Protein HU binds specifically to kinked DNA

We have purified the main four-way junction DNA-binding protein of Escherichia coli, and have found It to be the well-known HU protein. HU protein recognizes with high-affinity one of the angles present in the junction, a molecule with the shape of an X. Other DNA structures characterized by sharp bends or kinks, like bulged duplex DNAs containing unpaired bases, are also bound. HU protein appears to inhibit cruciform extrusion from supercoiled inverted repeat (palindromic) DNA, either by constraining supercoiling or by trapping a metastable interconversion intermediate. All these properties are analogous to the properties of the mammalian chromatin protein HMG1. We suggest that HU is a prokaryotic HMG1-like protein rather than a histone-like protein.     

Repair of abasic sites in DNA

Repair of both normal and reduced AP sites is activated by AP endonuclease, which recognizes and cleaves a phosphodiester bond 5' to the AP site. For a short period of time an incised AP site is occupied by poly(ADP-ribose) polymerase and then DNA polymerase beta adds one nucleotide into the repair gap and simultaneously removes the 5'-sugar phosphate. Finally, the DNA ligase III/XRCC1 complex accomplishes repair by sealing disrupted DNA ends. However, long-patch BER pathway, which is involved in the removal of reduced abasic sites, requires further DNA synthesis resulting in strand displacement and the generation of a damage-containing flap that is later removed by the flap endonuclease. Strand-displacement DNA synthesis is accomplished by DNA polymerase delta/epsilon and DNA ligase I restores DNA integrity. DNA synthesis by DNA polymerase delta/epsilon is dependent on proliferating cell nuclear antigen, which also stimulates the DNA ligase I and flap endonuclease. These repair events are supported by multiple protein-protein interactions.     

Characterization of a novel protein that specifically binds to DNA modified by N-acetoxy-acetylaminofluorene and cis-diamminedichloroplatinum

Proteins recognizing DNA damaged by the chemical carcinogen N-acetoxy-acetylaminofluorene (AAAF) were analyzed in nuclear extracts from rat tissues, using a 36 bp oligonucleotide as a substrate and electrophoretic mobility shift and Southwestern blot assays. One major damage-recognizing protein was detected, whose amount was estimated as at least 10(5) copies per cell. Levels of this protein were similar in extracts from brain, kidney and liver, but much lower in extracts from testis. The affinity of the detected protein for DNA damaged by AAAF was about 70-fold higher than for undamaged DNA. DNA damaged by cis-diamminedichloroplatinum (cis-DDP), benzo(a)pyrene diolepoxide (BPDE) or UV-radiation also bound this protein with an increased affinity, the former more strongly and the latter two more weakly as compared to AAAF-damaged DNA. The detected AAAF/DDP-damaged-DNA-binding (AAAF/DDP-DDB) protein had a molecular mass of about 25 kDa and was distinct from histone H1 or HMGB proteins, which are known to have a high affinity for cis-DDP-damaged DNA. The level of this damage-recognizing protein was not affected in rats treated with the carcinogen 2-acetylaminofluorene. The activity of an AAAF/DDP-DDB protein could also be detected in extracts from mouse liver cells but not from the Hep2G human hepatocellular carcinoma.     

Nucleoside transport in human and sheep erythrocytes. Evidence that nitrobenzylthioinosine binds specifically to functional nucleoside-transport sites.

