The effect of Escherichia coli Uvr protein binding on the topology of supercoiled DNA

Alkyltransferase-like protein clusters scan DNA rapidly over long distances and recruit NER to alkyl-DNA lesions

Alkylation of guanine bases in DNA is detrimental to cells due to its high mutagenic and cytotoxic potential and is repaired by the alkyltransferase AGT. Additionally, alkyltransferase-like proteins (ATLs), which are structurally similar to AGTs, have been identified in many organisms. While ATLs are per se catalytically inactive, strong evidence has suggested that ATLs target alkyl lesions to the nucleotide excision repair system (NER). Using a combination of single-molecule and ensemble approaches, we show here recruitment of UvrA, the initiating enzyme of prokaryotic NER, to an alkyl lesion by ATL. We further characterize lesion recognition by ATL and directly visualize DNA lesion search by highly motile ATL and ATL-UvrA complexes on DNA at the molecular level. Based on the high similarity of ATLs and the DNA-interacting domain of AGTs, our results provide important insight in the lesion search mechanism, not only by ATL but also by AGT, thus opening opportunities for controlling the action of AGT for therapeutic benefit during chemotherapy.

Structure of UvrA nucleotide excision repair protein in complex with modified DNA

One of the primary pathways for removal of DNA damage is nucleotide excision repair (NER). In bacteria, the UvrA protein is the component of NER that locates the lesion. A notable feature of NER is its ability to act on many DNA modifications that vary in chemical structure. So far, the mechanism underlying this broad specificity has been unclear. Here, we report the first crystal structure of a UvrA protein in complex with a chemically modified oligonucleotide. The structure shows that the UvrA dimer does not contact the site of lesion directly, but rather binds the DNA regions on both sides of the modification. The DNA region harboring the modification is deformed, with the double helix bent and unwound. UvrA uses damage-induced deformations of the DNA and a less rigid structure of the modified double helix for indirect readout of the lesion.

Potential role of proteolysis in the control of UvrABC incision

UvrB is specifically proteolyzed in Escherichia coli cell extracts to UvrB*. UvrB* is capable of interacting with UvrA in an aparently similar manner to the UvrB, however UvrB* is defective in the DNA strand displacement activity normally displayed by UvrAB. Whereas the binding of UvrC to a UvrAB-DNA complex leads to DNA incision and persistence of a stable post-incision protein-DNA complex, the binding of UvrC to UvrAB* leads to dissociation of the protein complex and no DNA incision is seen. The factor which stimulates this proteolysis has been partially purified and its substrate specificity has been examined. The protease factor is induced by "stress" and is under control of the htpR gene. The potential role of this proteolysis in the regulation of levels of active repair enzymes in the cell is discussed.

Incision of trivalent chromium [Cr(III)]-induced DNA damage by Bacillus caldotenax UvrABC endonuclease

Some hexavalent chromium [Cr(VI)]-containing compounds are lung carcinogens. Once within cells, Cr(VI) is reduced to trivalent chromium [Cr(III)] which displays an affinity for both DNA bases and the phosphate backbone. A diverse array of genetic lesions is produced by Cr including Cr-DNA monoadducts, DNA interstrand crosslinks (ICLs), DNA-Cr-protein crosslinks (DPCs), abasic sites, DNA strand breaks and oxidized bases. Despite the large amount of information available on the genotoxicity of Cr, little is known regarding the molecular mechanisms involved in the removal of these lesions from damaged DNA. Recent work indicates that nucleotide excision repair (NER) is involved in the processing of Cr-DNA adducts in human and rodent cells. In order to better understand this process at the molecular level and begin to identify the Cr-DNA adducts processed by NER, the incision of CrCl(3) [Cr(III)]-damaged plasmid DNA was studied using a thermal-resistant UvrABC NER endonuclease from Bacillus caldotenax (Bca). Treatment of plasmid DNA with Cr(III) (as CrCl(3)) increased DNA binding as a function of dose. For example, at a Cr(III) concentration of 1 microM we observed approximately 2 Cr(III)-DNA adducts per plasmid. At this same concentration of Cr(III) we found that approximately 17% of the plasmid DNA contained ICLs ( approximately 0.2 ICLs/plasmid). When plasmid DNA treated with Cr(III) (1 microM) was incubated with Bca UvrABC we observed approximately 0.8 incisions/plasmid. The formation of endonuclease IV-sensitive abasic lesions or Fpg-sensitive oxidized DNA bases was not detected suggesting that the incision of Cr(III)-damaged plasmid DNA by UvrABC was not related to the generation of oxidized DNA damage. Taken together, our data suggest that a sub-fraction of Cr(III)-DNA adducts is recognized and processed by the prokaryotic NER machinery and that ICLs are not necessarily the sole lesions generated by Cr(III) that are substrates for NER.

'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.

