DNA repair in Cockayne syndrome.

Cockayne syndrome (CS) is a rare recessive genetic disease characterized in part by premature ageing and photosensitive skin. Because of the latter characteristic, this syndrome was considered to be an example of a UV-sensitive DNA repair-defective human disorder. We demonstrated normal levels of UV-induced unscheduled DNA synthesis (UDS) in four unrelated CS patients that show hypersensitivity to both UV and Mitomycin C (MMC). At low UV exposure, CS DNA shows a dose-dependent decrease in size. By contrast, heterozygotes appear to have a threshold below which there is little change in size of single strand DNA. Immediately following UV or MMC treatment, CS DNA is deficient in high molecular weight species, but undergoes a normal transition to larger DNA during a chase interval in the presence or absence of caffeine. This suggests a defect in replication or excision repair and no defect in post-replication repair (PRR). Pulse studies performed in the presence of hydroxyurea (HU) also reveal a deficient production of large DNA, suggesting the defect is in repair. As these cells have normal UDS and normal PRR, the basis for their UV sensitivity must be distinct from that observed in xeroderma pigmentosum (XP).     

Repair of O6-ethylguanine DNA lesions in isolated cell nuclei. Presence of the activity in the chromatin proteins

Cell nuclei prepared from rat liver were alkylated in vitro with ethylnitrosourea; the nuclear DNA was found to lose O6-ethylguanine and 7-ethylguanine during a subsequent incubation at 37 degrees C. The rate of O6-ethylguanine loss is comparable to that observed in vivo, indicating that no cytoplasmic component is needed for the repair; no free O6-ethylguanine was found in the incubation medium of the ethylated nuclei. The rate of 7-ethylguanine loss is higher than the spontaneous depurination in vitro and an amount of free 7-ethylguanine equivalent to that lost by the nuclear DNA was found in the incubation medium; these results suggest that this DNA lesion is excised by a DNA glycosylase. The proteins of the chromatin prepared from the isolated nuclei induced the disappearance of O6-ethylguanine from an added ethylated DNA. No free O6-ethylguanine was released indicating that the repair is not catalyzed by a DNA glycosylase; no oligonucleotides enriched in O6-ethylguanine were released either, indicating that the disappearance of O6-ethylguanine from DNA is not the result of the cooperative action of a specific endonuclease and an exonuclease. Activities capable of removing O6-ethylguanine from DNA were found in other cell compartments; most of it, however, is in the nucleus where the main location is chromatin. A pretreatment of the rats with daily low doses of diethylnitrosamine during 3 or 4 weeks increased 2-3-times the repair activity of the chromatin proteins.     

Digestion of chromosomal proteins in formaldehyde treated chromatin

Treatment of chromatin subunits (nucleosome monomers) with formaldehyde results in the formation of cross-links between DNA and histones and between histones and histones. Digestion of chromosomal proteins with proteinase K does not lower the protein/DNA weight ratio below 0.08 to 0.1 as determined by cesium chloride gradient centrifugation of the digestion product from formaldehyde-treated nucleosomes. In addition to proteinase K, formaldehyde-treated nucleosomes were tested for accessibility to trypsin and pronase. The CsCl gradient patterns show, that pronase digestion and proteinase K treatment yield similar results. Trypsin treatment of control and formaldehyde-treated nucleosomes shows, that the sites which are accessible for trypsin in native nucleosomes, are blocked after formaldehyde treatment. Analysis of the CsCl gradient peak fractions in polyacrylamide gels shows, that the reliability of DNA fragment size determinations depends on the completeness of deproteinization.     

Degradation of chromosomal proteins during dissociation and reconstitution of chromatin

Histones and nonhistone chromosomal proteins are degraded when chromatin is exposed to 2 M NaCl-5 M urea (pH 6–8) which has been most often used for disscciation and reconstitution of chromatin. Histones and nonhistone proteins are also degraded in 5 M urea (pH 6–8).     

Repair of intrinsic DNA lesions

The repair of apurinic/apyrimidinic (AP) sites is described. The major pathway involves hydrolysis of the stable phosphodiester bond on the 5′ side of the lesion by an AP endonuclease. The 5′ terminal deoxyribose-phosphate residue is excised by a separate phosphodiesterase which does not appear to be an exonuclease. Repair replication of the single missing nucleotide residue by a DNA polymerase and ligation complete the excision-repair process. The possibility that minor DNA lesions may accumulate with time in long-lived cells is considered. Such lesions should be chemically stable and should not be recognized by DNA-repair enzymes.