Histone-DNA interactions within chromatin. Isolation of histones from DNA-histone adducts induced in nuclei by UV light.

We have developed a method by which to isolate histones that have been crosslinked to DNA following irradiation of calf thymus nuclei by UV light. The procedure involves separation of protein-DNA adducts from uncrosslinked protein by Sepharose 4B chromatography under dissociating conditions. Histones which are crosslinked to DNA are released by chemical hydrolysis of the DNA and identified by SDS gel electrophoresis. The results indicate that, of the histones, H1 and H3 become crosslinked to the DNA most readily under our irradiation conditions.     

BLM and the FANC proteins collaborate in a common pathway in response to stalled replication forks

Fanconi anaemia (FA) and Bloom syndrome (BS) are autosomal recessive diseases characterised by chromosome fragility and cancer proneness. Here, we report that BLM and the FA pathway are activated in response to both crosslinked DNA and replication fork stall. We provide evidence that BLM and FANCD2 colocalise and co-immunoprecipitate following treatment with either DNA crosslinkers or agents inducing replication arrest. We also find that the FA core complex is necessary for BLM phosphorylation and assembly in nuclear foci in response to crosslinked DNA. Moreover, we show that knock-down of the MRE11 complex, whose function is also under the control of the FA core complex, enhances cellular and chromosomal sensitivity to DNA interstrand crosslinks in BS cells. These findings suggest the existence of a functional link between BLM and the FA pathway and that BLM and the MRE11 complex are in two separated branches of a pathway resulting in S-phase checkpoint activation, chromosome integrity and cell survival in response to crosslinked DNA.     

Analysis of EDTA-chelatable proteins from DNA-protein crosslinks induced by a carcinogenic chromium(VI) in cultured intact human cells

DNA-protein crosslinks (DPCs) were induced in intact human leukemic T-lymphocyte MOLT4 cells or isolated nuclei by treatment with potassium chromate, chromium(III) chloride hexahydrate or x-rays. The proteins complexed to DNA were analyzed by two-dimensional SDS-polyacrylamide gel electrophoresis (PAGE). A group of identical non-histone proteins was crosslinked to DNA by any of the three treatments, except that a 51 kDa basic protein was additionally complexed to DNA when either potassium chromate or chromium(III) chloride hexahydrate was the crosslinking agent. Treatment of chromate-induced DNA-protein crosslinks with EDTA or thiourea followed by ultracentifugation dissociated the major proteins from the complex indicating that these proteins were crosslinked to DNA by direct participation of a EDTA-chelatable form of chromium such as Cr(III) through sulfur containing amino acid residues. The 51 kDa protein was not seen in the post-EDTA pellet but was present in the post-thiourea pellet, indicating that it was also crosslinked to DNA by Cr(III) through non-sulfur-containing amino acids. Digestion of x-rays-induced DPCs by DNase I also revealed this protein on two-dimensional gels indicating that the same protein was also crosslinked by oxidative mechanisms. The involvement of oxidative mechanisms in the crosslinking process was indicated as the majority of the proteins in chromate-induced DPCs were resistant to EDTA and thiourea treatment, and were found to crosslink to DNA when x-rays were used as the crosslinking agent. These results suggest that the chromate-induced DPCs are formed by the generation of reactive oxygen species during the intracellular chromate reduction as well as by the biologically generated Cr(III). About 19% of DNA-protein crosslinks actually involve Cr(III) crosslinking DNA to proteins, about 14% involve Cr(III) crosslinking DNA to proteins through non-sulfhydryl containing moieties and about 5% involve Cr(III) crosslinking DNA to sulfhydryl groups on proteins. The remaining 81% of DNA-protein crosslinks appear to be oxidatively crosslinked out of which about 45% appear to be through sulfhydryl groups and another 36% appear to be through non-sulfhydryl groups.     

Ddc1 checkpoint protein and DNA polymerase ɛ interact with nick-containing DNA repair intermediate in cell free extracts of Saccharomyces cerevisiae