Nitrobenzyl[35S]thioinosine binding and nitro[3H]benzylthioinosine binding to nucleoside-permeable and nucleoside-impermeable sheep erythrocyte membranes was investigated, and compared with that found for human erythrocytes. High-affinity nitrobenzylthioinosine-binding sites (apparent KD congruent to 1 nM) were present on human and nucleoside-permeable but not nucleoside-impermeable sheep erythrocyte membranes (8400 and 18 sites/cell for human and sheep nucleoside-permeable sheep erythrocytes was displaced by nitrobenzylthioguanosine and dipyridamole. Uridine, inosine and adenosine inhibited binding. The smaller number of nitrobenzylthioinosine sites on nucleoside-permeable cells compared with human erythrocytes corresponded to a considerably lower Vmax. for uridine influx in these cells (0.53 X 10(-20) mol/cell per s at 25 degrees C compared with 254 X 10(-20) mol/cell per s). It is suggested that high-affinity nitrobenzylthioinosine binding represents a specific interaction with functional nucleoside-transport sites. The uridine-translocation capacity for each transport site at 25 degrees C is 180 molecules/site per s for both nucleoside-permeable sheep cells and human erythrocytes (assuming a 1:1 interaction between nitrobenzylthioinosine and the nucleoside-transport system).     

Cleavage of abasic sites in DNA by intercalator-amines

Anthraquinone and naphthalene diimide intercalators with amine-containing side chains cleave plasmid DNA at abasic sites (apurinic or apyrimidinic (AP) sites). The intercalator-amine is substantially more effective than the amine itself; many intercalators with diamine side chains cleave most of the abasic sites at micromolar concentration (30 min at 37 degrees C). Intercalators with two amino moieties in the side chain are more efficient than those with one, arguing for a role for each of two amines in the cleavage mechanism. Side chains ending in tertiary amines are somewhat more effective than those ending in primary amines, indicating that imine formation is not required for cleavage at the abasic site. We also report a systematic study of abasic site cleavage by polyamines, including piperidine, spermine, spermidine and 12 other di-, tri- and tetra-amines. For polyamines as well as intercalator-amines, examples with three carbon atoms between neighboring nitrogens atoms cleave most efficiently. This may reflect a particularly favorable geometry for proton abstraction for these species. The effect of nitrogen-nitrogen spacing on the pKa values of the nitrogens may contribute as well. Overall, cleavage of plasmid DNA at adventitious abasic sites by intercalator-amines bearing two nitrogens in a single side chain occurs readily.     

Photochemically induced RNA and DNA abasic sites

Two phosphoramidite building blocks were synthesized that can easily be deprotected by UV light to reveal natural abasic sites in oligoribonucleotides as well as in oligodeoxyribonucleotides. Another building block which releases a 2'-O-methylated abasic site upon UV radiation is also described.     

Design of molecules that specifically recognize and cleave apurinic sites in DNA

We have prepared a series of a tailor-made molecules that recognize and cleave DNA at apurinic sites in vitro. These molecules incorporate in their structure different units designed for specific function: an intercalator for DNA binding, an nucleic base for abasic site recognition and a linking chain of variable length and nature (including amino and/or amido functions). The cleavage efficiency of the molecules can be modulated by varying successively the nature of the intercalating agent, the nucleic base and the chain. All molecules bind to native calf thymus DNA with binding constants ranging from 10⁴ to 10⁶ M^?1. Their cleavage activity was determined on plasmid DNA (pBR 322) containing 1.8 AP-sites per DNA-molecule. The minimum requirements for cleavage are the presence of the three units, the intercalator, the nucleic base and at least one amino function in the chain. The most efficient molecules cleaved plasmid DNA at nanomolar concentrations. Enzymatic experiments on the termini generated after cleavage of AP-DNA suggest a strand break induced by a β-elimination reaction. In order to get insight into the mode of action (efficiency, selectivity, interaction), we have used synthetic oligonucleotides containing either a true abasic site at a determined position to analyse the cleavage parameters of the synthetic molecules by HPLC or a chemically stable along (tetrahydrofuran) of the abasic site for high field ¹H NMR spectrometry and footprinting experiments. All results are consistent with a β-elimination mechanism in which each constituent of the molecule exerts a specific function as indicated in the scheme: DNA targeting, abasic site nucleases and can be used advantageously as substitutes for the natural enzyme for in vitro cleavage of AP-sites containing DNA.     

