Analysis of the distribution of DNA repair patches in the DNA-nuclear matrix complex from human cells

The distribution of ultraviolet-induced repair patches along DNA loops attached to the nuclear matrix, was investigated by digestion with DNA-degrading enzymes and neutral sucrose gradient centrifugation. When DNA was gradually removed by DNAase 1, pulse label incorporated by ultraviolet-irradiated cells during 10 min in the presence of hydroxyurea or hydroxyurea/arabinosylcytosine showed similar degradation kinetics as prelabelled DNA. No preferential association of pulse label with the nuclear matrix was observed, neither within 30 min nor 13 h after irradiation. When the pulse label was incorporated by replicative synthesis under the same conditions, a preferential association of newly-synthesized DNA with the nuclear matrix was observed. Single-strand specific digestion with nuclease S1 of nuclear lysates from ultraviolet-irradiated cells, pulse labelled in the presence of hydroxyurea/arabinosylcytosine, caused a release of about 70% of the prelabelled DNA and 90% of the pulse-labelled DNA from the rapidly sedimenting material in sucrose gradients. The results suggest no specific involvement of the nuclear matrix in repair synthesis, a random distribution of repair patches along the DNA loops, and simultaneously multiple incision events per DNA loop.     

Analysis of the structure and spatial distribution of ultraviolet-induced DNA repair patches in human cells made in the presence of inhibitors of replicative synthesis

The repair of ultraviolet-induced damage in the presence of hydroxyurea or hydroxyurea and arabinosylcytosine was investigated in confluent human fibroblasts at the level of DNA loops attached to the nuclear matrix. Estimation of single-strand break frequencies based on the release of DNA from the DNA-nuclear matrix complex after incubation with nuclease S1 revealed the occurrence of multiple incision events per DNA loop in the presence of inhibitors. When both inhibitors were employed, over 90% of the repair-labelled DNA was not ligated within 2 h post-incubation. In the absence of ligation of repair patches, we observed a preferential release of repair-labelled DNA from the nuclear matrix by nuclease S1 compared to prelabelled DNA, regardless of the period of post-UV incubation. The results suggest that repair events are clustered to some extent in a certain area of a DNA loop. However, the position of these clusters relative to the attachment sites of DNA loops at the nuclear matrix is random. The data are discussed in terms of denaturation of a putative repair complex in the presence of hydroxyurea resulting in an excess of incisions over repaired sites.     

Analysis of the attachment of replicating DNA to a nuclear matrix in mammalian interphase nuclei.

The attachment of replicating DNA to a rapidly sedimenting nuclear structure was investigated by digestion with various nucleases. When DNA was gradually removed by DNase I, pulse label incorporated during either 1 min or during 1 hour in the presence of arabinosylcytosine, remained preferentially attached to the nuclear structure. Single strand specific digestion by nuclease S1 or staphylococcal nuclease at low concentrations caused a release of about 30% of the pulse label, without significantly affecting the attachment of randomly labelled DNA. The released material had a low sedimentation coefficient and contained most of the Okasaki fragments. The remaining pulse label was less accessible to further digestion by double strand specific nuclease activity than the bulk DNA. The results suggest that an attachment of the replication fork to the nuclear structure occurs at sites behind but close to the branch point.     

Preferential repair of nuclear matrix associated DNA in xeroderma pigmentosum complementation group C

The distribution of ultraviolet-induced DNA repair patches in the genome of xeroderma pigmentosum cells of complementation group C was investigated by determining the molecular weight distribution of repair labeled DNA and prelabeled DNA in alkaline sucrose gradients after treatment with the dimerspecific endonuclease V of bacteriophage T4. The results were consistent with the data reported by Mansbridge and Hanawalt (1983) and suggest that DNA-repair synthesis in xeroderma pigmentosum cells of complementation group C occurs in localized regions of the genome. Analysis of the spatial distribution of ultraviolet-induced repair patches in DNA loops attached to the nuclear matrix revealed that in xeroderma pigmentosum cells of complementation group C repair patches are preferentially situated near the attachment sites of DNA loops at the nuclear matrix. In normal human fibroblasts we observed no enrichment of repair-labeled DNA at the nuclear matrix and repair patches appeared to be distributed randomly along the DNA loops. The enrichment of repair-labeled DNA at the nuclear matrix in xeroderma pigmentosum cells of complementation group C may indicate that the residual DNA-repair synthesis in these cells occurs preferentially in transcribing regions of the genome.     