To characterize proteins that interact with base excision/single-strand interruption repair DNA intermediates in cell free extracts of Saccharomyces cerevisiae, we used a combination of photoaffinity labeling with the protein identification by MALDI-TOF-MS peptide mapping. Photoreactive analogue of dCTP, namely exo-N-[4-(4-azido-2,3,5,6,-tetrafluorobenzylidenehydrazinocarbonyl)-butylcarbamoyl]-2'-deoxycytidine-5'-triphosphate, and [(32)P]-labeled DNA duplex containing one nucleotide gap were used to generate nick-containing DNA with a photoreactive dCMP residue at the 3'-margin of the nick. This photoreactive DNA derivative was incubated with the yeast cell extract and after UV irradiation a number of proteins were labeled. Two of the crosslinked proteins were identified as the catalytic subunit of DNA polymerase ? and Ddc1 checkpoint protein. Labeling of DNA polymerase ? catalytic subunit with the nick-containing DNA repair intermediate indicates that the DNA polymerase is involved in the DNA repair synthesis in yeast, at least at DNA single-strand interruptions. Crosslinking of Ddc1 to DNA nicks took place independently of the other components of checkpoint clamp, Mec3 and Rad17, suggesting that the protein alone is able to recognize DNA single-strand breaks. Indeed, purified GST-tagged Ddc1 protein was efficiently crosslinked to nick-containing DNA. The interaction of Ddc1 with DNA nicks may provide a link between the DNA damage checkpoint and DNA base excision/single-strand breaks repair pathways in yeast. In addition, we found that absence of Ddc1 protein greatly influences the overall pattern of other proteins crosslinked to DNA nick. We suggested that this last effect of Ddc1 is at least partially due to its capacity to prevent proteolytic degradation of the DNA-protein adducts.     

Replication of bacteriophage M13. XII. In vivo cross-linking of a phage-specific DNA binding protein to the single-stranded DNA of bacteriophage M13 by ultraviolet irradiation.

Ultraviolet irradiation of bacteriophage M13-infected Escherichia coli induces the formation of a covalent crosslink between progeny single-stranded DNA and the M13 DNA binding protein, the product of gene 5. The crosslinked complex is readily isolated from detergent-treated lysates by sucrose-gradient velocity sedimentation and CsCl equilibrium sedimentation in the presence of detergent. The crosslinked complex produced with optimal levels of irradiation sediments 1.06 times faster than uncomplexed M13 single-stranded DNA, has a buoyant density of approximately 1.62 to 1.64 g/cm³ and a protein to DNA mass ratio of 2 mg protein per mg DNA. Cleavage of the crosslinked complex with cyanogen bromide or trypsin yields products similar to those produced by cleavage of purified M13 gene 5 protein. The crosslink is located close to the carboxyl terminus of the protein.     

Crosslinking of proteins to DNA in human nuclei using a 60 femtosecond 266 nm laser.

We developed appropriate conditions to use a laser with 60 femtosecond pulses, a frequency of 1 KHz and a wavelength of 266 nm to efficiently crosslink proteins to DNA in human nuclei for the purpose of using immunoprecipitation to study the binding of specific proteins to specific sequences of DNA under native conditions. Irradiation of nuclei for 30 min with 1-3 GW/cm(2)pulses crosslinked 10-12% of total protein to DNA. The efficiency of crosslinking was dose and protein specific. Histones H1 and H3 were crosslinked by 15 min of irradiation with 20-25% efficiency, at least 10 times more strongly than the other histones, consistent with experiments using conventional UV light. Irradiation for 15 min did not damage proteins, as assayed by SDS-PAGE of Ku-70 and histones. Although the same level of irradiation did not cause double-strand breaks, it did make the DNA partially insensitive to Eco RI restriction enzyme, probably through formation of thymidine dimers. Immuno-analysis of crosslinked nucleoprotein showed that Ku crosslinking to nuclear DNA is detectable only in the presence of breaks in the DNA, and that nucleosomes are bound to a significant fraction of the telomeric repeat (TTAGGG) (n).     

Sequence preferences of DNA interstrand crosslinking agents: quantitation of interstrand crosslink locations in DNA duplex fragments containing multiple crosslinkable sites.

A general approach to the quantitative study of the sequence specificity of DNA interstrand crosslinking agents in synthetic duplex DNA fragments is described. In the first step, a DNA fragment previously treated with an interstrand crosslinking agent is subjected to denaturing PAGE. Not only does this distinguish crosslinked from native or monoadducted DNA, it is shown herein that isomeric crosslinked DNAs differing in position of the crosslink can in some cases be separated. In the second stage, the now fractionated crosslinked DNAs isolated from denaturing PAGE are subjected to fragmentation using iron(II)/EDTA. For those fractions which are structurally homogeneous, analysis of the resulting fragment distribution has previously been shown to reveal the crosslink position at nucleotide resolution. It is shown herein that in fractions which are structurally heterogeneous due to differences in position of crosslink, this analysis quantifies the relative extent of crosslinking at distinct sites. Using this method it is shown that reductively activated mitomycin C crosslinks the duplex sequences 5'-GCGC and 5'-TCGA with 3 +/- 1:1 relative efficiency.     