The inefficiency of incisions of ecteinascidin 743-DNA adducts by the UvrABC nuclease and the unique structural feature of the DNA adducts can be used to explain the repair-dependent toxicities of this antitumor agent

BACKGROUND

Ecteinascidin 743 (Et 743), a natural product derived from a marine tunicate, is a potent antitumor agent presently in phase II clinical trials. Et 743 binds in the minor groove of DNA and alkylates N2 of guanine via a unique mechanism involving catalytic activation. The sequence selectivity of Et 743 is governed by different patterns of hydrogen-bonding to DNA, which results in differential reversibility of the covalent adducts. As determined by nuclear magnetic resonance spectroscopy, the preferred sequences 5'-PuGC and 5'-PyGG are stabilized by a hydrogen-bonding network, while the non-preferred sequences 5'-NG(A/T) are much less stabilized due to the lack of a key hydrogen bond to the GC base pair on the 3'-side of the alkylated guanine.

RESULTS

Mammalian cell lines (XPB, XPD, XPF, XPG, and ERCC1) deficient in the nucleotide excision repair (NER) gene products show resistance to Et 743. The recognition and subsequent incision of Et 743-DNA adducts by the bacterial multisubunit endonuclease UvrABC were used to evaluate DNA repair-mediated toxicity as a rationale for the resistance of NER-defective cell lines and the antitumor activity of Et 743. The Et 743-DNA adducts are indeed recognized and incised by the UvrABC repair proteins; however, the pattern of incision indicated that the non-preferred, and less stable, sequences (i.e. 5'-NG(A/T)) modified with Et 743 are generally incised at a much higher efficiency than the preferred, more stable sequences (i.e. 5'-PuGC or 5'-PyGG). In addition, within the same Et 743 recognition sequence, the level of incision varies, indicating that flanking regions also contribute to the differential incision frequency.

CONCLUSIONS

The inefficient repair incision by the UvrABC nuclease of Et 743-DNA adducts provides a basis for rationalizing the observed repair-dependent cytotoxicities of these DNA adducts, if other associated structural properties of Et 743-DNA adducts are taken into account. In particular, the wedge-shaped Et 743, which forces open the minor groove of DNA, introducing a major groove bend, and the extrahelical protrusion of the C-subunit of Et 743 provide unique characteristics alongside the hydrogen-bonding stabilization of a covalent DNA adduct, which we propose traps an intermediate in NER processing of Et 743-DNA adducts. This trapped intermediate protein-Et 743-DNA adduct complex can be considered analogous to a poisoned topoisomerase I- or topoisomerase II-DNA complex. In the absence of an intact NER nuclease complex, this toxic lesion is unable to form, and the Et 743-DNA adducts, although not repaired by the NER pathway, are less toxic to cells. Conversely, elevated levels of either of these nucleases should lead to enhanced Et 743 toxicity.

Interaction of UvrA and UvrB proteins with a fluorescent single-stranded DNA. Implication for slow conformational change upon interaction of UvrB with DNA

UvrA and UvrB proteins play key roles in the damage recognition step in the nucleotide excision repair. However, the molecular mechanism of damage recognition by these proteins is still not well understood. In this work we analyzed the interaction between single-stranded DNA (ssDNA) labeled with a fluorophore tetramethylrhodamine (TMR) and Thermus thermophilus HB8 UvrA (ttUvrA) and UvrB (ttUvrB) proteins. TMR-labeled ssDNA (TMR-ssDNA) as well as UV-irradiated ssDNA stimulated ATPase activity of ttUvrB more strongly than did normal ssDNA, indicating that this fluorescent ssDNA was recognized as damaged ssDNA. The addition of ttUvrA or ttUvrB enhanced the fluorescence intensity of TMR-ssDNA, and the intensity was much greater in the presence of ATP. Fluorescence titration indicated that ttUvrA has higher specificity for TMR-ssDNA than for normal ssDNA in the absence of ATP. The ttUvrB showed no specificity for TMR-ssDNA, but it took over 200 min for the fluorescence intensity of the ttUvrB-TMR-ssDNA complex to reach saturation in the presence of ATP. This time-dependent change could be separated into two phases. The first phase was rapid, whereas the second phase was slow and dependent on ATP hydrolysis. Time dependence of ATPase activity and fluorescence polarization suggested that changes other than the binding reaction occurred during the second phase. These results strongly suggest that ttUvrB binds ssDNA quickly and that a conformational change in ttUrvB-ssDNA complex occurs slowly. We also found that DNA containing a fluorophore as a lesion is useful for directly investigating the damage recognition by UvrA and UvrB.

