Interaction of the UvrABC endonuclease with DNA containing a psoralen monoadduct or cross-link. Differential effects of superhelical density and comparison of preincision complexes

Cho Endonuclease Functions during DNA Interstrand Cross-Link Repair in Escherichia coli

DNA interstrand cross-links are complex lesions that covalently link both strands of the duplex DNA. Lesion removal is proposed to be initiated via the UvrABC nucleotide excision repair complex; however, less is known about the subsequent steps of this complex repair pathway. In this study, we characterized the contribution of nucleotide excision repair mutants to survival in the presence of psoralen-induced damage. Unexpectedly, we observed that the nucleotide excision repair mutants exhibit differential sensitivity to psoralen-induced damage, with uvrC mutants being less sensitive than either uvrA or uvrB We show that Cho, an alternative endonuclease, acts with UvrAB and is responsible for the reduced hypersensitivity of uvrC mutants. We find that Cho's contribution to survival correlates with the presence of DNA interstrand cross-links, rather than monoadducts, and operates at a step after, or independently from, the initial incision during the global repair of psoralen DNA adducts from the genome.

IMPORTANCE

DNA interstrand cross-links are complex lesions that covalently bind to both strands of the duplex DNA and whose mechanism of repair remains poorly understood. In this study, we show that Cho, an alternative endonuclease, acts with UvrAB and participates in the repair of DNA interstrand cross-links formed in the presence of photoactivated psoralens. Cho's contribution to survival correlates with the presence of DNA interstrand cross-links and operates at a step after, or independently from, the initial incision during the repair process.

Mammalian nucleotide excision repair proteins and interstrand crosslink repair

Although various schemes for interstrand crosslink (ICL) repair incorporate DNA recombination, replication, and double-strand break intermediate steps, action of the nucleotide excision repair (NER) system or some variation of it is a common feature of most models. In the bacterium Escherichia coli, the NER enzyme UvrABC can incise on either side of an ICL to unhook the crosslink, and can proceed via a subsequent recombination step. The relevance of NER to ICL repair in mammalian cells has been challenged. Of all NER mutants, it is clear that ERCC1 and XPF-defective cells show the most pronounced sensitivities to ICL-inducing agents, and defects in ICL repair. However, there is good evidence that cells defective in NER proteins including XPA and XPG are also more sensitive than normal to ICL-inducing agents. These results are summarized here, together with evidence for defective crosslink removal in NER-defective cells. Studies of incision at sites of ICL by cell extracts and purified proteins have been done, but these studies are not all consistent with one another and further research is required.

Differential survival of Escherichia coli uvrA, uvrB, and uvrC mutants to psoralen plus UV-A (PUVA): Evidence for uncoupled action of nucleotide excision repair to process DNA adducts

The nucleotide excision repair mechanism (NER) of Escherichia coli is responsible for the recognition and elimination of more than twenty different DNA lesions. Herein, we evaluated the in vivo role of NER in the repair of DNA adducts generated by psoralens (mono- or bi-functional) and UV-A light (PUVA) in E. coli. Cultures of wild-type E. coli K12 and mutants for uvrA, uvrB, uvrC or uvrAC genes were treated with PUVA and cell survival was determined. In parallel, kinetics of DNA repair was also evaluated by the comparison of DNA sedimentation profiles in all the strains after PUVA treatment. The uvrB mutant was more sensitive to PUVA treatment than all the other uvr mutant strains. Wild-type strain, and uvrA and uvrC mutants were able to repair PUVA-induced lesions, as seen by DNA sedimentation profiles, while the uvrB mutant was unable to repair the lesions. In addition, a quadruple fpg nth xth nfo mutant was unable to nick PUVA-treated DNA when the crude cell-free extract was used to perform plasmid nicking. These data suggest that DNA repair of PUVA-induced lesions may require base excision repair functions, despite proficient UvrABC activity. These results point to a specific role for UvrB protein in the repair of psoralen adducts, which appear to be independent of UvrA or UvrC proteins, as described for the classical UvrABC endonuclease mechanism.

