A cell cycle-associated pathway for repair of DNA-protein crosslinks in mammalian cells

Bulky adducts to DNA including DNA-protein crosslinks formed with trans-platinum(II)diammine-dichloride are repaired largely by the nucleotide excision pathway in mammalian cells. The discovery in this laboratory that cells deficient in nucleotide excision repair, i.e., SV40-virus transformed SV-XP20S cells, can efficiently repair DNA-protein crosslinks implicates a second pathway. In this report, details concerning this pathway are presented. DNA-protein crosslinks induced with 20 microM trans-platinum were assayed by the membrane alkaline elution procedure of Kohn. DNA replication was measured by CsCl gradient separation of newly synthesized DNA that had incorporated 5-bromodeoxyuridine. The following results indicate that this new repair pathway is associated with cell cycling: Whereas rapidly proliferating human cells deficient in excision repair (SV40 transformed XP20S, group A) are proficient in repair of DNA-protein crosslinks, the more slowly growing untransformed parent line is deficient but can complete repair after prolonged periods of 4-6 days, the approximate doubling time of the cell population. Either "used" culture medium or cycloheximide (1 microgram/ml) inhibits cell proliferation, protein synthesis, DNA replication and crosslink repair. In the presence of increasing concentrations of cycloheximide (0.01-5 micrograms/ml) the percent of DNA replication decreases and is essentially equivalent to the percent of crosslink repair. The following results indicate that this new repair pathway, though associated with cell cycling, is independent of DNA replication per se. The rates of DNA-protein crosslink repair and DNA replication are essentially the same in mouse L1210 cells rapidly proliferating in 20% serum supplement; however, to slower proliferation rates in 1% serum rate of crosslink repair is slower but differs from that of DNA replication. In the presence of aphidicolin (10 micrograms/ml) cells can repair DNA-protein crosslinks in virtually the complete absence of DNA replication, though the rate is slower in both nucleotide excision-proficient and -deficient cells. Thus, DNA replication is not essential for repair of DNA-protein crosslinks. Comparison of the kinetics of replication and DNA-protein crosslink repair of pulse-labeled indicates that, in the absence of metabolic inhibitors, repair of the crosslinks is independent of replication per se and, therefore, DNA recombination events are not involved in this repair process. We conclude, therefore, that the new repair pathway is not coupled with DNA replication but is with cell cycling.     

Telomere structure in Euplotes crassus: characterization of DNA-protein interactions and isolation of a telomere-binding protein.

The nucleoprotein structure of telomeres from Euplotes crassus was studied by using nuclease and chemical footprinting. The macronuclear telomeres were found to exist as DNA-protein complexes that are resistant to micrococcal nuclease digestion. Each complex encompassed 85 to 130 base pairs of macronuclear DNA and appeared to consist of two structural domains that are characterized by dissimilar DNA-protein interactions. Dimethyl sulfate footprinting demonstrated that very sequence-specific and salt-stable interactions occur in the most terminal region of each complex. DNase I footprinting indicated that DNA in the region 30 to 120 base-pairs from the 5' end lies on a protein surface; the interactions in this region of the complex are unlikely to be sequence specific. A 50-kilodalton telomere-binding protein was isolated. Binding of this protein protected telomeric DNA from BAL 31 digestion and gave rise to many of the sequence-specific DNA-protein interactions that were observed in vivo. The telomeric complexes from E. crassus were very similar in overall structure to the complexes found at Oxytricha telomeres. However, telomeric complexes from the two ciliates showed significant differences in internal organization. The telomeric DNA, the telomere-binding proteins, and the resultant DNA-protein interactions were all somewhat different. The telomere-binding proteins from the two ciliates were found to be less closely conserved than might have been expected. It appears that the proteins are tailored to match their cognate telomeric DNA.     

