DNA single-strand breaks and neurodegeneration

The association of human genetic disorders with defects in the DNA damage response is well established. Most of the major DNA repair pathways are represented by diseases in which that pathway is absent or impaired, including those responsible for repairing DNA double-strand breaks. Conspicuous by their absence, however, have been human disorders associated with defects in the repair or response to DNA single-strand breaks (SSBs). However, three papers have recently associated hereditary spinocerebellar ataxia with mutations in genes connected with SSBR. The emerging links between SSBR and neurodegeneration are discussed.     

Influence of DNA conformation on radiation-induced single-strand breaks

It is usually assumed that sparsely ionizing radiation produces randomly distributed DNA breakages. This seems to be supported by the finding that in some DNA fragments single-strand scissions occur uniformly at all nucleotide sites, regardless of sequence. We performed experiments on two DNA fragments of about 300 by having different conformation to test whether radiation-induced single-strand breakage is dependent on DNA conformation. Breakage analysis was carried out by denaturing polyacrylamide gel electrophoresis, which allows determination of the broken site at single nucleotide resolution. We found uniform cutting patterns in B-form regions. On the contrary, X- or-irradiation of curved fragments of kinetoplast DNA showed that the distribution of single-strand breaks was not uniform along the fragment, as the cleavage pattern was modulated in phase with the runs of A-T pairs. This modulation likely reflected the reduced accessibility of the sites which on hydroxyl-radical attack give rise to strand breaks. The cleavage pattern was phased with the runs of A-T pairs. Moreover, the overall yield of strand breaks was considerably lower in curved DNA fragments than in those with extended straight regions. The conformation effect found here indicates that the cleavage pattern reflects the fine structural features of DNA.     

Matching of single-strand breaks to form double-strand breaks in DNA

Single-strand breaks (ssb) in opposite strands of DNA can be sufficiently near that a double-strand break (dsb) results. A theory is presented by which the maximum number h of base pairs which cannot prevent double-strand breakage can be determined from the rates of production of ssb and dsb. The assumptions required to derive the necessary equations as well as the range of validity of the equations are discussed in detail. In the experiments ssb and dsb were produced by x-irradiation in buffers which do not eliminate indirect effects and were measured by analytical ultracentrifugation. Values of h have been determined in low and high ionic strength and in low ionic strength over a range of temperatures. The values, 2.64 and 15.8, were obtained for high and low ionic strength, respectively.     

Gamma-ray induced double-strand breaks in DNA resulting from randomly-inflicted single-strand breaks: temporal local denaturation, a new radiation phenomenon?

The induction of single- and double-strand breaks in DNA by gamma-rays has been measured. The maximum number of nucleotide pairs (a) between two independently induced single-strand breaks in opposite strands of the DNA which cannot prevent the occurrence of a double-strand break was found to amount to about 16. This value did not differ significantly for the four types of bacteriophage DNA investigated (T4, T7 and PM2 DNA, and replicative form DNA of phage phiX174) and was the same in 10(-2) M phosphate buffer containing 0, 0.5 or 1 M NaCl. In 10(-3) M phosphate buffer a was 34 nucleotide pairs. Evidence is presented that the relatively large value of a has to be ascribed at least partly to a temporal local denaturation accompanying the induction of a single-strand scission. A contribution of base damage that labilizes the DNA-helix, between two single-strand breaks to the high value of a can not be excluded.     

Cigarette tar causes single-strand breaks in DNA

The results of this study demonstrate, for the first time, that cigarette tar causes DNA damage. Incubation in vitro of phage PM2 DNA with aqueous extracts of cigarette tar results in the introduction of DNA single-strand breaks. The effects of protective enzymes and radical scavengers indicate the involvement of active oxygen species. Although the semiquinone components of tar reduce dioxygen forming superoxide radicals and hydrogen peroxide, our results suggest that hydroxyl radicals formed via metal catalyzed decomposition of hydrogen peroxide are ultimately responsible for the DNA lesions. Our results also suggest that the metals in tar are reduced by the semiquinone components of tar and by superoxide at comparable rates.     

Electron attachment-induced DNA single-strand breaks at the pyrimidine sites

To elucidate the contribution of pyrimidine in DNA strand breaks caused by low-energy electrons (LEEs), theoretical investigations of the LEE attachment-induced C_3′–O_3′, and C_5′–O_5′ σ bond as well as N-glycosidic bond breaking of 2′-deoxycytidine-3′,5′-diphosphate and 2′-deoxythymidine-3′,5′-diphosphate were performed using the B3LYP/DZP++ approach. The base-centered radical anions are electronically stable enough to assure that either the C–O or glycosidic bond breaking processes might compete with the electron detachment and yield corresponding radical fragments and anions. In the gas phase, the computed glycosidic bond breaking activation energy (24.1 kcal/mol) excludes the base release pathway. The low-energy barrier for the C_3′–O_3′ σ bond cleavage process (∼6.0 kcal/mol for both cytidine and thymidine) suggests that this reaction pathway is the most favorable one as compared to other possible pathways. On the other hand, the relatively low activation energy barrier (∼14 kcal/mol) for the C_5′–O_5′ σ bond cleavage process indicates that this bond breaking pathway could be possible, especially when the incident electrons have relatively high energy (a few electronvolts). The presence of the polarizable medium greatly increases the activation energies of either C–O σ bond cleavage processes or the N-glycosidic bond breaking process. The only possible pathway that dominates the LEE-induced DNA single strands in the presence of the polarizable surroundings (such as in an aqueous solution) is the C_3′–O_3′ σ bond cleavage (the relatively low activation energy barrier, ∼13.4 kcal/mol, has been predicted through a polarizable continuum model investigation). The qualitative agreement between the ratio for the bond breaks of C_5′–O_5′, C_3′–O_3′ and N-glycosidic bonds observed in the experiment of oligonucleotide tetramer CGAT and the theoretical sequence of the bond breaking reaction pathways have been found. This consistency between the theoretical predictions and the experimental observations provides strong supportive evidences for the base-centered radical anion mechanism of the LEE-induced single-strand bond breaking around the pyrimidine sites of the DNA single strands.     