A fixed site of DNA replication in eucaryotic cells

We studied the role of the nuclear matrix (the skeletal framework of the nucleus) in DNA replication both in vivo and in a cell culture system. When regenerating rat liver or exponentially growing 3T3 fibroblasts are pulse-labeled with ³H-thymidine and nuclear matrix is subsequently isolated, the fraction of DNA remaining tightly attached to the matrix is highly enriched in newly synthesized DNA. After a 30 sec pulse labeling period and limited DNAase I digestion, the matrix DNA of 3T3 fibroblasts, which constitutes 15% of the total DNA, contains approximately 90% of the labeled newly synthesized DNA. Over 80% of this label can be chased out of the matrix DNA if the pulse is followed by a 45 min incubation with excess unlabeled thymidine. These and other kinetic studies suggest that the growing point of DNA replication is attached to the nuclear matrix. Studies measuring the size distribution of the matrix DNA also support this conclusion. Reconstitution controls and autoradiographic studies indicate that these results are not due to preferential, nonspecific binding of nascent DNA to the matrix during the extraction procedures. Electron microscopic autoradiography shows that, as with intact nuclei, sites of DNA replication are distributed throughout the nuclear matrix. A fixed site of DNA synthesis is proposed in which DNA replication complexes are anchored to the nuclear matrix and the DNA is reeled through these complexes as it is replicated.     

Intranuclear localization of UV-induced DNA repair in human VA13 cells

We have investigated the intranuclear localization of DNA-repair synthesis in G1-phase VA13 human cells. Ultraviolet-irradiated cells were permitted to perform unscheduled DNA synthesis in 3H-thymidine (3H-TdR) and then extracted with nonionic detergent and 2 M NaCl to produce nucleoids in which residual nuclear matrix was surrounded by an extended halo of DNA loops. Autoradiographic analysis of these structures permitted discrimination of DNA repair between the matrix and halo regions. Repair label in nucleoids prepared from cells after exposure to fluences of 2.5-30 J/m2 exhibited a dose-dependent association with the nuclear matrix, which ranged from 80% after 2.5 J/m2 to 50% after 30 J/m2. These results support the view that DNA repair is a nuclear matrix-associated process. This conclusion is in agreement with our preliminary study (Harless et al., 1983) and the results of McCready and Cook (1984) but contrasts with that of Mullenders et al. (1983). Questions concerning the differing experimental designs and their potential effects on the localization of DNA repair are discussed. The implications of these results to previous attempts to isolate chromatin factors associated with DNA repair are also considered.     

Organization of DNA replication in Physarum polycephalum. Attachment of origins of replicons and replication forks to the nuclear matrix.

We have investigated the attachment of the DNA to the nuclear matrix during the division cycle of the plasmodial slime mold Physarum polycephalum. The DNA of plasmodia was pulse labelled at different times during the S phase and the label distribution was studied by graded DNase digestion of the matrix-DNA complexes prepared from nuclei isolated by extraction with 2 M NaCl. Pulse labelled DNA was preferentially recovered from the matrix bound residual DNA at any time of the S phase. Label incorporated at the onset of the S phase remained preferentially associated with the matrix during the G2 phase and the subsequent S phase. The occurrence of the pulse label in the matrix associated DNA regions was transiently elevated at the onset of the subsequent S phase. Label incorporated at the end of the S phase was located at DNA regions which, in the G2 phase, were preferentially released from the matrix by DNase treatment. From the results and previously reported data on the distribution of attachment sites it can be concluded that origins of replicons or DNA sites very close to them are attached to the matrix during the entire nuclear cycle. The data further indicate that initiations of DNA replication occur at the same origins in successive S phases. Replicating DNA is bound to the matrix, in addition, by the replication fork or a region close to it. This binding is loosened after completion of the replication.     

Multiple conformational states of repair patches in chromatin during DNA excision repair