Proteomic approach to identification of proteins reactive for abasic sites in DNA

Apurinic/apyrimidinic (AP) sites, a prominent type of DNA damage, are repaired through the base excision repair mechanism in both prokaryotes and eukaryotes and may interfere with many other cellular processes. A full repertoire of AP site-binding proteins in cells is presently unknown, preventing reliable assessment of harm inflicted by these ubiquitous lesions and of their involvement in the flux of DNA metabolism. We present a proteomics-based strategy for assembling at least a partial catalogue of proteins capable of binding AP sites in DNA. The general scheme relies on the sensitivity of many AP site-bound protein species to NaBH(4) cross-linking. An affinity-tagged substrate is used to facilitate isolation of the cross-linked species, which are then separated and analyzed by mass spectrometry methods. We report identification of seven proteins from Escherichia coli (AroF, DnaK, MutM, PolA, TnaA, TufA, and UvrA) and two proteins from bakers' yeast (ARC1 and Ygl245wp) reactive for AP sites in this system.     

Origin of endogenous DNA abasic sites in Saccharomyces cerevisiae

Abasic (AP) sites are among the most frequent endogenous lesions in DNA and present a strong block to replication. In Saccharomyces cerevisiae, an apn1 apn2 rad1 triple mutant is inviable because of its incapacity to repair AP sites and related 3'-blocked single-strand breaks (M. Guillet and S. Boiteux, EMBO J. 21:2833, 2002). Here, we investigated the origin of endogenous AP sites in yeast. Our results show that the deletion of the UNG1 gene encoding the uracil DNA glycosylase suppresses the lethality of the apn1 apn2 rad1 mutant. In contrast, inactivation of the MAG1, OGG1, or NTG1 and NTG2 genes encoding DNA glycosylases involved in the repair of alkylation or oxidation damages does not suppress lethality. Although viable, the apn1 apn2 rad1 ung1 mutant presents growth delay due to a G(2)/M checkpoint. These results point to uracil as a critical source of the formation of endogenous AP sites in DNA. Uracil can arise in DNA by cytosine deamination or by the incorporation of dUMP during replication. Here, we show that the overexpression of the DUT1 gene encoding the dUTP pyrophosphatase (Dut1) suppresses the lethality of the apn1 apn2 rad1 mutant. Therefore, this result points to the dUTP pool as an important source of the formation of endogenous AP sites in eukaryotes.     

The impact of abasic sites on DNA flexibility

We use internal coordinate molecular mechanics calculations to study the impact of abasic sites on the conformation and the mechanics of the DNA double helix. Abasic sites, which are common mutagenic lesions, are shown to locally modify both the groove geometry and the curvature of DNA in a sequence dependent manner. By controlled twisting and bending, it is also shown that these lesions modify the deformability of the duplex, generally increasing its flexibility, but again to an extent which depends on the nature of the abasic site and on the surrounding base sequence. Both the conformational and mechanical influence of this type of DNA damage may be significant for recognition and repair mechanisms.     

Covalent binding of the natural antimicrobial peptide indolicidin to DNA abasic sites

Indolicidin is a host defense tridecapeptide that inhibits the catalytic activity of HIV-1 integrase in vitro. Here we have elucidated its mechanism of integrase inhibition. Using crosslinking and mass spectrometric footprinting approaches, we found that indolicidin interferes with formation of the catalytic integrase-DNA complex by directly binding DNA. Further characterization revealed that the peptide forms covalent links with abasic sites. Indolicidin crosslinks single- or double-stranded DNAs and various positions of the viral cDNA with comparable efficiency. Using truncated and chemically modified peptides, we show that abasic site crosslinking is independent of the PWWP motif but involves the indolicidin unique lysine residue and the N- and C- terminal NH₂ groups. Because indolicidin can also inhibit topoisomerase I, we believe that multiple actions at the level of DNA might be a common property of antimicrobial peptides.     

