation of two types of enzyme-substrate complexes during the interaction of EcoRII restriction enzyme with synthetic DNA-duplexes]

Binding of EcoRII restriction endonuclease to synthetic oligodeoxyribonucleotide substrates of 11-30 base pairs long was investigated by polyacrylamide gel electrophoresis under nondenaturing conditions in the absence of Mg2+ ions. Irrespective of the length of a substrate, two types of specific DNA-protein complexes were shown to be formed. Their mobility in gel was close to that of the monomer (45 kDa) and dimer (90 kDa) of marker protein, ovalbumin. The ratio of these complexes in solution depended on that of the molar concentrations of EcoRII restriction endonuclease and DNA duplexes. The possible structure of the complexes is discussed.     

Camptothecin inhibits both the cleavage and religation reactions of eukaryotic DNA topoisomerase I.

We investigated the mode of action of the antitumor drug, camptothecin, by use of a partly double-stranded suicide DNA substrate which enables uncoupling of the cleavage and religation half-reactions of topoisomerase I. The suicide DNA substrate contains a single topoisomerase I site at which SDS cleavage is strongly enhanced by camptothecin on normal double-stranded DNA. The results show that the religation reaction of topoisomerase I per se is strongly inhibited at this site compared to site that is only marginally affected by camptothecin on double-stranded DNA. This study hereby directly demonstrates that camptothecin-mediated stability of a topoisomerase I-DNA complex is sequence-dependent. The influence of camptothecin on the suicide cleavage reaction of topoisomerase I was also investigated. Surprisingly, the cleavage reaction per se is strongly inhibited by the drug. However, reformation of a cleavable suicide DNA substrate, which is fully double-stranded downstream from the cleavage position except for a nick, completely reverses the inhibitory effect of the drug on the cleavage reaction. The results suggest that the inhibitory effect of camptothecin on cleavage is due to a general decrease in the noncovalent interaction of topoisomerase I with partly double-stranded suicide DNA substrates. Based on the findings, a plausible model for camptothecin action is discussed.