Solution structure of the DNA decamer duplex containing a 3'-T x T basepair of the cis-syn cyclobutane pyrimidine dimer: implication for the mutagenic property of the cis-syn dimer

The cis - syn dimer is the major DNA photoproduct produced by UV irradiation. In order to determine the origin of the mutagenic property of the cis - syn dimer, we used NMR restraints and molecular dynamics to determine the solution structure of a DNA decamer duplex containing a wobble pair between the 3'-T of the cis - syn dimer and the opposite T residue (CS/TA duplex). The solution structure of the CS/TA duplex revealed that the 3'-T x T base pair of the cis - syn dimer had base pair geometry that was significantly different from the canonical Watson-Crick base pair and caused destabilization and conformational distortion of its 3'-region. However, a 3'-T x A base pair at the cis - syn dimer within this related DNA decamer maintains the normal Watson-Crick base pair geometry and causes little distortion in the conformation of its 3'-side. Our results show that in spite of its stable hydrogen bonding, the insertion of a T residue opposite the 3'-T of the cis - syn dimer is inhibited by structural distortion caused by the 3'-T x T base pair. This may explain why the frequency of the 3'-T-->A transversion, which is the major mutation produced by the cis - syn dimer, is only 4%.

The role of ATP binding and hydrolysis by UvrB during nucleotide excision repair

We have isolated UvrB-DNA complexes by capture of biotinylated damaged DNA substrates on streptavidin-coated magnetic beads. With this method the UvrB-DNA preincision complex remains stable even in the absence of ATP. For the binding of UvrC to the UvrB-DNA complex no cofactor is needed. The subsequent induction of 3' incision does require ATP binding by UvrB but not hydrolysis. This ATP binding induces a conformational change in the DNA, resulting in the appearance of the DNase I-hypersensitive site at the 5' side of the damage. In contrast, the 5' incision is not dependent on ATP binding because it occurs with the same efficiency with ADP. We show with competition experiments that both incision reactions are induced by the binding of the same UvrC molecule. A DNA substrate containing damage close to the 5' end of the damaged strand is specifically bound by UvrB in the absence of UvrA and ATP (Moolenaar, G. F., Monaco, V., van der Marel, G. A., van Boom, J. H., Visse, R., and Goosen, N. (2000) J. Biol. Chem. 275, 8038-8043). To initiate the formation of an active UvrBC-DNA incision complex, however, UvrB first needs to hydrolyze ATP, and subsequently a new ATP molecule must be bound. Implications of these findings for the mechanism of the UvrA-mediated formation of the UvrB-DNA preincision complex will be discussed.

Damage recognition in nucleotide excision repair of DNA

Nucleotide excision repair (NER) is found throughout nature, in eubacteria, eukaryotes and archaea. In human cells it is the main pathway for the removal of damage caused by UV light, but it also acts on a wide variety of other bulky helix-distorting lesions caused by chemical mutagens. An ongoing challenge is to understand how a site of DNA damage is located during NER and distinguished from non-damaged sites. This article reviews information on damage recognition in mammalian cells and the bacterium Escherichia coli. In mammalian cells the XPC-hHR23B, XPA, RPA and TFIIH factors may all have a role in damage recognition. XPC-hHR23B has the strongest affinity for damaged DNA in some assays, as does the similar budding yeast complex Rad4-Rad23. There is current discussion as to whether XPC or XPA acts first in the repair process to recognise damage or distortions. TFIIH may play a role in distinguishing the damaged strand from the non-damaged one, if translocation along a DNA strand by the TFIIH DNA helicases is interrupted by encountering a lesion. The recognition and incision steps of human NER use 15 to 18 polypeptides, whereas E. coli requires only three proteins to obtain a similar result. Despite this, many remarkable similarities in the NER mechanism have emerged between eukaryotes and bacteria. These include use of a distortion-recognition factor, a strand separating helicase to create an open preincision complex, participation of structure-specific endonucleases and the lack of a need for certain factors when a region containing damage is already sufficiently distorted.

Solution structure of a DNA decamer duplex containing the stable 3' T.G base pair of the pyrimidine(6-4)pyrimidone photoproduct [(6-4) adduct]: implications for the highly specific 3' T --> C transition of the (6-4) adduct

The pyrimidine(6-4)pyrimidone photoproduct [(6-4) adduct] is one of the major photoproducts induced by UV irradiation of DNA and occurs at TpT sites. The (6-4) adduct is highly mutagenic and leads most often to a 3' T --> C transition with 85% replicating error frequency [LeClerc, J. E., Borden, A. & Lawrence, C. W. (1991) Proc. Natl. Acad. Sci. USA 88, 9685-9689]. To determine the origin of the specific 3' T --> C transition of the (6-4) adduct, we have used experimental NMR restraints and molecular dynamics to determine the solution structure of a (6-4)-lesion DNA decamer duplex that contains a mismatched base pair between the 3' T residue and an opposed G residue. Normal Watson-Crick-type hydrogen bonding is retained at the 5' T of the lesion site. The O2 carbonyl of the 3' T residue forms hydrogen bonds with the imino and amino protons of the opposed G residue. This potential hydrogen bonding stabilizes the overall helix and restores the highly distorted conformation of the (6-4) adduct to the typical B-form-like DNA structure. This structural feature can explain the marked preference for the insertion of an A residue opposite the 5' T and a G residue opposite the 3' T of the (6-4) lesion during trans-lesion synthesis. Thus these insertions yield the predominant 3' T --> C transition.