Effects of nickel(II) on nuclear protein binding to DNA in intact mammalian cells

An intracellular effect of nickel(II) which may be involved in its carcinogenic action is the alteration of normal DNA-protein binding. This effect of ionic nickel was studied in Chinese hamster ovary cells using several chromatin isolation methods in combination with SDS-polyacrylamide gel electrophoresis. DNA from cells incubated with (35S)-methionine or (35S)-cysteine to radiolabel protein was prepared by three methods: (solation of nuclei or nucleoids followed by chloroform-isoamyl alcohol (24:1 v/v) extraction and in some cases an additional extraction in the absence or presence of 2M NaCl, 40 mM EDTA or SDS; by isopycnic centrifugation through Cs2SO4 gradients containing 0.8% sarkosyl, 2.2 MCs2SO4, 1 mM NaCl and 10 mM EDTA; or by chromatin disaggregation and denaturation using 9 M urea, 2% 2-mercaptoethanol, 4% Nonidet P-40 +/- 2 M NaCl. DNA from nickel-treated cells consistently had more (35S)-methionine radioactivity associated with it than did DNA from untreated cells. This radioactivity was resistant to ribonuclease but sensitive to protease. Differential extraction using denaturing agents and high ionic strength followed by SDS-polyacrylamide gel electrophoresis revealed that most of the tightly bound proteins were nonhistone chromosomal proteins, and possibly histone 1. The enhancement of DNA-protein binding from nickel-treated cells was disrupted by SDS, suggesting that nickel ions do not function as classical bifunctional crosslinking agents. Since regulation of DNA replication and gene expression is dependent upon DNA-protein interactions, the effect of nickel in altering the extent of DNA-protein binding may interfere with this regulation and may contribute to the carcinogenic activity of nickel compounds.     

Supercoiled DNA folded by nonhistone proteins in cultured mouse carcinoma cells.

Upon gentle lysis of exponentially growing mouse carcinoma cells FM3A by sodium dodecyl sulfate, DNA was released as a "DNA-protein complex" in a folded conformation. No histones could be detected in the DNA-protein complex. The proteins bound to DNA were found to be composed of several kinds of nonhistone proteins with a molecular weight range of 50,000 to 60,000; they appear to play a key role in stabilizing and maintaining the compact and folded structure of the complex. Removal of the proteins by Pronase or 2-mercaptoethanol produced a more relaxed structure sedimenting about half as fast as the original complex in a neutral sucrose gradient. DNA in the folded complex is supercoiled, as indicated by the characteristic biphasic response of its sedimentation rate to increasing concentration of various intercalating agents, actinomycin D, ethidium bromide and acriflavine, with which the cells were treated before lysis. Pronase- or 2-mercaptoethanol-treated relaxed DNA still possessed the characteristic of closed-circular structure as judged from its response to intercalating agents. Nicking with gamma-ray or 4NQO broke these superhelical turns and relaxed the folded complex to slower sedimenting forms equivalent to the relaxed DNA obtained on treatment with Pronase or 2-mercaptoethanol. Viscometric observations of DNA-protein complex were consistent with the above results. A tentative model for the structure of this DNA-protein complex is proposed in which supercoiled DNA is folded into loops by several kinds of nonhistone proteins. Autoradiographic examination of the complex appeared to support this model.     

Properties of the telomeric DNA-binding protein from Oxytricha nova

Telomeres of Oxytricha macronuclear DNA exist as discrete DNA-protein complexes. Different regions of each complex display characteristic DNA-protein interactions. In the most terminal region, binding of a 43- and a 55-kDa protein to the telomeric DNA appears to account for all the DNA-protein interactions that can be detected by chemical and nuclease footprinting. We have used gradient sedimentation and protein-protein cross-linking to establish that the 43- and 55-kDa proteins are subunits of a heterodimer. Both subunits are very basic, which is unexpected considering the resistance of the DNA-protein interaction to high concentrations of salt. It is extremely difficult to dissociate the two subunits either from telomeric DNA or from each other. Even after extensive treatment of protein preparations with nuclease, a fragment of the 3' tail from macronuclear DNA remains bound to the protein. A wide range of conditions was screened for dissociation of the subunits from the DNA and/or from each other. Dissociation was only obtained by using conditions that caused some inactivation of the DNA-binding capacity of the protein. The use of reagents that covalently modify sulfydryl groups during the purification procedure facilitates preparation of telomere protein with full DNA-binding activity.     