Determination of the DNA-interacting region of the archaebacterial chromosomal protein MC1. Photocrosslinks with 5-bromouracil-substituted DNA.

Protein MC1 is the major chromosomal protein in methanosarcinaceae. Using photochemical crosslinking on 5-bromouracil-substituted DNA, we identified the region of the protein that interacts with it. This region is located in the C-terminal part of the polypeptide chain, and the crosslinked amino-acids are in the region 74-86. Tryptophan 74 is one of the amino-acids crosslinked to DNA.     

DNA strand specificity in promoter recognition by RNA polymerase.

DNA strand and enzyme subunit specificities involved in the interaction between E. coli RNA polymerase and T7 DNA were studied by photo-crosslinking techniques. In non-specific enzyme-DNA complexes, subunits, sigma, beta, and beta' were crosslinked to both strands of the DNA. Under conditions leading to specific enzyme-promoter complexes, however, only sigma and beta subunits were crosslinked. The sigma subunit was crosslinked preferentially to the non-sense strand at promoter sites. No such strand specificity was observed for the beta subunit. These results provide insight into the molecular mechanism of promoter recognition and indicate that the interaction between RNA polymerase and DNA template is different at promoters and at non-specific sites.     

Crosslinking of nuclear proteins to DNA by cis-diamminedichloroplatinum in intact cells. Involvement of nuclear matrix proteins.

In order to detect the nuclear matrix proteins involved in DNA binding, avoiding possible artifacts derived from the disruption of nuclei, proteins were crosslinked to DNA by the action of cis-diamminedichloroplatinum on intact chicken liver cells and analyzed by two-dimensional gel electrophoresis. At least eleven species of crosslinked proteins were found to derive from the nuclear matrix prepared from the same cell type, and five of these were found also among the proteins crosslinked to DNA in intact liver cells from ox and pig. This subset of common proteins, conserved in different animal species, is likely to have a fundamental role for the anchorage of DNA to the nuclear matrix.     

Stabilization of R loop structures by photochemical crosslinking with 4,5',8-trimethylpsoralen: application to gene enrichment and molecular cloning

R loops formed between nucleosomal DNA and tRNA can be photochemically crosslinked with 4,5′,8-trimethylpsoralen directly in the R loop formation buffer. When biotin is coupled to the tRNA 3′-terminus via a diaminohexan linker and the modified tRNA employed for R loop hybridization the crosslinked R loops can be efficiently purified by affinity chromatography on avidin-glass columns. Following tRNA hydrolysis the partially crosslinked double stranded DNA, highly enriched for tRNA genes can be cloned in E. coli χ¹⁷⁷⁶.     

Intermediates in extrachromosomal homologous recombination in Xenopus laevis oocytes: characterization by electron microscopy.

Several molecular mechanisms have been proposed to account for nonconservative homologous recombination. This type of recombination is particularly efficient in Xenopus oocytes when appropriate DNA substrates are injected. To distinguish between possible models, we have investigated recombination intermediates from oocytes by direct observation in the electron microscope. Partially recombined DNA was crosslinked with a psoralen derivative after incubation in oocytes to limit the branch migration that might occur during recovery procedures and alter the structures that were initially present. Branched structures, which we interpret as intermediates, represented approximately 10% of the DNA recovered and were readily analyzed. We did not observe any structures with internal loops predicted by invasion mechanisms. The majority of intermediates had one or two single-stranded branches on product-sized molecules, as predicted for incomplete junctions in the resection-annealing mechanism. Detailed length measurements confirmed the expectations of that model. When recovered DNA was not crosslinked, or when annealed junctions were prepared in vitro, we saw branched structures that indicated the occurrence of extensive branch migration. Comparison with the crosslinked sample confirmed the effectiveness of the crosslinking in preserving structures created in the oocytes. Our results strongly support a resection-annealing mechanism of recombination in oocytes.     

Synthesis and characterization of DNA duplexes containing an N3T-ethyl-N3T interstrand crosslink in opposite orientations

DNA duplexes containing an ethyl interstrand crosslink that bridges the N3 atoms of thymidines on the opposite strands have been synthesized using an approach that combines conventional solid phase oligonucleotide synthesis and the selective removal of protecting groups of a crosslinked thymidine dimer. This approach allows for the assembly of a crosslinked duplex directly on the solid support. Duplexes that contain a N3T-ethyl-N3T interstrand crosslink in a staggered orientation at either a -TA- or -AT-step in a duplex have been prepared. When placed in an -AT- step of a duplex the effect was stabilizing relative to the non-crosslinked control duplex (deltaTm= +24 degrees C) and this crosslinked duplex was found to efficiently form multimers in the presence of T4 ligase. In the case of the -TA- crosslinked duplex the stabilizing effect was less pronounced (deltaT.= +6 degrees C) and likewise did not undergo self ligation under identical conditions. Molecular modeling studies suggested that the -AT- containing lesion had little deviation in structure relative to the non-crosslinked duplex DNA control, whereas the -TA- crosslinked duplex exhibited significant buckling of the base pairs flanking the lesion.     