Thermodynamic and base-pairing studies of matched and mismatched DNA dodecamer duplexes containing cis-syn, (6-4) and Dewar photoproducts of TT

Cis-syn dimers, (6-4) products and their Dewar valence isomers are the major photoproducts of DNA and have different mutagenic properties and rates of repair. To begin to understand the physical basis for these differences, the thermal stability and base pairing properties of the corresponding photoproducts of the TT site in d(GAGTATTATGAG) were investigated. The (6-4) and Dewar products destabilize the duplex form by approximately 6 kcal/mol of free energy at 37 degreesC relative to the parent, whereas a cis-syn dimer only destabilizes the duplex form by 1.5 kcal/mol. Duplexes with G opposite the 3'-T of the (6-4) and Dewar products are more stable than those with A by approximately 0.4 kcal/mol, whereas the cis-syn dimer prefers A over G by 0.7 kcal/mol. Proton NMR suggests that wobble base pairing takes place between the 3'-T of the cis-syn dimer and an opposed G, whereas there is no evidence of significant H-bonding between these two bases in the (6-4) product. The thermodynamic and H-bonding data for the (6-4) product are consistent with a 4 nt interior loop structure which may facilitate flipping of the photoproduct in and out of the helix.

Hydrophobic forces dominate the thermodynamic characteristics of UvrA-DNA damage interactions

The Escherichia coli DNA repair proteins UvrA, UvrB and UvrC work together to recognize and incise DNA damage during the process of nucleotide excision repair (NER). To gain an understanding of the damage recognition properties of UvrA, we have used fluorescence spectroscopy to study the thermodynamics of its interaction with a defined DNA substrate containing a benzo[a]pyrene diol epoxide (BPDE) adduct. Oligonucleotides containing a single site-specifically modified N2-guanine (+)-trans-, (-)-trans-, (+)-cis-, or (-)-cis-BPDE adducts were ligated into 50-base-pair DNA fragments. All four stereoisomers of DNA-BPDE adducts show an excitation maximum at 350 nm and an emission maximum around 380 to 385 nm. Binding of UvrA to the BPDE-DNA adducts results in a five to sevenfold fluorescence enhancement. Titration of the BPDE-adducted DNA with UvrA was used to generate binding isotherms. The equilibrium dissociation constants for UvrA binding to (+)-trans-, (-)-trans-, (+)-cis-, and (-)-cis- BPDE adduct were: 7.4+/-1.9, 15. 8+/-5.4, 11.3+/-2.7 and 22.4+/-2.0 nM, respectively. There was a large negative change in heat capacity DeltaCpo,obs, (-3.3 kcal mol-1 K-1) accompanied by a relatively unchanged DeltaGoobs with temperature. Furthermore, varying the concentration of KCl showed that the number of ions released upon formation of UvrA-DNA complex is about 3.4, a relatively small value compared to the contact size of UvrA with the substrate. These data suggest that hydrophobic interactions are an important driving force for UvrA binding to BPDE-damaged DNA.

Introduction of a tryptophan reporter group into the ATP binding motif of the Escherichia coli UvrB protein for the study of nucleotide binding and conformational dynamics

The DNA-dependent ATPase activity of UvrB is required to support preincision steps in nucleotide excision repair in Escherichia coli. This activity is, however, cryptic. Elicited in nucleotide excision repair by association with the UvrA protein, it may also be unmasked by a specific proteolysis eliminating the C-terminal domain of UvrB (generating UvrB*). We introduced fluorescent reporter groups (tryptophan replacing Phe47 or Asn51) into the ATP binding motif of UvrB, without significant alteration of behavior, to study both nucleotide binding and those conformational changes expected to be essential to function. The inserted tryptophans occupy moderately hydrophobic, although potentially heterogeneous, environments as evidenced by fluorescence emission and time-resolved decay characteristics, yet are accessible to the diffusible quencher acrylamide. Activation, via specific proteolysis, is accompanied by conformational change at the ATP binding site, with multiple changes in emission spectra and a greater shielding of the tryptophans from diffusible quencher. Titration of tryptophan fluorescence with ATP has revealed that, although catalytically incompetent, UvrB can bind ATP and bind with an affinity equal to that of the active UvrB* form (Kd of approximately 1 mM). The ATP binding site of UvrB is therefore functional and accessible, suggesting that conformational change either brings amino acid residues into proper alignment for catalysis and/or enables response to effector DNA.