Relaxation kinetics of denaturation of DNA

The one-dimensional Ising model, with nearest-neighbor correlations only, used earlier in equilibrium studies of melting of DNA is extended to study the relaxation kinetics of copolymeric synthetic DNA near the melting temperature. An exponential kinetics, in agreement with the observations, has been found.     

DNA single-strand breaks in adult and embryonic avian erythrocytes

We have investigated the possibility that the reactivation rate of adult avian erythrocytes, which is slower than that of embryonic erythrocytes, after fusion with metabolically active cells, is due to a greater number of single-strand breaks (ssb) in the DNA of the former. We have assayed ssb by measuring the template activity of the erythrocyte nuclei for added Escherichia coli DNA polymerase. We have found that differences in the numbers of ssb within polymerase-accessible regions between adult and embryonic cells are within experimental error. We conclude that, unless very localized clusters of damage exist within the DNA (which would not be detectable by this or other techniques), the difference in reactivation rate is not attributable to differences in ssb numbers.     

The protein kinase CK2 facilitates repair of chromosomal DNA single-strand breaks

CK2 was the first protein kinase identified and is required for the proliferation and survival of mammalian cells. Here, we have identified an unanticipated role for CK2. We show that this essential protein kinase phosphorylates the scaffold protein XRCC1 and thereby enables the assembly and activity of DNA single-strand break repair protein complexes in vitro and at sites of chromosomal breakage. Moreover, we show that inhibiting XRCC1 phosphorylation by mutation of the CK2 phosphorylation sites or preventing CK2 activity using a highly specific inhibitor ablates the rapid repair of cellular DNA single-strand breaks by XRCC1. These data identify a direct role for CK2 in the repair of chromosomal DNA strand breaks and in maintaining genetic integrity.     

The effect of superhelical density on the yield of single-strand breaks in gamma-irradiated plasmid DNA.

Using agarose gel electrophoresis, the formation of DNA single-strand breaks (SSBs) by 137Cs gamma irradiation was quantified in negatively supercoiled topological isomers of plasmid pUC18. The G value for SSB formation falls slightly from 1 x 10(8) to 8 x 10(-9) SSB Gy-1 Da-1 as the superhelical density varies from 0.00 to -0.08. This result is not in agreement with recent observations by others which suggest that increasing the negative superhelical density of plasmid DNA increases its sensitivity to X irradiation.     

TDP1 facilitates repair of ionizing radiation-induced DNA single-strand breaks

Tyrosyl DNA phosphodiesterase-1 (TDP1) is the gene product mutated in spinocerebellar ataxia with axonal neuropathy1 (SCAN1). SCAN1 is a hereditary ataxia that lacks extra-neurological phenotype, pointing to a critical role for TDP1 in the nervous system. Recently, we showed that TDP1 is associated with the DNA single-strand break (SSBR) repair machinery through an interaction with DNA ligase 3alpha (Lig3alpha) and that SCAN1 cells are defective in the repair of chromosomal DNA single-strand breaks (SSBs) arising from abortive Topoisomerase 1 (Top1)-DNA intermediates. Here we demonstrate that TDP1 is also required for the repair of SSBs induced by ionizing radiation (IR), though not measurably for IR-induced DNA double-strand breaks (DSBs). In addition, we provide evidence that abortive Top1 cleavage complexes are processed by the proteasome prior to the action of TDP1 in vivo, and we exploit this observation to show that the SSBR defect in SCAN1 following IR reflects, in part at least, the presence of IR-induced protein-DNA cross-links. Finally we show that TDP1 activity at abortive Top1-SSBs is stimulated by XRCC1/Lig3alpha in vitro. These data expand the type of SSBs processed by TDP1 to include those induced by ionizing radiation, and raise the possibility that TDP1 inhibitors may improve radiotherapy.     

Measurement of DNA single-strand breaks by alkaline elution and fluorometric DNA quantification

The method presented is based on the alkaline elution procedure for the determination of DNA single-stand (ss) breaks developed by Kohn and on the principles of DNA quantification after binding with the dye Hoechst 33258. In the present study, modification of the alkaline elution procedure with regard to the elution solution volume was performed. The influences of the DNA strandedness, the ethylenediaminetetraacetate/tetraethylammonium hydroxide denaturation and elution solution presence, the DNA solution pH, the dye amount, and the incubation time for the formation of the dye-ssDNA complex on the DNA fluorometric quantification were also studied. The modified DNA alkaline elution procedure followed by the optimized fluorometric determination of the ssDNA was applied on liver tissue from both untreated and treated (N-nitroso-N-methylurea- administered) Wistar rats. The criteria for the selection of the appropriate estimator and statistical analysis of the obtained results are also presented. The method of the DNA alkaline elution followed by fluorometric determination of ssDNA as modified and evaluated is an accurate and reliable approach for the determination of in vivo induced ssDNA strand breaks.