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.     

The effect of the DNA flanking the lesion on formation of the UvrB-DNA preincision complex. Mechanism for the UvrA-mediated loading of UvrB onto a DNA damaged site

The UvrB-DNA preincision complex plays a key role in nucleotide excision repair in Escherichia coli. To study the formation of this complex, derivatives of a DNA substrate containing a cholesterol adduct were constructed. Introduction of a single strand nick into either the top or the bottom strand at the 3' side of the adduct stabilized the UvrB-DNA complex, most likely by the release of local stress in the DNA. Removal of both DNA strands up to the 3' incision site still allowed formation of the preincision complex. Similar modifications at the 5' side of the damage, however, gave different results. The introduction of a single strand nick at the 5' incision site completely abolished the UvrA-mediated formation of the UvrB-DNA complex. Deletion of both DNA strands up to the 5' incision site also prevented the UvrA-mediated loading of UvrB onto the damaged site, but UvrB by itself could bind very efficiently. This demonstrates that the UvrB protein is capable of recognizing damage without the matchmaker function of the UvrA protein. Our results also indicate that the UvrA-mediated loading of the UvrB protein is an asymmetric process, which starts at the 5' side of the damage.     

Functions of base flipping in E. coli nucleotide excision repair

UvrB is the main damage recognition protein in bacterial nucleotide excision repair and is capable of recognizing various structurally unrelated types of damage. Previously we have shown that upon binding of Escherichia coli UvrB to damaged DNA two nucleotides become extrahelical: the nucleotide directly 3' to the lesion and its base-pairing partner in the non-damaged strand. Here we demonstrate using a novel fluorescent 2-aminopurine-menthol modification that the position of the damaged nucleotide itself does not change upon UvrB binding. A co-crystal structure of B. caldotenax UvrB and DNA has revealed that one nucleotide is flipped out of the DNA helix into a pocket of the UvrB protein where it stacks on Phe249 [J.J. Truglio, E. Karakas, B. Hau, H. Wang, M.J. DellaVecchia, B. van Houten, C. Kisker, Structural basis for DNA recognition and processing by UvrB, Nat. Struct. Mol. Biol. 13 (2006) 360-364]. By mutating the equivalent of Phe249 (Tyr249) in the E. coli UvrB protein we show that on damaged DNA neither of the extrahelical nucleotides is inserted into this protein pocket. The mutant UvrB protein, however, resulted in an increased binding and incision of undamaged DNA showing that insertion of a base into the nucleotide-binding pocket is important for dissociation of UvrB from undamaged sites. Replacing the nucleotides in the non-damaged strand with a C3-linker revealed that the extruded base in the non-damaged strand is not directly involved in UvrB-binding or UvrC-mediated incision, but that its displacement is needed to allow access for residues of UvrB or UvrC to the neighboring base, which is directly opposite the DNA damage. This interaction is shown to be essential for optimal 3'-incision by UvrC. After 3'-incision base flipping in the non-damaged DNA strand is lost, indicative for a conformational change needed to prepare the UvrB-DNA complex for 5'-incision.     

The nucleotide excision repair protein UvrB, a helicase-like enzyme with a catch

Nucleotide excision repair (NER) is a universal DNA repair mechanism found in all three kingdoms of life. Its ability to repair a broad range of DNA lesions sets NER apart from other repair mechanisms. NER systems recognize the damaged DNA strand and cleave it 3', then 5' to the lesion. After the oligonucleotide containing the lesion is removed, repair synthesis fills the resulting gap. UvrB is the central component of bacterial NER. It is directly involved in distinguishing damaged from undamaged DNA and guides the DNA from recognition to repair synthesis. Recently solved structures of UvrB from different organisms represent the first high-resolution view into bacterial NER. The structures provide detailed insight into the domain architecture of UvrB and, through comparison, suggest possible domain movements. The structure of UvrB consists of five domains. Domains 1a and 3 bind ATP at the inter-domain interface and share high structural similarity to helicases of superfamilies I and II. Not related to helicase structures, domains 2 and 4 are involved in interactions with either UvrA or UvrC, whereas domain 1b was implicated for DNA binding. The structures indicate that ATP binding and hydrolysis is associated with domain motions. UvrB's ATPase activity, however, is not coupled to the separation of long DNA duplexes as in helicases, but rather leads to the formation of the preincision complex with the damaged DNA substrate. The location of conserved residues and structural comparisons with helicase-DNA structures suggest how UvrB might bind to DNA. A model of the UvrB-DNA interaction in which a beta-hairpin of UvrB inserts between the DNA double strand has been proposed recently. This padlock model is developed further to suggest two distinct consequences of domain motion: in the UvrA(2)B-DNA complex, domain motions lead to translocation along the DNA, whereas in the tight UvrB-DNA pre-incision complex, they lead to distortion of the 3' incision site.     