Sequence-dependent modulation of nucleotide excision repair: the efficiency of the incision reaction is inversely correlated with the stability of the pre-incision UvrB-DNA complex

The UvrABC excinuclease is involved in the nucleotide excision repair (NER) pathway. Sequence-dependent differences in repair efficiency have been reported for many different lesions, and it is often suggested that sites with poor repair contribute to the occurrence of mutation hot spots. However, guanine bases modified by N-2-acetylaminofluorence (AAF) within the NarI site (5'-G1G2CG3CC-3') are incised by the UvrABC excinuclease with different efficiencies in a pattern not correlated with the potency of mutation induction. To gain insight into the mechanism of sequence-dependent modulation of NER, we analyzed the formation, the structure and the stability of UvrB-DNA pre-incision complexes formed at all three positions of the AAF-modified NarI site. We show that the efficiency of release of UvrA2 from specific UvrA2B-DNA complexes is sequence-dependent and that the efficiency of incision is inversely related to the stability of the pre-incision complex. We propose that the pre-incision complex, [UvrB-DNA], when formed upon dissociation of UvrA2, undergoes a conformational change (isomerization step) giving rise to an unstable but incision-competent complex that we call [UvrB-DNA]'. The [UvrB-DNA] complex is stable and unable to form an incision-competent complex with UvrC. As the release of UvrA2, this isomerization step is sequence-dependent. Both steps contribute to modulate NER efficiency.

Formation of DNA repair intermediates and incision by the ATP-dependent UvrB-UvrC endonuclease

The Escherichia coli UvrB and UvrC proteins play key roles in DNA damage processing and incisions during nucleotide excision repair. To study the DNA structural requirements and protein-DNA intermediates formed during these processes, benzo[a]pyrene diol epoxide-damaged and structure-specific 50-base pair substrates were constructed. DNA fragments containing a preexisting 3' incision were rapidly and efficiently incised 5' to the adduct. Gel mobility shift assays indicated that this substrate supported UvrA dissociation from the UvrB-DNA complex, which led to efficient incision. Experiments with a DNA fragment containing an internal noncomplementary 11-base region surrounding the benzo[a]pyrene diol epoxide adduct indicated that UvrABC nuclease does not require fully duplexed DNA for binding and incision. In the absence of UvrA, UvrB (UvrC) bound to an 11-base noncomplementary region containing a 3' nick (Y substrate), forming a stable protein-DNA complex (Kd approximately 5-10 nM). Formation of this complex was absolutely dependent upon UvrC. Addition to this complex of ATP, but not adenosine 5'-(beta,gamma-iminotriphosphate) or adenosine 5'-(beta, gamma-methylene)triphosphate, caused incision three or four nucleotides 5' to the double strand-single strand junction. The ATPase activity of native UvrB is activated upon interaction with UvrC and enhanced further by the addition of Y substrate. Incision of this Y structure occurs even without DNA damage. Thus the UvrBC complex is a structure-specific, ATP-dependent endonuclease.

UvrAB activity at a damaged DNA site: is unpaired DNA present?

To study the activity of the Escherichia coli UvrA and UvrB nucleotide excision repair proteins during the formation of the pre-incision complex at a damaged DNA site, we used substrates with modifications around a single 2-(acetylamino)fluorene (AAF) lesion. Based on the release of AAF-containing oligonucleotides from a single-stranded DNA circle, we conclude that during interaction with our substrates UvrAB introduces changes in DNA which are localized at the lesion and are limited to 1-3 bp. Since these changes might include a denaturation of DNA at the lesion site and, consequently, a bubble structure might be present in a pre-incision complex, we studied incision activity of UvrABC excinuclease on substrates with 1-4 unpaired bases next to an AAF adduct. Opening more than one base on either or both sides of the lesion caused a significant decrease in the incision activity of UvrABC, but did not change the position of the incision sites. We conclude that the UvrAB action leading to a pre-incision complex does not include the formation of a bubble intermediate generated by extensive denaturation of base pairs.

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 binding of UvrAB proteins to bubble and loop regions in duplex DNA

Based on the binding of the UvrAB complex to a promoter region in transcription open complexes (Ahn, B., and Grossman, L. (1996) J. Biol. Chem. 271, 21453-21461) and the requirement of a single-stranded region for UvrAB helicase activity, we examined the binding of UvrAB proteins to synthetic bubble or loop regions in duplex DNA and the role of these regions in translocation of the UvrAB complex as well as incision of DNA damage. We found that the UvrAB complex was able to bind to bubble and loop regions with an affinity similar to that for damaged DNA in the absence of RNAP. The preferential recognition and incision of damaged sites by the UvrAB complex was observed downstream of the bubble or loop region in the strand complementary to the strand along which the UvrAB complex translocates. These results imply that the bubble region generated in duplex DNA by RNAP serves as a preferred entry site for the translocation of the UvrAB complex, and that preferential binding and unidirectional translocation of the UvrAB complex predetermine where incision is to occur.