Expression of an enhancer-binding protein in insect cells transfected with the Autographa californica nuclear polyhedrosis virus IE1 gene.

The baculovirus Autographa californica nuclear polyhedrosis virus contains an element known as homologous region 5 (hr5) which is an enhancer of delayed-early viral gene expression. To begin to identify proteins that interact with hr5, DNA-protein interactions were analyzed by using extracts from Spodoptera frugiperda cells and a fragment of DNA containing the left half of the hr5 enhancer. This 252-bp DNA fragment contains two copies of a 30-bp direct repeat (DR30) and two copies of a 24-bp imperfect palindrome contained within a 60-bp direct repeat (DR60). Extracts prepared from normal S. frugiperda cells and cells transfected with pUC8 lacked enhancer-binding proteins. However, when gel shift assays were performed with extracts from cells transfected with a plasmid containing the viral trans-activator IE1 gene, two DNA-protein complexes were formed. Both DNA-protein complexes were specifically inhibited by competition with a 60-bp oligonucleotide corresponding to DR60 but not by competition with a different oligonucleotide corresponding to DR30. Formation of the two complexes did not appear to involve cooperative interactions between binding proteins. When DR60 was used as a probe, a single complex was formed. To measure the enhancer activity of DR60, a reporter plasmid was constructed that contained DR60 cloned upstream of the reporter chloramphenicol acetyltransferase gene under the control of the delayed-early 39K promoter. Transient expression analysis indicated that the oligonucleotide increased expression of this gene 300-fold over the level obtained in the absence of any enhancer sequences.     

Analysis of DNA-protein crosslinking activity of malondialdehyde in vitro

In an attempt to identify endogenous chemicals producing DNA-protein crosslinks, we have studied in vitro crosslinking potential of malondialdehyde, a bifunctional chemical that is ubiquitously formed as a product of lipid peroxidation of polyunsaturated fatty acids. We have found that malondialdehyde readily forms crosslinks between DNA and histones under physiological ionic and pH conditions. Formation of DNA-protein crosslinks was limited to proteins that were able to bind to DNA. Malondialdehyde failed to form DNA-protein crosslinks when histone binding to DNA was prevented by elevated ionic strength or when bovine serum albumin was used in the reaction mixture. Malondialdehyde-produced DNA-histone crosslinks were relatively stable at 37 degrees C with t1/2=13.4 days. Crosslinking of histones to DNA proceeds through the initial formation of protein adduct followed by reaction with DNA. Modification of DNA by malondialdehyde does not lead to a subsequent crosslinking of proteins. Significant formation of DNA-protein crosslinks was also registered in isolated kidney and liver nuclei treated with malondialdehyde. Based on its reactivity and stability of the resulting crosslinks, it is suggested that malondialdehyde could be one of the significant sources of endogenous DNA-protein crosslinks.     

The structure of the complexes of DNA with chromosomal protein HMGB1 and histone H1 in the presence of manganese ions. I. Circular dicroism spectroscopy

The mechanisms of interaction of the non-histone chromosomal protein HMGB1 and linker histone H1 with DNA have been studied using circular dichroism and absorption spectroscopy. Both of the proteins are located in the inter-nucleosomal regions of chromatin. It was demonstrated that properties of the DNA-protein complexes depend on the protein content and can not be considered as a simple summing up of the effects of individual protein components. Interaction of HMGB1 and H1 proteins is shown to be co-operative rather than competitive. Lysine-rich histone H1 facilitates the binding of the HMGB1 with DNA by screening the negatively charged groups of the sugar-phosphate backbone of DNA and dicarboxylic amino-acid residues in the C-terminal domain of the HMGB1 protein. The observed joint action of the and H1 proteins stimulates DNA condensation with formation of the anisotropic DNA-protein complexes with typical psi-type CD spectra. Structural organization of the complexes depends not only on the DNA-protein interactions, but also on the interaction between HMGB1 and H1 protein molecules bound to DNA. Manganese ions significantly modify the character of interactions between the components in the triple DNA-HMGB1-H1 complex. Binding of Mn2+ ions causes the weakening of the DNA-protein interactions and strengthening the protein-protein interactions, which promote DNA condensation and formation of large DNA-protein particles in solution.     