The histone-like protein HU binds specifically to DNA recombination and repair intermediates

The heterodimeric HU protein associated with the Escherichia coli nucleoid shares some properties with histones and HMG proteins. HU binds DNA junctions and DNA containing a nick much more avidly than double-stranded (ds-) DNA. Cells lacking HU are extremely sensitive to gamma irradiation and we wondered how HU could play a role in maintaining the integrity of the bacterial chromosome. We show that HU binds with high affinity to DNA repair and recombination intermediates, including DNA invasions, DNA overhangs and DNA forks. The DNA structural motif that HU specifically recognizes in all these structures consists of a ds-DNA module joined to a second module containing either ds- or single-stranded (ss-) DNA. The two modules rotate freely relative to one another. Binding specificity results from the simultaneous interaction of HU with these two modules: HU arms bind the ds-DNA module whereas the HU body contacts the 'variable' module containing either ds- or ss-DNA. Both structural motifs are recognized by HU at least 1000-fold more avidly than duplex DNA.     

Two glycosylase/abasic lyases from Neisseria mucosa that initiate DNA repair at sites of UV-induced photoproducts

Diverse organisms ranging from Escherichia coli to humans contain a variety of DNA repair proteins that function in the removal of damage caused by shortwave UV light. This study reports the identification, purification, and biochemical characterization of two DNA glycosylases with associated abasic lyase activity from Neisseria mucosa. These enzymes, pyrimidine dimer glycosylase I and II (Nmu-pdg I and Nmu-pdg II), were purified 30,000- and 10,000-fold, respectively. SDS-polyacrylamide gel electrophoresis analysis indicated that Nmu-pdg I is approximately 30 kDa, whereas Nmu-pdg II is approximately 19 kDa. The N-terminal amino acid sequence of Nmu-pdg II exhibits 64 and 66% identity with E. coli and Hemophilus parainfluenzae endonuclease III, respectively. Both Nmu-pdg I and Nmu-pdg II were found to have broad substrate specificities, as evidenced by their ability to incise DNA containing many types of UV and some types of oxidative damage. Consistent with other glycosylase/abasic lyases, the existence of a covalent enzyme-DNA complex could be demonstrated for both Nmu-pdg I and II when reactions were carried out in the presence of sodium borohydride. These data indicate the involvement of an amino group in the catalytic reaction mechanism of both enzymes.     

Moloney murine leukemia virus integration protein produced in yeast binds specifically to viral att sites.

The integration protein (IN) of Moloney murine leukemia virus (MuLV), purified after being produced in yeast cells, has been analyzed for its ability to bind its putative viral substrates, the att sites. An electrophoretic mobility shift assay revealed that the Moloney MuLV IN protein binds synthetic oligonucleotides containing att sequences, with specificity towards its cognate (MuLV) sequences. The terminal 13 base pairs, which are identical at both ends of viral DNA, are sufficient for binding if present at the ends of oligonucleotide duplexes in the same orientation as in linear viral DNA. However, only weak binding was observed when the same sequences were positioned within a substrate in a manner simulating att junctions in circular viral DNA with two long terminal repeats. Binding to att sites in oligonucleotides simulating linear viral DNA was dependent on the presence of the highly conserved CA residues preceding the site for 3' processing (an IN-dependent reaction that removes two nucleotides from the 3' ends of linear viral DNA); mutation of CA to TG abolished binding, and a CA to TA change reduced affinity by at least 20-fold. Removal of either the terminal two base pairs from both ends of the oligonucleotide duplex or the terminal two nucleotides from the 3' ends of each strand did not affect binding. The removal of three 3' terminal nucleotides, however, abolished binding, suggesting an essential role for the A residue immediately upstream of the 3' processing site in the binding reaction. These results help define the sequence requirements for att site recognition by IN, explain the conservation of the subterminal CA dinucleotide, and provide a simple assay for sequence-specific IN activity.     