The C-terminal region of the UvrB protein of Escherichia coli contains an important determinant for UvrC binding to the preincision complex but not the catalytic site for 3'-incision

The UvrABC endonuclease from Escherichia coli repairs damage in the DNA by dual incision of the damaged strand on both sides of the lesion. The incisions are in an ordered fashion, first on the 3'-side and next on the 5'-side of the damage, and they are the result of binding of UvrC to the UvrB-DNA preincision complex. In this paper, we show that at least the C-terminal 24 amino acids of UvrB are involved in interaction with UvrC and that this binding is important for the 3'-incision. The C-terminal region of UvrB, which shows homology with a domain of the UvrC protein, is part of a region that is predicted to be able to form a coiled-coil. We therefore propose that UvrB and UvrC interact through the formation of such a structure. The C-terminal region of UvrB only interacts with UvrC when present in the preincision complex, indicating that the conformational change in UvrB accompanying the formation of this complex exposes the UvrC binding domain. Binding of UvrC to the C-terminal region of UvrB is not important for the 5'-incision, suggesting that for this incision a different interaction of UvrC with the UvrB-DNA complex is required. Truncated UvrB mutants that lack up to 99 amino acids from the C terminus still give rise to significant incision (1-2%), indicating that this C-terminal region of UvrB does not participate in the formation of the active site for 3'-incision. This region, however, contains the residue (Glu-640) that was proposed to be involved in 3'-catalysis, since a mutation of the residue (E640A) fails to promote 3'-incision (Lin, J.J., Phillips, A.M., Hearst, J.E., and Sancar, A. (1992) J. Biol. Chem. 267, 17693-17700). We have isolated a mutant UvrB with the same E640A substitution, but this protein shows normal UvrC binding and incision in vitro and also results in normal survival after UV irradiation in vivo. As a consequence of these results, it is still an open question as to whether the catalytic site for 3'-incision is located in UvrB, in UvrC, or is formed by both proteins.

Protein-DNA interactions and alterations in the DNA structure upon UvrB-DNA preincision complex formation during nucleotide excision repair in Escherichia coli

The UvrB-DNA preincision complex is a key intermediate in the repair of damaged DNA by the UvrABC endonuclease from Escherichia coli. DNaseI footprinting of this complex on DNA with a cis-[Pt(NH3)2[d(GpG)-N7(1),N7(2)]] adduct provided global information on the protein binding site on this substrate [Visse, R., et al. (1991) J. Biol. Chem. 266, 7609-7617]. By applying a method developed by Fairall and Rhodes [Fairall, L., & Rhodes, D. (1992) Nucleic Acids Res. 20, 4727-4731], who have used the size and shape of DNasI for the interpretation of a footprint, we were able to define in more detail the region where UvrB-DNA interactions in the preincision complex occur. The potential interactions with phosphate groups could be reduced to less then 14 in the damaged and to 12 in the nondamaged strand. The main UvrB-DNA interactions seem restricted to the major groove on both sides of the lesion. As a consequence UvrB crosses the minor groove just downstream of the damage. Such a binding of UvrB orients the protein away from the damage. The more detailed interpretation of UvrB-DNA interactions was supported by methylation protection experiments. The structure of the DNA in the preincision complex formed on cis-[Pt(NH3)2[GpG-N7(1),N7(2)]] is altered as could be shown diethylpyrocarbonate sensitivity of adenines just downstream of the lesion. However the adenines just downstream of another cisplatin adduct, cis-[Pt(NH3)2[d(GpCpG)-N7(1),N7(3)]], did not become diethylpyrocarbonate sensitive in the preincision complex although this complex is incision proficient.(ABSTRACT TRUNCATED AT 250 WORDS)

Enhancement of the uvrA gene dosage reduces pyrimidine dimer excision in UV-irradiated Escherichia coli

E. coli possesses an efficient repair mechanism able to remove pyrimidine dimers from UV-irradiated DNA, which is catalyzed by UvrABC endonuclease. In E. coli B/r Hcr+ cells transformed with a multicopy plasmid harboring a gene coding for UvrA, the excision capacity was greatly reduced. The course of thymine dimer excision was investigated using the enzymatic as well as the radiochromatographic method and the results are discussed in term of nonspecific interaction between the excess of UvrA protein and undamaged DNA duplex.

Mechanism of action of the Escherichia coli UvrABC nuclease: clues to the damage recognition problem

During the process of E. coli nucleotide excision repair, DNA damage recognition and processing are achieved by the action of the uvrA, uvrB, and uvrC gene products. The availability of highly purified proteins has lead to a detailed molecular description of E. coli nucleotide excision repair that serves as a model for similar processes in eukaryotes. An interesting aspect of this repair system is the protein complex's ability to work on a vast array of DNA lesions that differ widely in their chemical composition and molecular architecture. Here we propose a model for damage recognition in which the UvrB protein serves as the component that confers enhanced specificity to a preincision complex. We hypothesize that one major determinant for the formation of a stable preincision complex appears to be the disruption of base stacking interactions by DNA lesions.