Analysis of the interaction of cyanobacterial HU-type protein and supercoiled circular DNA

The use of small topoisomerised DNA rings to study in vitro DNA-protein interactions with a cyanobacterial HU-type protein allowed to obtain stable complexes which in turn distinguish the properties of that protein as compared with those of histones. Like histones, the HU-type protein is able to compact topoisomers under two forms, but unlike histones, these two compacted forms cannot be separated by sedimentation. Similar cross-links, when observed with histones, are obtained by formaldehyde-mediated DNA-HU type protein cross-links.     

Structure of DNA complexes with chromosomal protein HMGB1 and histone H1 in the presence of manganese ions: 1. Circular dichroism spectroscopy

Mechanisms of interaction of DNA with nonhistone chromosomal protein HMGB1 and linker histone H1 have been studied by means of circular dichroism and absorption spectroscopy. Both proteins are located in the internucleosomal regions of chromatin. It is demonstrated that the properties of DNA-protein complexes depend on the protein content and cannot be considered as a mere summing up of the effects of individual protein components. Interaction of the HMGB1 and H1 proteins is shown with DNA to be cooperative rather than competitive. Lysine-rich histone H1 facilitates the binding of HMGB1 to DNA by screening the negatively charged groups of the sugar-phosphate backbone of DNA and dicarboxylic amino acid residues in the C-terminal domain of HMGB1. The observed joint action of HMGB1 and H1 stimulates DNA condensation with the formation of anisotropic DNA-protein complexes with typical ψ-type CD spectra. Structural organization of the complexes depends not only on DNA-protein interactions but also on interaction between the HMGB1 and H1 protein molecules bound to DNA. Manganese ions significantly modify the mode of interactions between components in the triple DNA-HMGB1-H1 complex. The binding of Mn²⁺ ions weakens DNA-protein interactions and strengthens protein-protein interactions, which promote DNA condensation and formation of large DNA-protein particles in solution.     

Effect of nickel(II) on DNA-protein interactions

Alterations in DNA-protein interactions (DPI) may play an important role in carcinogenesis. Although the mechanism of nickel carcinogenesis is unknown, nickel reportedly affects DPI. A microfiltration, nitrocellulose filter assay was utilized to study DPI in intact Chinese hamster ovary (CHO) cells and in isolated nuclei. Prior to exposure of CHO cells or isolated CHO cell nuclei, DNA and proteins were radiolabeled using³H-thymidine and³⁵S-methionine, respectively. Nuclei were exposed to NiCl₂ in 10 mM HEPES buffer (pH 6.8). CHO cells were exposed in either complete or a salts-glucose medium. Following exposure, nuclei or cells were incubated at 37°C for 20 min in a high salt lysis solution; aliquots were loaded onto nitrocellulose filters and washed with a low salt solution. DNA (³H) retained on each filter was normalized to protein (³⁵S) bound on the filter. Exposure of either whole cells or isolated nuclei to increasing, noncytotoxic concentrations of NiCl₂ resulted in a dose dependent decrease in DPI. The effect of nickel on specific DNA-protein interactions was examined using a band shift assay and a cloned satellite DNA sequence. Nickel inhibited specific protein binding to the satellite DNA probe. The results of these two independent assays, which were conducted at physiological pH, indicate that NiCl₂ inhibits specific DNA-protein interactions.     

Site-directed mutagenesis studies of tn5 transposase residues involved in synaptic complex formation

Transposition (the movement of discrete segments of DNA, resulting in rearrangement of genomic DNA) initiates when transposase forms a dimeric DNA-protein synaptic complex with transposon DNA end sequences. The synaptic complex is a prerequisite for catalytic reactions that occur during the transposition process. The transposase-DNA interactions involved in the synaptic complex have been of great interest. Here we undertook a study to verify the protein-DNA interactions that lead to synapsis in the Tn5 system. Specifically, we studied (i) Arg342, Glu344, and Asn348 and (ii) Ser438, Lys439, and Ser445, which, based on the previously published cocrystal structure of Tn5 transposase bound to a precleaved transposon end sequence, make cis and trans contacts with transposon end sequence DNA, respectively. By using genetic and biochemical assays, we showed that in all cases except one, each of these residues plays an important role in synaptic complex formation, as predicted by the cocrystal structure.     