Recognition and incision of Cr(III) ligand-conjugated DNA adducts by the nucleotide excision repair proteins UvrABC: importance of the Cr(III)-purine moiety in the enzymatic reaction

Hexavalent chromium [Cr(VI)] is an ubiquitous environmental contaminant and a well-known etiological agent of human lung cancer. Inside human cells, Cr(VI) is reduced to Cr(III), which can conjugate with amino acids, ascorbic acids, and glutathiones in the cytoplasm. Conjugated and unconjugated Cr(III) can enter the nucleus to form adducts with DNA and electrostatically interact with the phosphate group of DNA. It has been found that in both human and Escherichia coli systems, Cr(III) ligand-conjugated DNA ternary adducts are efficiently repaired by the nucleotide excision repair (NER) pathway. In contrast, DNA adducts formed by unconjugated Cr(III) with DNA are repaired significantly less efficiently by the NER system. These results raise the possibility that the NER system repairs Cr(III) ligand-conjugated DNA adducts and biadducts such as Cr(III)-guanine-phosphate adducts but not Cr(III)-phosphate adducts. To test this hypothesis, we determined the cutting efficiency and the mode of cutting of DNA modified with tannin-conjugated Cr(III) by the E. coli NER enzymes UvrABC. Tannin compounds, gallic acid (GA), and ethyl gallate (EGA) can reduce Cr(VI) to Cr(III) to form Cr(III)-GA 2 and Cr(III)-EGA 2, respectively, which can interact with a single guanine or adenine base but not with the DNA phosphate backbone. We found that UvrABC is able to incise Cr(III)-GA 2- and Cr(III)-EGA 2-modified plasmid DNA, and the amount of incision increased as a function of tannin concentration used for modifications. In contrast, UvrABC nuclease does not incise GA- and EGA-modified plasmid DNA. Mapping the sequence specificity of Cr(III)-GA 2- and Cr(III)-EGA 2-DNA formation in the human p53 gene sequence by UvrABC nuclease cutting, we found that the sequence specificity for both adducts is the same but is much more selective than Cr(III)-guanine-DNA adducts. Together, these results suggest that NER proteins from E. coli recognize the purine-Cr(III) adduct but not the Cr(III)-backbone phosphate complex.

RecA-mediated excision repair: a novel mechanism for repairing DNA lesions at sites of arrested DNA synthesis

In Escherichia coli, bulky DNA lesions are repaired primarily by nucleotide excision repair (NER). Unrepaired lesions encountered by DNA polymerase at the replication fork create a blockage which may be relieved through RecF-dependent recombination. We have designed an assay to monitor the different mechanisms through which a DNA polymerase blocked by a single AAF lesion may be rescued by homologous double-stranded DNA sequences. Monomodified single-stranded plasmids exhibit low survival in non-SOS induced E. coli cells; we show here that the presence of a homologous sequence enhances the survival of the damaged plasmid more than 10-fold in a RecA-dependent way. Remarkably, in an NER proficient strain, 80% of the surviving colonies result from the UvrA-dependent repair of the AAF lesion in a mechanism absolutely requiring RecA and RecF activity, while the remaining 20% of the surviving colonies result from homologous recombination mechanisms. These results uncover a novel mechanism - RecA-mediated excision repair - in which RecA-dependent pairing of the mono-modified single-stranded template with a complementary sequence allows its repair by the UvrABC excinuclease.

'Close-fitting sleeves': DNA damage recognition by the UvrABC nuclease system

DNA damage recognition represents a long-standing problem in the field of protein-DNA interactions. This article reviews our current knowledge of how damage recognition is achieved in bacterial nucleotide excision repair through the concerted action of the UvrA, UvrB, and UvrC proteins.