In mammalian cells, newly synthesized DNA repair patches are highly sensitive to digestion by staphylococcal nuclease (SN), but with time, they acquire approximately the same nuclease resistance as the DNA in bulk chromatin. We refer to the process which restores native SN sensitivity to repaired DNA as chromatin rearrangement. We find that during repair of ultraviolet damage in human fibroblasts, repair patch synthesis and ligation occur at approximately the same rate, with ligation delayed by about 4 min, but that chromatin rearrangement is only 75% as rapid. Thus, repair-incorporated nucleotides can exist in at least three distinct states: unligated/unrearranged, ligated/unrearranged, and ligated/rearranged. Inhibition of repair patch synthesis by aphidicolin or hydroxyurea results in inhibition of both patch ligation and chromatin rearrangement, confirming that repair patch completion and/or ligation are prerequisites for rearrangement. We also analyze the kinetics of SN digestion of repair-incorporated nucleotides at various extents of rearrangement and find the data to be consistent with the existence of two or more forms of unrearranged repair patch which have different sensitivities to digestion by SN. These data indicate that the chromatin rearrangement which restores native SN sensitivity to repaired DNA is a multistep process. The multiple forms of unrearranged chromatin with different SN sensitivities may include the unligated/unrearranged and ligated/unrearranged states. If so, the differences in SN sensitivity must arise from differences in chromatin structure, because SN does not differentiate between ligated and unligated repair patches in naked DNA.     

Inhibition by hyperthermia of repair synthesis and chromatin reassembly of ultraviolet-induced damage to DNA

We have investigated the effects of hyperthermia treatment on sequential steps of the repair of UV-induced DNA damage in HeLa cells. DNA repair synthesis was inhibited by 40% after 15 min of hyperthermia treatment at 45 degrees C; greater inhibition of repair synthesis occurred with prolonged incubation at 45 degrees C. Enzymatic digestion of repair-labeled DNA with Exonuclease III indicated that once DNA repair was initiated, the DNA repair patch was synthesized to completion and that ligation of the DNA repair patch occurred. Thus the observed inhibition of UV-induced DNA repair synthesis by hyperthermia treatment may be the result of inhibition of enzymes involved in the initiating step(s) of DNA repair. DNA repair patches synthesized in UV-irradiated cells labeled at 37 degrees C with [3H]Thd were 2.2-fold more sensitive to micrococcal nuclease digestion than was parental DNA; if the length of the labeling period was prolonged, the nuclease sensitivity of the repair patch synthesized approached that of the parental DNA. DNA repair patches synthesized at 45 degrees C, however, remained sensitive to micrococcal nuclease digestion even after long labeling periods, indicating that heat treatment inhibits the reassembly of the DNA repair patch into nucleosomal structures.     

Initiation of unscheduled synthesis on DNA sites associated with a nuclear matrix of irradiated hepatoma cells

A study was made of the distribution of unscheduled DNA synthesis (induced by UV- or gamma-radiation and resistant to hydroxyurea) between the DNA sites in the nuclear matrix and total nuclear DNA of Zajdela ascites hepatoma cells. It was shown that during the first 1.5 to 5 min of the postirradiation incubation the rate of the unscheduled synthesis of DNA was considerably higher in the DNA fraction, firmly associated with the nuclear matrix proteins, than in the total nuclear DNA.     

The periodic loss of metabolically unstable DNA during replication of chromosomal DNA of CHO cells

The fate of ³H-thymidine incorporated into newly synthesized DNA of CHO cells was analyzed by either the estimation of the incorporated radioactivity per cell or sedimentation in alkaline sucrose gradient. Under conditions in which DNA synthesis proceeded continuously, of incorporated radioactivity was periodically lost and regained during a 90 min chase, corresponding to a cyclic change in the sedimentation profiles. When DNA synthesis was inhibited by hydroxyurea no cyclic change of the incorporated radioactivity was observed. The cyclic changes were regarded as the result of an actual metabolic change in³H-labelled DNA probaly joining to one of the newly formed sister strands of DNA and the loss of radioactivity seems to require active continued DNA synthesis.     

Association of transcriptionally active vitellogenin II gene with the nuclear matrix of chicken liver

Supercoiled DNA loops linked to the nuclear matrix can be progressively cleaved with deoxyribonuclease I. The DNA which remains associated with the nuclear matrix can be purified and analysed for vitellogenin II sequence content by dot blot hybridization. Using this technique we show that vitellogenin II gene sequences are selectively associated with the nuclear matrix of liver but not with oviduct of laying hens. Following primary stimulation in immature chicks of vitellogenin synthesis with estradiol, the association of the gene with the nuclear matrix precedes vitellogenin mRNA synthesis. After 15 days when the level of vitellogenin mRNA has returned to zero, the gene is no longer preferentially associated with the nuclear matrix. At this time a second stimulation with estradiol results in a reassociation of the vitellogenin II gene with the nuclear matrix. In addition to the structural gene, both the 3' and 5' end flanking regions (1.5-2 kb) also bind to the nuclear matrix. However, beyond the limit of 1.5-2 kb upstream from the 5' end of the gene, there is no preferential binding of DNA to the nuclear matrix.     

