DNA double-strand breaks (DSB) are considered to be critical primary lesions in the formation of chromosomal aberrations. DSB may be induced by exogenous agents, such as ionizing radiation, but also occur spontaneously during cellular processes at quite significant frequencies. To repair this potentially lethal damage, eukaryotic cells have evolved a variety of repair pathways related to homologous and illegitimate recombination, also called non-homologous DNA end joining, which may induce small scale mutations and chromosomal aberrations. In this paper we review the major cellular sources of spontaneous DSB and the different homologous and illegitimate recombination repair pathways, with particular focus on their potential to induce chromosomal aberrations.
Non-homologous DNA end joining (NHEJ) is considered the major pathway of double-strand break (DSB) repair in mammalian cells and depends, among other things, on the DNA end-binding Ku70/80 hetero-dimer. To investigate the function of Ku in NHEJ we have compared the ability of cell-free extracts from wild-type CHO-K1 cells, Ku80-deficient xrs6 cells and Ku80-cDNA-complemented xrs6 cells (xrs6-Ku80) to rejoin different types of DSB in vitro. While the two Ku80-proficient extracts were highly efficient and accurate in rejoining all types of DNA ends, the xrs6 extract displayed strongly decreased NHEJ efficiency and accuracy. The lack of accuracy is most evident in non-homologous terminus configurations containing 3'-overhangs that abut a 5'-overhang or blunt end. While the sequences of the 3'-overhangs are mostly preserved by fill-in DNA synthesis in the Ku80-proficient extracts, they are always completely lost in the xrs6 extract so that, instead, small deletions displaying microhomology patches at their breakpoints arise. In summary, our results are consistent with previous results from Ku-deficient yeast strains and indicate that Ku may serve as an alignment factor that not only increases NHEJ efficiency but also accuracy. Furthermore, a secondary NHEJ activity is present in the absence of Ku which is error-prone and possibly assisted by base pairing interactions.
Extracts of Xenopus laevis eggs can efficiently join ends of duplex DNA that differ in structure and sequence. This was analysed by recircularisation of linear plasmid DNA molecules with dissimilar termini, generated by successive cuts with two different restriction enzymes within the pSP65 polylinker. Use of various enzymes provided blunt ended or 4 nucleotides long 3' and 5' protruding single strand (PSS) termini which were successfully joined in vitro in any tested combination. Sequence analysis of numerous junctions from cloned reaction products of 7 terminus combinations reveal: apart from very rare base exchanges and single nucleotide insertions less than 10% deletions (1 to 18 nucleotides long) were detected. Blunt/PSS or 3'PSS/5'PSS terminus pairs undergo simple "blunt end" joining which preserves PSS ends by fill-in. In contrast, equally polar 3'PSS/3'PSS or 5'PSS/5'PSS terminus pairs are joined by a complex mode: PSS ends overlap by a defined number of nucleotides, set by matching basepairs. Even one basematch suffices to define the setting. This then determines the final mismatch repair and fill-in pattern. We propose that yet unknown terminal DNA-binding proteins stabilize the energetically highly unfavorable configuration of single matching basepairs and help to support defined overlap structures.
To examine determinants of fidelity in DNA end joining, a substrate containing a model of a staggered free radical-mediated double-strand break, with cohesive phosphoglycolate-terminated 3-overhangs and a onebase gap in each strand, was constructed. In extracts of Xenopus eggs, human lymphoblastoid cells, hamster CHO-K1 cells, and a Chinese hamster ovary (CHO) derivative lacking the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs), the predominant end joining product was that corresponding to accurate restoration of the original sequence. In extracts of the Ku-deficient CHO derivative xrs6, a shorter product, consistent with 3 3 5 resection before ligation, was formed. Similar results were seen for a substrate with 5-overhangs and recessed 3-phosphoglycolate ends. Supplementation of the xrs6 extracts with purified Ku restored accurate end joining. In Xenopus and human extracts, but not in hamster extracts, gap filling and ligation were blocked by wortmannin, consistent with a requirement for DNA-PKcs activity. The results suggest a Ku-dependent pathway, regulated by DNA-PKcs, that can accurately restore the original DNA sequence at sites of free radical-mediated double-strand breaks, by protecting DNA termini from degradation and maintaining the alignment of short partial complementarities during gap filling and ligation.
Nonhomologous DNA end joining (NHEJ) is considered the major pathway of double-strand break (DSB) repair in vertebrate cells. Various studies indicated the existence of at least two different NHEJ pathways; one that joins DNA ends accurately and depends on Ku, a protein heterodimer that binds to DNA ends, and one that generates deletions and is independent of Ku. While the former pathway has been characterised in some detail, only little is known about the latter error-prone. We have partially purified such an NHEJ activity from extracts of Xenopus laevis eggs. End-joined junctions formed in the most extensively purified protein fraction displayed deletions containing short patches of sequence homology at their break points, a feature characteristic of single-strand annealing (SSA). Detailed biochemical characterisation revealed the presence of DNA ligase III, DNA polymerase ε, FEN-1 endonuclease, and exonuclease activities of 5′-3′ and 3′-5′ directionality. We show that these activities are able to correctly process proposed intermediates of SSA. Interestingly, neither Ku nor the associated DNA-dependent protein kinase were detected, indicating that the mechanism can dispense with Ku. Our findings provide evidence for the existence of an error-prone NHEJ pathway that creates deletions by microhomologydriven SSA.Keywords : DSB repair; nonhomologous DNA end joining; single-strand annealing; illegitimate recombination; ligation.DNA double-strand breaks (DSB), probably the most disruptive form of DNA damage, may arise spontaneously by various cellular processes [1,2] or after exposure to DNA-damaging agents, such as ionising radiation (IR) [3]. If left unrepaired, DSB may result in broken chromosomes and cell death and if repaired improperly, they can cause mutations, chromosome rearrangements and oncogenic transformation. Repair of DSB is achieved either by homologous recombination which requires an intact copy of the broken DNA sequence provided by the sister chromatid [4], or by nonhomologous DNA end joining (NHEJ) which rejoins the broken ends directly and appears to be the main pathway in vertebrates [5,6]. Mammalian cells defective in DSB repair fall into four complementation groups [7]. The corresponding genes (XRCC4-7) encode the XRCC4 protein that associates with and stimulates DNA ligase IV [8,9], and the three components of the DNA-dependent protein kinase (DNA-PK) represented by the 86-kDa and 70-kDa subunits of the DNA end-binding Ku heterodimer and the catalytic subunit of the protein kinase (DNA-PK CS ), respectively [5,10].Studies in rad52 yeast strains in which the yeast Ku70/86 and/or DNA ligase IV homologues were knocked out showed that efficient NHEJ requires Ku and DNA ligase IV. In the absence of these proteins, a second less efficient NHEJ pathway is still functional which creates deletions [11,12]. Consistent with this, increased frequencies of imprecise end joining were also observed in the xrs6 hamster cell line which is deficient in Ku86 [13]. Together with the results from partially puri...
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