New insights on how nucleotide excision repair could remove DNA adducts induced by chemotherapeutic agents and psoralens plus UV-A (PUVA) in Escherichia coli cells

Chemotherapeutic agents such as mitomycin C or nitrogen mustards induce DNA inter-strand cross-links (ICL) and are highly toxic, thus constituting an useful tool to treat some human degenerative diseases, such as cancer. Additionally, psoralens plus UV-A (PUVA), which also induce ICL, find use in treatment of patients afflicted with psoriasis and vitiligo. The repair of DNA ICL generated by different molecules involves a number of multi-step DNA repair pathways. In bacteria, as in eukaryotic cells, if DNA ICL are not tolerated or repaired via nucleotide excision repair (NER), homologous recombination or translesion synthesis pathways, these DNA lesions may lead to mutations and cell death. Herein, we bring new insights to the role of Escherichia coli nucleotide excision repair genes uvrA, uvrB and uvrC in the repair of DNA damage induced by some chemotherapeutic agents and psoralen derivatives plus UV-A. These new observations point to a novel role for the UvrB protein, independent of its previously described role in the Uvr(A)BC complex, which could be specific for repair of monoadducts, intra-strand biadducts and/or ICL.

The isomerization of the UvrB-DNA preincision complex couples the UvrB and UvrC activities

In Escherichia coli nucleotide excision repair, the UvrB-DNA preincision complex plays a key role, linking adduct recognition to incision. We previously showed that the efficiency of the incision is inversely related to the stability of the preincision complex. We postulated that an isomerization reaction converts [UvrB-DNA], stable but incompetent for incision, into the [UvrB-DNA]' complex, unstable and competent for incision. Here, we identify two parameters, negative supercoiling and presence of a nick at the fifth phosphodiester bond 3' to the lesion, that accelerate the isomerization leading to an increasing incision efficiency. We also show that the [UvrB-DNA] complex is more resistant to a salt concentration increase than the [UvrB-DNA]' complex. Finally, we report that the [UvrB-DNA]' is recognized by UvrC. These data suggest that the isomerization reaction leads to an exposure of single-stranded DNA around the lesion. This newly exposed single-stranded DNA serves as a binding site and substrate for the UvrC endonuclease. We propose that the isomerization reaction is responsible for coupling UvrB and UvrC activities and that this reaction corresponds to the binding of ATP.

Triple helix-directed psoralen crosslinks are recognized by Uvr(A)BC excinuclease

Pyrimidine oligonucleotides bind to the major groove of an oligopyrimidine-oligopurine DNA sequence by triple helix formation. A 14-mer oligopyrimidine 3'-psoralen-conjugate (P) and a doubly modified 5'-acridine/3'-psoralen-oligonucleotide (PA) were photo-crosslinked to their target site. The crosslinked complexes were tested regarding their sensitivity to Uvr(A)BC excinuclease/DNA complex formation and excision, and compared to free psoralen crosslinked to the same site (M). An electrophoretic mobility-shift assay showed that the crosslinked triple-helix did not hamper formation of the (A)2B complex under conditions where the third strand was bound to its target. In vitro excision experiments performed on damaged DNA fragments containing crosslinked 5-methoxypsoralen (M-target) confirmed that the psoralen photoadduct was recognized by Uvr(A)BC and that excision occurred at the crosslinked site. The major cleavage reaction took place on the 5'-side of oligopurine strand. The excision was less efficient on the 5'-side of the pyrimidine strand. The 3'-side incision either on the purine or pyrimidine strand was even weaker. With optimal Uvr(A) concentrations, it was observed that the incision reaction on (P)- and (PA)-modified targets was clearly inhibited compared to the (M)-modified target, reflecting an effect of the oligonucleotide on the recognition/excision process. These results demonstrate that a triple helix is efficient in promoting inhibition of Uvr(A)BC excision nuclease activity. These results could account for divergent findings concerning the effects of triple helix-forming oligonucleotides on repair systems and open new perspectives to study DNA repair processes through the use of bi-substituted triple helix-forming oligonucleotides.