Ultraviolet-induced DNA excision repair in human B and T lymphocytes. II. Effect of inhibitors and DNA precursors.

Despite their great sensitivity to ultraviolet light purified human B and T lymphocytes are capable of complete repair provided that the ultraviolet dose does not exceed 0.5 Jm-2. Their capacity to repair, as measured by the restoration of DNA supercoiling in preparations of nucleoids, and their survival are significantly increased in the presence of deoxyribonucleosides. Certain agents which inhibit semi-conservative DNA synthesis (hydroxyurea, 1-beta-D-arabinofuranosylcytosine (arafCyt) either stop or delay the repair process in lymphocytes. The effect of hydroxyurea is eventually overcome spontaneously, but changes in the sedimentation behaviour of ultraviolet-irradiated nucleoids caused by arafCyt can only be neutralized by addition of deoxycytidine. The effective inhibition of repair by arafCyt permits the detection of extremely small amounts of ultraviolet damage and also the estimation of when repair is complete.     

Complementation of the xeroderma pigmentosum DNA repair defect in cell-free extracts

Soluble extracts from human lymphoid cell lines that perform repair synthesis on covalently closed circular DNA containing pyrimidine dimers or psoralen adducts are described. Short patches of nucleotides are introduced by excision repair of damaged DNA in an ATP-dependent reaction. Extracts from xeroderma pigmentosum cell lines fail to act on damaged circular DNA, but are proficient in repair synthesis of ultraviolet-irradiated DNA containing incisions generated by Micrococcus luteus pyrimidine dimer-DNA glycosylase. Repair is defective in extracts from all xeroderma pigmentosum cell lines investigated, representing the genetic complementation groups A, B, C, D, H, and V. Mixing of cell extracts of group A and C origin leads to reconstitution of the DNA repair activity.     

DNA replication and the nuclear envelope

Upon isolation of the nuclear membrane from cultured mouse leukemia L5178Y cells, approximately 1% of the total nuclear DNA was found to be attached to this structure. After pulse labeling of DNA and isolation of the nuclear membrane, the ratio of labeled DNA in the membrane fraction and in the rest of chromatin was compared. Results indicate that with a 3 min pulse, DNA in the membrane fraction showed slightly higher specific activity, but when the pulse was longer than 5 min there was no difference in the specific activities. Since the DNA fragment associated with the membrane fraction was found to be long enough to contain most of the DNA labeled during a 5 min pulse, the results obtained indicate that there is no preferential association of DNA to the nuclear envelope during initiation or elongation of DNA.     

Cytochemical localization of DNA loop attachment sites to the nuclear lamina and to the inner nuclear matrix

Summary The rat liver nuclear matrix, obtained by endogenous nuclease digestion and extraction with low and high lonic strength media, contains residual DNA fragments that are considered to represent the attachment sites of the chromatin domains to the nucleoskeleton. These sites, protected against nuclease digestion by their binding with the nucleoskeleton proteins, should be either mainly linked to the peripheral lamina or to the inner nuclear matrix. The DNA fragment distribution at the level of the different components of the nuclear matrix has been evaluated in samples embedded in Epon and in hydrophilic resins by means of the DNase-gold technique. The labeling obtained suggests that the chromatin loops are prevailingly associated with the interior of the matrix; in fact about twice of the label is present in the inner matrix with respect to the peripheral lamina area.These results confirm the hypothesis that in interphase the chromatin maintains an organization similar to that of chromosomes, with loops radiating from a central scaffold, instead of being mainly attached to the lamina as otherwise suggested.     

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.     

Proximity of repair patches to persistent pyrimidine dimers in DNA of normal human and xeroderma pigmentosum cells

The proximity of repair patches to persistent pyrimidine dimers in normal human cells and xeroderma pigmentosum group C and D cells was analyzed by sequential digestion of repaired DNA with Micrococcus luteus UV-endonuclease and Escherichia coli DNA polymerase I. Although this enzymatic digestion removed one-third of the pyrimidine dimers, less than 3% of the label associated with repair patches and a similar amount of uniformly labeled DNA were removed. The repair patches therefore appear to be similarly distant from persistent dimers in all cell types, and, in particular, are not adjacent to unexcised dimers in xeroderma pigmentosum group D cells. A previous model that suggested that patches are inserted adjacent to dimers in xeroderma pigmentosum group D cells receives no support from these results.