Enhanced infectivity of adenovirus type 2 DNA and a DNA-protein complex.

The infectivity of adenovirus type 2 DNA and a DNA-protein complex was studied in 293 cells, a human embryonic kidney cell line transformed by sheared adenovirus type 5 DNA, and in human KB cells. Adenovirus type 2 DNA was more infectious (up to about 40-fold) in 293 cells than in KB cells, whereas a DNA-protein complex (prepared by a rapid procedure) had about the same infectivity in both cell lines. These data may mean that a factor present in 293 cells (perhaps a viral-coded protein) enhances the infectivity of free viral DNA. The infectivity of DNA and the DNA-protein complex was increased up to fivefold by brief treatment of cell monolayers with 25% dimethyl sulfoxide after transfection. Under these conditions, (i) the infectivity of native adenovirus type 2 DNA ranged from 400 to 1,300 PFU/microgram of DNA in 293 cells and from about 9 to 14 PFU/microgram of DNA in KB cells, and (ii) the infectivity of the DNA-protein complex was 6 X 10(3)to 2 X 10(4) PFU/microgram in 293 cells and 1.4 X 10(4) to 1.6 X 10(4) PFU/microgram in KB cells.     

Analysis of DNA-protein complexes induced by chemical carcinogens.

DNA-protein complexes induced in intact cells by chromate have been isolated and compared with those formed by other agents such as cis-platinum. Actin has been identified as one of the major proteins that is complexed to the DNA by chromate based upon a number of criteria including, a molecular weight and isoelectric point identical to actin, positive reaction with actin polyclonal antibody, and proteolytic mapping. Chromate and cis-platinum both complex proteins of very similar molecular weight and isoelectric points and these complexes can be disrupted by exposure to chelating or reducing agents. These results suggest that the metal itself is participating in rather than catalyzing the formation of a DNA-protein complex. An antiserum which was raised to chromate-induced DNA-protein complexes reacted primarily with a 97,000 protein that could not be detected by silver staining. Western blots and slot blots were utilized to detect p97 DNA-protein complexes formed by cis-platinum, UV, formaldehyde, and chromate. Other work in this area, involving studying whether DNA-protein complexes are formed in actively transcribed DNA compared with genetically inactive DNA, is discussed. Methods to detect DNA-protein complexes, the stability and repair of these lesions, and characterization of DNA-protein complexes are reviewed. Nuclear matrix proteins have been identified as a major substrate for the formation of DNA-protein complexes and these findings are also reviewed.     

DNA damage and cytotoxicity of nitracrine in cultured HeLa cells

The effects of nitracrine (1-nitro-9-(3,3-N,N-dimethylaminopropylamino)acridine on DNA of cultured HeLa cells were studied. DNA strand breakage and interstrand cross-linking as well as DNA-protein cross-linking were measured by means of an alkaline elution technique and were compared with the cytotoxic effect of the drug. Interstrand cross-links were not detectable in the concentration range that inhibited cell growth up to 99%. DNA single-strand breaks were found when cells were treated with highly cytotoxic doses of the drug. DNA breakage was not reparable and exhibited a tendency to increase during incubation after drug removal. The only chromatin lesion induced by sublethal doses of nitracrine were DNA-protein cross-links which persisted for 24 h after drug treatment. It is concluded that DNA breaks represent degraded DNA from dying cells, whereas DNA-protein cross-links are specific cellular lesions, which may be responsible for the cell-killing effect of nitracrine.     

