Site-specific DNA repair at the nucleosome level in a yeast minichromosome

The rate of excision repair of UV-induced pyrimidine dimers (PDs) was measured at specific sites in each strand of a yeast minichromosome containing an active gene (URA3), a replication origin (ARS1), and positioned nucleosomes. All six PD sites analyzed in the transcribed URA3 strand were repaired more rapidly (greater than 5-fold on average) than any of the nine PD sites analyzed in the nontranscribed strand. Efficient repair also occurred in both strands of a disrupted TRP1 gene (ten PD sites), containing four unstable nucleosomes, and in a nucleosome gap at the 5' end of URA3 (two PD sites). Conversely, slow repair occurred in both strands immediately downstream of the URA3 gene (12 of 14 PD sites). This region contains the ARS1 consensus sequence, a nucleosome gap, and two stable nucleosomes. Thus, modulation of DNA repair occurs in a simple yeast minichromosome and correlates with gene expression, nucleosome stability, and (possibly) control of replication.     

A nonuniform distribution of excision repair synthesis in nucleosome core DNA

We have investigated the distribution in nucleosome core DNA of nucleotides incorporated by excision repair synthesis occurring immediately after UV irradiation in human cells. We show that the differences previously observed for whole nuclei between the DNase I digestion profiles of repaired DNA (following its refolding into a nucleosome structure) and bulk DNA are obtained for isolated nucleosome core particles. Analysis of the differences obtained indicates that they could reflect a significant difference in the level of repair-incorporated nucleotides at different sites within the core DNA region. To test this possibility directly, we have used exonuclease III digestion of very homogeneous sized core particle DNA to "map" the distribution of repair synthesis in these regions. Our results indicate that in a significant fraction of the nucleosomes the 5' and 3' ends of the core DNA are markedly enhanced in repair-incorporated nucleotides relative to the central region of the core particle. A best fit analysis indicates that a good approximation of the data is obtained for a distribution where the core DNA is uniformly labeled from the 5' end to position 62 and from position 114 to the 3' end, with the 52-base central region being devoid of repair-incorporated nucleotides. This distribution accounts for all of the quantitative differences observed previously between repaired DNA and bulk DNA following the rapid phase of nucleosome rearrangement when it is assumed that linker DNA and the core DNA ends are repaired with equal efficiency and the nucleosome structure of newly repaired DNA is identical with that of bulk chromatin. Furthermore, the 52-base central region that is devoid of repair synthesis contains the lowest frequency cutting sites for DNase I in vitro, as well as the only "internal" locations where two (rather than one) histones interact with a 10-base segment of each DNA strand.     

Nucleosome rearrangement in human cells following short patch repair of DNA damaged by bleomycin.

We have examined the structure of newly repaired regions of chromatin in intact and permeabilized human cells following exposure to bleomycin (BLM). The average repair patch size (in permeabilized cells) was six to nine bases, following doses of 1-25 micrograms/mL BLM, and greater than 80% of the total repair synthesis was resistant to aphidicolin. In both intact and permeabilized cells, nascent repair patches were initially very sensitive to staphylococcal nuclease, analogous to repair induced by "long patch" agents, and are nearly absent from isolated nucleosome core DNA. Unlike long patch repair, however, the loss of nuclease sensitivity during subsequent chase periods was very slow in intact cells, or in permeabilized cells treated with a low dose of BLM (1 microgram/mL), and was abolished by treatment with hydroxyurea (HU) or aphidicolin (APC). The rate of repair patch ligation did not correlate with this slow rate of chromatin rearrangement since greater than 95% of the patches were ligated within 6 h after incorporation (even in the presence of HU or APC). In permeabilized cells, repair patches induced by either 5 or 25 micrograms/mL BLM, where significant levels of strand breaks occur in compact regions of chromatin, lost the enhanced nuclease sensitivity at a rate similar to that observed following long patch repair. This rapid rate of rearrangement was not affected by APC. These results indicate that short patch repair in linker regions of nucleosomes, and/or "open" regions of chromatin, involves much less nucleosome rearrangement than long patch repair or short patch repair in condensed chromatin domains.     

Stability of nucleosome placement in newly repaired regions of DNA

Rearrangements of chromatin structure during excision repair of UV-damaged DNA appear to involve unfolding of nucleosomal DNA while repair is taking place, followed by refolding of this DNA into a native nucleosome structure. Recently, we found that repair patches are not distributed uniformly along the DNA in nucleosome core particles immediately following their refolding into nucleosomes (Lan, S. Y., and Smerdon, M. J. (1985) Biochemistry, 24,7771). Therefore, the distribution of repair patches in nucleosome core DNA was used to monitor the stability of nucleosome placement in these regions. Our results indicate that in nondividing human cells undergoing excision repair there is a slow change in the positioning of nucleosomes in newly repaired regions of chromatin, resulting in the eventual randomization of repair patches in nucleosome core DNA. Furthermore, the nonrandom placement of nucleosomes observed just after the refolding event is not re-established during DNA replication. Possible mechanisms for this change in nucleosome placement along the DNA are discussed.     