Renaturation of DNA catalysed by yeast DNA repair and recombination protein RAD10

The RAD10 gene of Saccharomyces cerevisiae is required for the incision step of excision repair of ultraviolet-damaged DNA, and it functions in mitotic recombination. RAD10 has homology to the human excision repair gene ERCC-1. Here we describe the purification of the protein encoded by RAD10 and show that it is a DNA-binding protein with a strong preference for single-stranded DNA. We also show that RAD10 promotes the renaturation of complementary DNA strands.

DNA unwinding produced by site-specific intrastrand cross-links of the antitumor drug cis-diamminedichloroplatinum(II)

The DNA unwinding produced by specific adducts of the antitumor drug cis-diamminedichloroplatinum(II) has been quantitatively determined. Synthetic DNA duplex oligonucleotides of varying lengths with two base pair cohesive ends were synthesized and characterized that contained site-specific intrastrand N7-purine/N7-purine cross-links. Included are cis-[Pt(NH3)2[d(GpG)]], cis-[Pt(NH3)2(d(ApG)]], and cis-[Pt(NH3)2[d(GpTpG)]] adducts, respectively referred to as cis-GG, cis-AG, and cis-GTG. Local DNA distortions at the site of platination were amplified by polymerization of these monomers and quantitatively evaluated by using polyacrylamide gel electrophoresis. The extent of DNA unwinding was determined by systematically varying the interplatinum distance, or phasing, in polymers containing the adducts. The multimer that migrates most slowly gives the optimal phasing for cooperative bending, from which the degree of unwinding can be obtained. We find that the cis-GG and cis-AG adducts both unwind DNA by 13 degrees, while the cis-GTG adduct unwinds DNA by 23 degrees. In addition, experiments are presented that support previous studies revealing that a hinge joint forms at the sites of platination in DNA molecules containing trans-GTG adducts. On the basis of an analysis of the present and other published studies of site-specifically modified DNA, we propose that local duplex unwinding is a major determinant in the recognition of DNA damage by the Escherichia coli (A)BC excinuclease. In addition, local duplex unwinding of 13 degrees and bending by 35 degrees are shown to correlate well with the recognition of platinated DNA by a previously identified damage recognition protein (DRP) in human cells.

DNA helicases of Escherichia coli

A great deal has been learned in the last 15 years with regard to how helicase enzymes participate in DNA metabolism and how they interact with their DNA substrates. However, many questions remain unanswered. Of critical importance is an understanding of how NTP hydrolysis and hydrogen-bond disruption are coupled. Several models exist and are being tested; none has been proven. In addition, an understanding of how a helicase disrupts the hydrogen bonds holding duplex DNA together is lacking. Recently, helicase enzymes that unwind duplex RNA and DNA.RNA hybrids have been described. In some cases, these are old enzymes with new activities. In other cases, these are new enzymes only recently discovered. The significance of these reactions in the cell remains to be clarified. However, with the availability of significant amounts of these enzymes in a highly purified state, and mutant alleles in most of the genes encoding them, the answers to these questions should be forthcoming. The variety of helicases found in E. coli, and the myriad processes these enzymes are involved in, were perhaps unexpected. It seems likely that an equally large number of helicases will be discovered in eukaryotic cells. In fact, several helicases have been identified and purified from eukaryotic sources ranging from viruses to mouse cells (4-13, 227-234). Many of these helicases have been suggested to have roles in DNA replication, although this remains to be shown conclusively. Helicases with roles in DNA repair, recombination, and other aspects of DNA metabolism are likely to be forthcoming as we learn more about these processes in eukaryotic cells.

The UvrABC endonuclease system of Escherichia coli--a view from Baltimore

Nucleotide excision is initiated by the UvrABC endonuclease system in which the initial DNA interaction is with UvrA which was dimerized in the presence of ATP. Nucleoprotein formation most likely takes place on undamaged regions of DNA by (UvrA)2 which has been dimerized in the presence of ATP. Topological unwinding of DNA, driven by ATP binding, is increased by the presence of UvrB to approximately a single helical turn. The Uvr(A)2B complex translocates to a damaged site by the combined Uvr(A)2B helicase in which the driving force is provided by the UvrB-associated ATPase. The dual incision reaction is initiated by the binding of the UvrC protein to the Uvr(A)2B-nucleoprotein complex. The proteins in this post-incision nucleoprotein complex do not turn over and require the presence of the UvrD protein and DNA polymerase I under polymerizing conditions. The final integrity of the DNA strands is restored with polynucleotide ligase.