Measurements of alkali-labile DNA damage and protein-DNA crosslinks after 2450 MHz microwave and low-dose gamma irradiation in vitro

In vitro experiments were performed to determine whether 2450 MHz microwave radiation induces alkali-labile DNA damage and/or DNA-protein or DNA-DNA crosslinks in C3H 10T(1/2) cells. After a 2-h exposure to either 2450 MHz continuous-wave (CW) microwaves at an SAR of 1.9 W/kg or 1 mM cisplatinum (CDDP, a positive control for DNA crosslinks), C3H 10T(1/2) cells were irradiated with 4 Gy of gamma rays ((137)Cs). Immediately after gamma irradiation, the single-cell gel electrophoresis assay was performed to detect DNA damage. For each exposure condition, one set of samples was treated with proteinase K (1 mg/ml) to remove any possible DNA-protein crosslinks. To measure DNA-protein crosslinks independent of DNA-DNA crosslinks, we quantified the proteins that were recovered with DNA after microwave exposure, using CDDP and gamma irradiation, positive controls for DNA-protein crosslinks. Ionizing radiation (4 Gy) induced significant DNA damage. However, no DNA damage could be detected after exposure to 2450 MHz CW microwaves alone. The crosslinking agent CDDP significantly reduced both the comet length and the normalized comet moment in C3H 10T(1/2) cells irradiated with 4 Gy gamma rays. In contrast, 2450 MHz microwaves did not impede the DNA migration induced by gamma rays. When control cells were treated with proteinase K, both parameters increased in the absence of any DNA damage. However, no additional effect of proteinase K was seen in samples exposed to 2450 MHz microwaves or in samples treated with the combination of microwaves and radiation. On the other hand, proteinase K treatment was ineffective in restoring any migration of the DNA in cells pretreated with CDDP and irradiated with gamma rays. When DNA-protein crosslinks were specifically measured, we found no evidence for the induction of DNA-protein crosslinks or changes in amount of the protein associated with DNA by 2450 MHz CW microwave exposure. Thus 2-h exposures to 1.9 W/ kg of 2450 MHz CW microwaves did not induce measurable alkali-labile DNA damage or DNA-DNA or DNA-protein crosslinks.     

Comparative analysis of subdomain fragments of chromatin

Nuclei isolated from Djungarian hamster fibroblasts transformed by SV40 were treated with restriction endonuclease Bsp RI, fixed on Celite columns and underwent successive gradients of dissociating agents, such as NaCl, LiCl-urea, and temperature. This procedure leads to fractionation of DNA fragments in accordance with the tightness of DNA-protein bonds in situ. The fractions obtained were analysed by agarose gel electrophoresis and dot-hybridization technique with the use of various DNA probes. The results received are as follows: a) a DNA fragment size is not a factor determining the chromatographic position, the latter is probably stipulated by DNA-protein interactions; b) an analysis of cells synchronized at the G1/S border shows that the distribution of specific DNA sequences, such as actin, histone, hsp 70, and c-Ha-ras genes as well as reiterated DNA sequences, does not coincide with that of total genomic DNA; the nuclear matrix-attached fragments of those sequences are enriched to various extents. By nick-translation labeling in situ, DNase I-sensitive and hypersensitive regions were tentatively identified among subdomain chromatin fragments.     

Analytical biochemistry of DNA--protein assemblies from crude cell extracts

Purification of specific DNA-protein complexes is a challenging task, as the involved interactions can be both electrostatic/H-bond and hydrophobic. The chromatographic stringency needed to obtain reasonable purifications uses salts and detergents. However, these components elicit the removal of proteins unspecifically bound to the chromatographic support itself, thus contaminating the purification products. In this work, a photocleavable linker connected the target oligonucleotidic sequence to the chromatographic beads so as to allow the irradiation-based release of the purified DNA-protein complexes off the beads. Our bioanalytical conditions were validated by purifying the tetracycline repressor protein onto a specific oligonucleotide. The purification factor was unprecedented, with a single contaminant. The robustness of our method was challenged by applying it to the purification of multiprotein assemblies forming onto DNA damage-mimicking oligonucleotides. The purified components were identified as well-known DNA repair proteins, and were shown to retain their enzymatic activities, as seen by monitoring DNA ligation products. Remarkably, kinase activities, also monitored, were found to be distinct on the beads and on the purified DNA-protein complexes, showing the benefits to uncouple the DNA-protein assemblies from the beads for a proper understanding of biochemical regulatory mechanisms involved in the DNA-protein assemblies.