Rearrangements of chromatin structure in newly repaired regions of deoxyribonucleic acid in human cells treated with sodium butyrate or hydroxyurea

The rate and extent of redistribution of repair-incorporated nucleotides within chromatin during very early times (10-45 min) after ultraviolet irradiation were examined in normal human fibroblasts treated with 20 mM sodium butyrate, or 2-10 mM hydroxyurea, and compared to results for untreated cells. Under these conditions, DNA replicative synthesis is reduced to very low levels in each case. However, DNA repair synthesis is stimulated by sodium butyrate and partially inhibited by hydroxyurea. Furthermore, in the sodium butyrate treated cells, the core histones are maximally hyperacetylated. Using methods previously described by us, it was found that treatment with sodium butyrate had little or no effect on either the rate or the extent of redistribution of repair-incorporated nucleotides during this early time interval. On the other hand, there was a 1.7-2.5-fold decrease in the rate of redistribution of these nucleotides in cells treated with hydroxyurea; the extent of redistribution was unchanged in these cells. Since hydroxyurea has been shown to decrease the rate of completion of "repair patches" in mammalian cells, these results indicate that nucleosome rearrangement in newly repaired regions of DNA does not occur until after the final stages of the excision repair process are completed. Furthermore, hyperacetylation of the core histones in a large fraction of the total chromatin prior to DNA damage and repair synthesis does not appear to alter the rate or extent of nucleosome core formation in newly repaired regions of DNA.     

Completion of excision repair in human cells. Relationship between ligation and nucleosome formation

The completion of excision repair patches in human cells, following UV irradiation, was compared to the refolding of these regions into nucleosomes. Incomplete repair patches were detected by their enhanced sensitivity to exonuclease III. This enhanced sensitivity was due to the presence of gaps (or displaced parental strands) at the 3' end rather than unligated nicks, indicating that ligation occurs rapidly after repair synthesis is completed. Different rates of completion were achieved by treatment with the inhibitors hydroxyurea and sodium butyrate, as well as by using a (partially) ligase-deficient human cell strain. Hydroxyurea caused a marked decrease in both the rate of completion and the level of repair incorporation in all three cell types studied, while sodium butyrate yielded different effects in each cell type. In each case, however, a decrease in the rate of repair patch completion resulted in a concomitant decrease in the level of nucleosome formation. To determine the temporal relationship of these two events, the levels of repair-incorporated nucleotides in isolated 146-base pair nucleosome core DNA were compared on native and denaturing gels. The data indicate that little (or no) nucleosome formation occurred in the nascent DNA regions prior to ligation regardless of the cell type or treatment used. Furthermore, comparison of the fraction of unligated repair patches and the fraction of repair patches in a nonnucleosomal state indicated that in the absence of inhibitors there was a significant time lag between ligation and nucleosome formation. This lag time, however, decreased when cells were treated with hydroxyurea. Thus, the formation of nucleosomes in newly repaired regions of DNA occurred after the ligation step in all cases and these two features of the excision repair process are not "tightly coupled" events.     

Deficient repair of the transcribed strand of active genes in Cockayne's syndrome cells.

Removal of ultraviolet light induced cyclobutane pyrimidine dimers (CPD) from active and inactive genes was analyzed in cells derived from patients suffering from the hereditary disease Cockayne's syndrome (CS) using strand specific probes. The results indicate that the defect in CS cells affects two levels of repair of lesions in active genes. Firstly, CS cells are deficient in selective repair of the transcribed strand of active genes. In these cells the rate and efficiency of repair of CPD are equal for the transcribed and the nontranscribed strand of the active ADA and DHFR genes. In normal cells on the other hand, the transcribed strand of these genes is repaired faster than the nontranscribed strand. However, the nontranscribed strand is still repaired more efficiently than the inactive 754 gene and the gene coding for coagulation factor IX. Secondly, the repair level of active genes in CS cells exceeds that of inactive loci but is slower than the nontranscribed strand of active genes in normal cells. Our results support the model that CS cells lack a factor which is involved in targeting repair enzymes specifically towards DNA damage located in (potentially) active DNA.     

Single-stranded DNA gaps, tails and loops are repaired in Escherichia coli

Uniformly methylated heteroduplex plasmids which contained 6 mismatched regions, including loops of 24, 30, 248 and 283 nucleotides, as well as single-stranded gaps and free ends were introduced into a recombination-deficient strain of bacteria, and the products of repair were analyzed. The results indicate that these cells are capable of repairing all of these structures, although with different efficiencies. Repair of single-stranded gaps and free ends, which occurs most efficiently, is always associated with acquisition of information from the uncut strand (unidirectional repair). Regions containing single loops or twin loops were repaired at similar efficiencies. In these cases each of the two strands was capable of acting as the template for repair (bidirectional repair). At sites containing twin or substitution loops, the larger of the loops was removed twice as efficiently as the smaller loop. DNA sequencing of the repaired regions indicated that the repair is precise. The data also suggest that markers separated by only 58 nucleotides do not always segregate together indicating that repair tracts may be relatively short.