Repair of DNA interstrand crosslinks may take place at the nuclear matrix

Host cell reactivation assay using Trioxsalen-crosslinked plasmid pEGFP-N1 showed that human cells were able to repair Trioxsalen interstrand crosslinks (ICL). To study the mechanism of this repair pathway, cells were transfected with the plasmids pEGFP-1, which did not contain the promoter of the egfp gene, and with pEGFP-G-, which did not contain the egfp gene. Neither of these plasmids alone was able to express the green fluorescent protein. After cotransfection with the two plasmids, 1%-2% of the cells developed fluorescent signal, which showed that recombination events had taken place in these cells to create DNA constructs containing the promoter and the gene properly aligned. When one or both of the plasmids were crosslinked with Trioxsalen, the recombination rate increased several fold. To identify the nuclear compartment where recombination takes place, cells were transfected with crosslinked pEGFP-N1 and the amount of plasmid DNA in the different nuclear fractions was determined. The results showed that Trioxsalen crosslinking increased the percentage of matrix attached plasmid DNA in a dose-dependent way. Immunoblotting experiments showed that after transfection with Trioxsalen crosslinked plasmids the homologous recombination protein Rad51 also associated with the nuclear matrix fraction. These studies provide a model system for investigating the precise molecular mechanisms that appear to couple repair of DNA ICL with nuclear matrix attachment.     

A method for the isolation of covalent DNA-protein crosslinks suitable for proteomics analysis

The covalent crosslinking of protein to DNA is a form of DNA damage induced by a number of commonly encountered agents, including metals, aldehydes, and radiation as well as chemotherapeutic drugs. DNA-protein crosslinks (DPCs) are potentially bulky and helix distorting and have the potential to block the progression of translocating protein complexes. To fully understand the induction and repair of these lesions, it will be important to identify the crosslinked proteins involved. To take advantage of dramatic improvements in instrument sensitivity that have facilitated the identification of proteins by proteomic approaches, improved methods are required for isolation of DPCs. This article describes a novel method for the isolation of DPCs from mammalian cells that uses chaotropic agents to isolate genomic DNA and stringently remove noncrosslinked proteins followed by DNase I digestion to release covalently crosslinked proteins. This method generates high-quality protein samples in sufficient quantities for analysis by mass spectrometry. In addition, the article presents a modified form of this method that also makes use of chaotropic agents for promoting the adsorption of DNA (with crosslinked proteins) to silica fines, markedly reducing the DPC isolation time and cost. These approaches were applied to radiation- and camptothecin-induced DPCs.     

In vivo crosslinking of nuclear proteins to DNA by cis-diamminedichloroplatinum (II) in differentiating rat myoblasts

When cells are briefly exposed to cis-diamminedichloroplatinum (II) before lysis in high sodium dodecyl sulfate-urea solutions, the high molecular-weight nucleic acids pelleted by ultracentrifugation contain an increased level of bound proteins when compared to a similar fraction from untreated cells. Subsequent shearing of the pelleted DNA followed by treatment with DNase permits electrophoretic and immunoblot analysis of the crosslinked proteins. In the present study such experiments were carried out with reference to nuclear envelope pore complex proteins in the differentiating L8 rat skeletal muscle cells. The results show that (i) whereas the major lamin proteins crosslinked to DNA in both myoblast and myotubes, lamin B is crosslinked to a greater extent to DNA in myotubes; (ii) a 62-kDa lectin-binding glycoprotein is apparently situated differently with respect to DNA in myotube nuclei; and (iii) the crosslinking pattern of the nuclear matrix proteins to DNA is qualitatively similar in myoblast and myotubes. In addition, lamin C', a modified form of lamin C, not observed in intact nonmuscle cells previously [Glass et al. (1985) J. Biol. Chem. 260, 1895-1900], exists as a native component of the nuclear lamina in rat skeletal myotubes but not in myoblasts. These results point to significant structural alterations in the proteins of the nuclear lamina-pore complex during myogenesis.