The chemical stability of abasic RNA compared to abasic DNA

We describe the synthesis of an abasic RNA phosphoramidite carrying a photocleavable 1-(2-nitrophenyl)ethyl (NPE) group at the anomeric center and a triisopropylsilyloxymethyl (TOM) group as 2′-O-protecting group together with the analogous DNA and the 2′-OMe RNA abasic building blocks. These units were incorporated into RNA-, 2′-OMe-RNA- and DNA for the purpose of studying their chemical stabilities towards backbone cleavage in a comparative way. Stability measurements were performed under basic conditions (0.1 M NaOH) and in the presence of aniline (pH 4.6) at 37°C. The kinetics and mechanisms of strand cleavage were followed by High pressure liquid chromotography and ESI-MS. Under basic conditions, strand cleavage at abasic RNA sites can occur via β,δ-elimination and 2′,3′-cyclophosphate formation. We found that β,δ-elimination was 154-fold slower compared to the same mechanism in abasic DNA. Overall strand cleavage of abasic RNA (including cyclophosphate formation) was still 16.8 times slower compared to abasic DNA. In the presence of aniline at pH 4.6, where only β,δ-elimination contributes to strand cleavage, a 15-fold reduced cleavage rate at the RNA abasic site was observed. Thus abasic RNA is significantly more stable than abasic DNA. The higher stability of abasic RNA is discussed in the context of its potential biological role.     

A versatile new tool to quantify abasic sites in DNA and inhibit base excision repair

A number of endogenous and exogenous agents, and cellular processes create abasic (AP) sites in DNA. If unrepaired, AP sites cause mutations, strand breaks and cell death. Aldehyde-reactive agent methoxyamine reacts with AP sites and blocks their repair. Another alkoxyamine, ARP, tags AP sites with a biotin and is used to quantify these sites. We have combined both these abilities into one alkoxyamine, AA3, which reacts with AP sites with a better pH profile and reactivity than ARP. Additionally, AA3 contains an alkyne functionality for bioorthogonal click chemistry that can be used to link a wide variety of biochemical tags to AP sites. We used click chemistry to tag AP sites with biotin and a fluorescent molecule without the use of proteins or enzymes. AA3 has a better reactivity profile than ARP and gives much higher product yields at physiological pH than ARP. It is simpler to use than ARP and its use results in lower background and greater sensitivity for AP site detection. We also show that AA3 inhibits the first enzyme in the repair of abasic sites, APE-1, to about the same extent as methoxyamine. Furthermore, AA3 enhances the ability of an alkylating agent, methylmethane sulfonate, to kill human cells and is more effective in such combination chemotherapy than methoxyamine.     

Heat shock protein 70 binds to human apurinic/apyrimidinic endonuclease and stimulates endonuclease activity at abasic sites

The interaction of human heat shock protein 70 (HSP70) with human apurinic/apyrimidinic endonuclease (HAP1) was demonstrated by coimmunoprecipitation. A combination of HSP70 and HAP1 also caused a shift in the electrophoretic mobility of a DNA fragment containing an apurinic/apyrimidinic site. The functional consequence of the HSP70/HAP1 interaction was a 10-100-fold enhancement of endonuclease activity at abasic sites. The physical and functional interaction between HSP70 and HAP1 did not require the addition of ATP. The association of HSP70 and a key base excision repair enzyme suggests a role for heat shock proteins in promoting base excision repair. These findings provide a possible mechanism by which HSP70 protects cells against oxidative stress.     

The human GINS complex binds to and specifically stimulates human DNA polymerase alpha-primase

The eukaryotic GINS complex has an essential role in the initiation and elongation phases of genome duplication. It is composed of four paralogous subunits--Sld5, Psf1, Psf2 and Psf3--which are ubiquitous and evolutionarily conserved in eukaryotic organisms. Here, we report the biochemical characterization of the human GINS complex (hGINS). The four hGINS subunits were coexpressed in Escherichia coli in a highly soluble form and purified as a complex. hGINS was shown to interact directly with the heterodimeric human DNA primase, by using either surface plasmon resonance measurements or by immunoprecipitation experiments carried out with anti-hGINS antibodies. The DNA polymerase alpha-primase synthetic activity was specifically stimulated by hGINS on various primed DNA templates. The significance of these findings is discussed in view of the molecular dynamics at the human replication fork.