Nucleotide excision repair in Escherichia coli

One of the best-studied DNA repair pathways is nucleotide excision repair, a process consisting of DNA damage recognition, incision, excision, repair resynthesis, and DNA ligation. Escherichia coli has served as a model organism for the study of this process. Recently, many of the proteins that mediate E. coli nucleotide excision have been purified to homogeneity; this had led to a molecular description of this repair pathway. One of the key repair enzymes of this pathway is the UvrABC nuclease complex. The individual subunits of this enzyme cooperate in a complex series of partial reactions to bind to and incise the DNA near a damaged nucleotide. The UvrABC complex displays a remarkable substrate diversity. Defining the structural features of DNA lesions that provide the specificity for damage recognition by the UvrABC complex is of great importance, since it represents a unique form of protein-DNA interaction. Using a number of in vitro assays, researchers have been able to elucidate the action mechanism of the UvrABC nuclease complex. Current research is devoted to understanding how these complex events are mediated within the living cell.

Superhelical stress restrained in plasmid DNA during repair synthesis initiated by the UvrA, B and C proteins in vitro

Purified UvrA, UvrB, UvrC, UvrD, PolA and Lig proteins from Escherichia coli have been used to assess the effect of nucleotide excision repair on the conformation of native negatively supercoiled plasmid DNA in an in vitro test system. The analysis of labeled reaction products on specific gel systems suggests that the Uvr excinuclease has the ability to restrain the superhelical stress in the template DNA during the repair process. This feature, observed in the case of the Uvr system is not found if the repair reaction is initiated by T4 endonuclease V or Micrococcus luteus UV endonuclease.

The noncovalent complex between DNA and the bifunctional intercalator ditercalinium is a substrate for the UvrABC endonuclease of Escherichia coli

We have demonstrated that the noncovalent complex formed between DNA and an antitumor bifunctional intercalator, ditercalinium, is recognized in vitro as bulky covalent DNA lesions by the purified Escherichia coli UvrABC endonuclease. It was established that no covalent drug-DNA adduct was formed during the incubation of the drug with DNA or during subsequent incubation with the UvrAB proteins. The nucleoprotein-ditercalinium complexes appear different from those generated by repair of pyrimidine dimers. The UvrA protein is able to form a stable complex with ditercalinium-intercalated DNA in the presence of ATP, whereas both UvrA and UvrB proteins are required to form a stable complex with pyrimidine dimer-containing DNA. The apparent half-life of the UvrA- and UvrAB-ditercalinium-DNA complexes following removal of free ditercalinium is 5 min. However, if the free ditercalinium concentration is maintained to allow the intercalation of one molecule of ditercalinium per 3000 base pairs, the half-life of the UvrA- or UvrAB-ditercalinium-DNA complex is 50 min, comparable to that of the complex of UvrAB proteins formed with pyrimidine dimer-containing DNA. UvrABC endonuclease incises ditercalinium-intercalated DNA as efficiently as pyrimidine dimer-containing DNA. However, unlike repair of pyrimidine dimers, the incision reaction is strongly favored by the supercoiling of the DNA substrate. Because UvrA- or UvrAB-ditercalinium-DNA complexes can be formed with relaxed DNA without leading to a subsequent incision reaction, these apparently dead-end nucleoprotein complexes may become lesions in themselves resulting in the cytotoxicity of ditercalinium. Our results show that binding of excision repair proteins to a noncovalent DNA-ligand complex may lead to cell toxicity.

ATPase activity of the UvrA and UvrAB protein complexes of the Escherichia coli UvrABC endonuclease

We have analyzed the ATPase activity exhibited by the UvrABC DNA repair complex. The UvrA protein is an ATPase whose lack of DNA dependence may be related to the ATP induced monomer-dimer transitions. ATP induced dimerization may be responsible for the enhanced DNA binding activity observed in the presence of ATP. Although the UvrA ATPase is not stimulated by dsDNA, such DNA can modulate the UvrA ATPase activity by decreases in Km and Vm and alterations in the Ki for ADP and ATP-gamma-S. The induction of such changes upon binding to DNA may be necessary for cooperative interactions of UvrA with UvrB that result in a DNA stimulated ATPase for the UvrAB protein complex. The UvrAB ATPase displays unique kinetic profiles that are dependent on the structure of the DNA effector. These kinetic changes correlate with changes in footprinting patterns, the stabilization of protein complexes on DNA damage and with the expression of helicase activity.

Potential role of proteolysis in the control of UvrABC incision

UvrB is specifically proteolyzed in Escherichia coli cell extracts to UvrB*. UvrB* is capable of interacting with UvrA in an apparently similar manner to the UvrB, however UvrB* is defective in the DNA strand displacement activity normally displayed by UvrAB. Whereas the binding of UvrC to a UvrAB-DNA complex leads to DNA incision and persistence of a stable post-incision protein-DNA complex, the binding of UvrC to UvrAB* leads to dissociation of the protein complex and no DNA incision is seen. The factor which stimulates this proteolysis has been partially purified and its substrate specificity has been examined. The protease factor is induced by "stress" and is under control of the htpR gene. The potential role of this proteolysis in the regulation of levels of active repair enzymes in the cell is discussed.