A protocol for separation and isolation of small and/or large DNA fragments with high yield using CL4B Sepharose

Mutations altering the interplay between GkDnaC helicase and DNA reveal an insight into helicase unwinding

Replicative helicases are essential molecular machines that utilize energy derived from NTP hydrolysis to move along nucleic acids and to unwind double-stranded DNA (dsDNA). Our earlier crystal structure of the hexameric helicase from Geobacillus kaustophilus HTA426 (GkDnaC) in complex with single-stranded DNA (ssDNA) suggested several key residues responsible for DNA binding that likely play a role in DNA translocation during the unwinding process. Here, we demonstrated that the unwinding activities of mutants with substitutions at these key residues in GkDnaC are 2-4-fold higher than that of wild-type protein. We also observed the faster unwinding velocities in these mutants using single-molecule experiments. A partial loss in the interaction of helicase with ssDNA leads to an enhancement in helicase efficiency, while their ATPase activities remain unchanged. In strong contrast, adding accessory proteins (DnaG or DnaI) to GkDnaC helicase alters the ATPase, unwinding efficiency and the unwinding velocity of the helicase. It suggests that the unwinding velocity of helicase could be modulated by two different pathways, the efficiency of ATP hydrolysis or protein-DNA interaction.

Determination and analysis of site-specific 125I decay-induced DNA double-strand break end-group structures

End groups contribute to the structural complexity of radiation-induced DNA double-strand breaks (DSBs). As such, end-group structures may affect a cell's ability to repair DSBs. The 3'-end groups of strand breaks caused by gamma radiation, or oxidative processes, under oxygenated aqueous conditions have been shown to be distributed primarily between 3'-phosphoglycolate and 3'-phosphate, with 5'-phosphate ends in both cases. In this study, end groups of the high-LET-like DSBs caused by 125I decay were investigated. Site-specific DNA double-strand breaks were produced in plasmid pTC27 in the presence or absence of 2 M DMSO by 125I-labeled triplex-forming oligonucleotide targeting. End-group structure was assessed enzymatically as a function of the DSB end to serve as a substrate for ligation and various forms of end labeling. Using this approach, we have demonstrated 3'-hydroxyl (3'-OH) and 3'-phosphate (3'-P) end groups and 5'-ends (> or = 42%) terminated by phosphate. A 32P postlabeling assay failed to detect 3'-phosphoglycolate in a restriction fragment terminated by the 125I-induced DNA double-strand break, and this is likely due to restricted oxygen diffusion during irradiation as a frozen aqueous solution. Even so, end-group structure and relative distribution varied as a function of the free radical scavenging capacity of the irradiation buffer.

Molecular analysis of base damage clustering associated with a site-specific radiation-induced DNA double-strand break

Base damage flanking a radiation-induced DNA double-strand break (DSB) may contribute to DSB complexity and affect break repair. However, to date, an isolated radiation-induced DSB has not been assessed for such structures at the molecular level. In this study, an authentic site-specific radiation-induced DSB was produced in plasmid DNA by triplex forming oligonucleotide-targeted (125)I decay. A restriction fragment terminated by the DSB was isolated and probed for base damage with the E. coli DNA repair enzymes endonuclease III and formamidopyrimidine-DNA glycosylase. Our results demonstrate base damage clustering within 8 bases of the (125)I-targeted base in the DNA duplex. An increased yield of base damage (purine > pyrimidine) was observed for DSBs formed by irradiation in the absence of DMSO. An internal control fragment 1354 bp upstream from the targeted base was insensitive to enzymatic probing, indicating that the damage detected proximal to the DSB was produced by the (125)I decay that formed the DSB. Gas chromatography-mass spectrometry identified three types of damaged bases in the approximately 32-bp region proximal to the DSB. These base lesions were 8-hydroxyguanine, 8-hydroxyadenine and 5-hydroxycytosine. Finally, evidence is presented for base damage >24 bp upstream from the (125)I-decay site that may form via a charge migration mechanism.

Characterization of complex apurinic/apyrimidinic-site clustering associated with an authentic site-specific radiation-induced DNA double-strand break

Radiation lethality is largely attributed to radiation-induced DNA double-strand breaks (DSBs). A range of structural complexity is predicted for radiation-induced DSBs. However, this lesion has never been analyzed in isolation at the molecular level. To address this problem, we have created authentic site-specific radiation-induced DSBs in plasmid DNA by triplex-forming oligonucleotide-targeted 125I decay. No significant difference in DSB yield was observed after irradiation in the presence or absence of the radical scavenger DMSO, suggesting that DSB formation is a result of the direct effect of the radiation. A restriction fragment terminated by the DSB was isolated and probed with the Escherichia coli DNA repair enzyme endonuclease IV (endo IV), which recognizes apurinic/apyrimidinic (AP) sites. Enzymatic probing demonstrated clustering of AP sites within 10 bases of the 125I-targeted base in the DNA duplex. Our results suggest scavengeable radicals may not play a large role in the generation of AP sites associated with DSB formation, because at least 30% of all fragments have endo IV-sensitive sites, regardless of irradiation conditions. An internal control fragment recovered from the 125I linearized plasmid did not exhibit endo IV sensitivity in excess of that observed for a similar fragment recovered from an undamaged plasmid. Thus, AP site clustering proximal to the DSB resulted from the 125I decays responsible for DSB formation and was not due to untargeted background irradiation.

Characterization of a complex 125I-induced DNA double-strand break: implications for repair

PURPOSE

To examine the role of radiation-induced DNA double-strand break (DSB) structural organization in DSB repair, and characterize the structural features of 125I-induced DSBs that may impact the repair process.

METHODS

Plasmid DNA was linearized by sequence-specific targeting using an 125I-labeled triplex-forming oligonucleotide (TFO). Following isolation from agarose gels, base damage structures associated with the DSB ends in plasmids linearized by the 125I-TFO were characterized by probing with the E. coli DNA damage-specific endonuclease and DNA-glycosylases, endonuclease IV (endo IV), endonuclease III (endo III), and formamidopyrimidine-glycosylase (Fpg).

RESULTS

Plasmid DNA containing DSBs produced by the high-LET-like effects of 125I-TFO has been shown to support at least 2-fold lower end joining than gamma-ray linearized plasmid, and this may be a consequence of the highly complex structure expected near an 125I-induced DSB end. Therefore, to determine if a high density of base damage exists proximal to the DSBs produced by 125I-TFOs, short fragments of DNA recovered from the DSB end of 125I-TFO-linearized plasmid were enzymatically probed. Base damage and AP site clustering was demonstrated within 3 bases downstream and 7 bases upstream of the targeted base. Furthermore, the pattern and extent of base damage varied depending upon the presence or absence of 2 M DMSO during irradiation.

CONCLUSIONS

125I-TFO-induced DSBs exhibit a high degree of base damage clustering proximal to the DSB end. At least 60% of the nucleotides within 10 bp of the 125I decay site are sensitive to cleavage by endo IV, endo III, or Fpg following damage accumulation in the presence of DMSO, whereas > or = 80% are sensitive in the absence of DMSO. The high degree of base damage clustering associated with the 125I-TFO-induced DSB end may be a major factor leading to its negligible in vitro repair by the non-homologous end-joining pathway (NHEJ).