The topodynamics of incision of UV-irradiated covalently closed DNA by the Escherichia coli Uvr(A)BC endonuclease

The Escherichia coli Uvr(A)BC endonuclease (Uvr(A)BC) initiates nucleotide excision repair of a large variety of DNA damages. The damage recognition and incision steps by the Uvr(A)BC is a complex process utilizing an ATP-dependent DNA helix-tracking activity associated with the UvrA2B1 complex. The latter activity leads to the generation of highly positively supercoiled DNA in the presence of E. coli topoisomerase I in vitro. Such highly positively supercoiled DNA, containing ultraviolet irradiation-induced photoproducts (uvDNA), is resistant to the incision by Uvr(A)BC, whereas the negatively supercoiled and relaxed forms of the uvDNA are effectively incised. The E. coli gyrase can contribute to the above reaction by abolishing the accumulation of highly positively supercoiled uvDNA thereby restoring Uvr(A)BC-catalyzed incision. Eukaryotic (calf thymus) topoisomerase I is able to substitute for gyrase in restoring this Uvr(A)BC-mediated incision reaction. The inability of Uvr(A)BC to incise highly positively supercoiled uvDNA results from the failure of the formation of UvrAB-dependent obligatory intermediates associated with the DNA conformational change. In contrast to Uvr(A)BC, the Micrococcus luteus UV endonuclease efficiently incises uvDNA regardless of its topological state. The in vitro topodynamic system proposed in this study may provide a simple model for studying a topological aspect of nucleotide excision repair and its interaction with other DNA topology-related processes in E. coli.

The actual incision determines the efficiency of repair of cisplatin-damaged DNA by the Escherichia coli UvrABC endonuclease

The UvrABC endonuclease from Escherichia coli repairs a broad spectrum of DNA lesions with variable efficiencies. The effectiveness of repair is influenced by the nature of the lesion, the local DNA sequence, and/or the topology of the DNA. To get a better understanding of the aspects of this multistep repair reaction that determine the effectiveness of repair, we compared the incision efficiencies of linear DNA fragments containing either a site-specific cis-[Pt(NH3)2(d(GpG)-N7(1),-N7(2)]] or a cis- Pt(NH3)2[d(GpCpG)-N7(1),-N7(3)]] adduct. Overall the DNA with the cis-PtGG adduct was incised about 3.5 times more efficiently than the cis-Pt.GCG-containing DNA. The rate of UvrB-DNA preincision complex formation for both lesions was similar and high in relation to the incision. DNase I footprints, however, showed that the local structure of the two preincision complexes is different. An assay was developed to measure the binding of UvrC to the preincision complexes and it was found that the binding rate of UvrC to the more slowly incised cis-Pt.GCG preincision complex was higher than to the cis-Pt.GG preincision complex. This most likely reflects a qualitative difference in preincision complex structures. For both lesions the binding of UvrC to the preincision complex was fast compared to the kinetics of actual incision. Apparently, direct incision of cisplatin damage requires an additional conformational change after the binding of UvrC.

In vitro evolution of cisplatin/DNA monoadducts into diadducts is dependent upon superhelical density

DNA binding of antitumor platinum(II) compounds accounts for cellular toxicity. Binding of cis-dichlorodiammineplatinum(II) (cis-DDP) to DNA involves the transient presence of monoadducts which evolve in a second phase into difunctional lesions which are far more toxic than the monoadducts. Temporal control of the monoadducts half-live is at least dependent upon the chemical nature of the cis-platinum derivative and the secondary structure of DNA. The effect of the degree of DNA superhelicity on the binding of cis-platinum derivatives as well as on the evolution of monofunctional adducts has been addressed on plasmid DNA. The rate of platination was not affected by the degree of DNA superhelicity. Similarly, when the evolution of the lesions was complete, no variation of toxicity was found with different populations of topoisomers, as determined by bacterial transformation efficiency. In contrast, when the kinetic of difunctional lesions formation was controlled in vitro, we observed a higher rate of formation on a supercoiled plasmid by comparison with a relaxed one. This result suggests that platinum-DNA adduct toxicity could be modulated by the topology of the chromosome.