Base flipping in nucleotide excision repair

UvrB, the ultimate damage-binding protein in bacterial nucleotide excision repair is capable of binding a vast array of structurally unrelated lesions. A beta-hairpin structure in the protein plays an important role in damage-specific binding. In this paper we have monitored DNA conformational alterations in the UvrB-DNA complex, using the fluorescent adenine analogue 2-aminopurine. We show that binding of UvrB to a DNA fragment with cholesterol damage moves the base adjacent to the lesion at the 3' side into an extrahelical position. This extrahelical base is not accessible for acrylamide quenching, suggesting that it inserts into a pocket of the UvrB protein. Also the base opposite this flipped base is extruded from the DNA helix. The degree of solvent exposure of both residues varies with the type of cofactor (ADP/ATP) bound by UvrB. Fluorescence of the base adjacent to the damage is higher when UvrB is in the ADP-bound configuration, but concomitantly this UvrB-DNA complex is less stable. In the ATP-bound form the UvrB-DNA complex is very stable and in this configuration the base in the non-damaged strand is more exposed. Hairpin residue Tyr-95 is specifically involved in base flipping in the non-damaged strand. We present evidence that this conformational change in the non-damaged strand is important for 3' incision by UvrC.     

Architecture of nucleotide excision repair complexes: DNA is wrapped by UvrB before and after damage recognition

Nucleotide excision repair (NER) is a major DNA repair mechanism that recognizes a broad range of DNA damages. In Escherichia coli, damage recognition in NER is accomplished by the UvrA and UvrB proteins. We have analysed the structural properties of the different protein-DNA complexes formed by UvrA, UvrB and (damaged) DNA using atomic force microscopy. Analysis of the UvrA(2)B complex in search of damage revealed the DNA to be wrapped around the UvrB protein, comprising a region of about seven helical turns. In the UvrB-DNA pre-incision complex the DNA is wrapped in a similar way and this DNA configuration is dependent on ATP binding. Based on these results, a role for DNA wrapping in damage recognition is proposed. Evidence is presented that DNA wrapping in the pre-incision complex also stimulates the rate of incision by UvrC.     

Incision of damaged versus nondamaged DNA by the Escherichia coli UvrABC proteins.

Incision of damaged DNA by the Escherichia coli UvrABC endonuclease requires the UvrA, UvrB, and UvrC proteins as well as ATP hydrolysis. This incision reaction can be divided into three steps: site recognition, preincision complex formation, and incision. UvrAB is able to execute the first two steps in the reaction while the addition of UvrC is required for the incision of DNA. This incision reaction does not require ATP hydrolysis and results in the formation of a tight UvrABC post-incision complex and the generation of an oligomer of approximately 12 nucleotides. At high UvrABC concentrations the specificity of the incision for damaged DNA is decreased and significant incision of undamaged DNA occurs. Analogous to damage specific incision, this type of incision leads to generation of an oligonucleotide, but in this case the size is approximately 9 nucleotides in length. Further evidence shows that the combination of UvrB and UvrC proteins can generate a significant amount of a similar size product on undamaged DNA. In addition, the UvrC protein alone can generate a small amount of the same product. Immunological characterization of the weak nuclease activity seen with UvrC indicates that the activity is very tightly associated with the purified UvrC protein.     

Structure and function of the (A)BC excinuclease of Escherichia coli

(A)BC excinuclease is the enzymatic activity resulting from the mixture of E. coli UvrA, UvrB and UvrC proteins with damaged DNA. This is a functional definition as new evidence suggests that the three proteins never associate in a ternary complex. The UvrA subunit associates with the UvrB subunit in the form of an A2B1 complex which, guided by UvrA's affinity for damaged DNA binds to a lesion in DNA and delivers the UvrB subunit to the damaged site. The UvrB-damaged DNA complex is extremely stable (t1/2 congruent to 100 min). The UvrC subunit, which has no specific affinity for damaged DNA, recognizes the UvrB-DNA complex with high specificity and the protein complex consisting of UvrB and UvrC proteins makes two incisions, the 8th phosphodiester bond 5' and the 5th phosphodiester bond 3' to the damaged nucleotide. (A)BC excinuclease recognizes DNA damage ranging from AP sites and thymine glycols to pyrimidine dimers, and the adducts of psoralen, cisplatinum, mitomycin C, 4-nitroquinoline oxide and interstrand crosslinks.     

Binding of the UvrB dimer to non-damaged and damaged DNA: residues Y92 and Y93 influence the stability of both subunits

UvrB is the ultimate damage-binding protein in bacterial nucleotide excision repair. Previous AFM experiments have indicated that UvrB binds to a damage as a dimer. In this paper we visualize for the first time a UvrB dimer in a gel retardation assay, with the second subunit (B2) more loosely bound than the subunit (B1) that interacts with the damage. A beta-hairpin motif in UvrB plays an important role in damage specific binding. Alanine substitutions of Y92 or Y93 in the beta-hairpin result in proteins that kill E. coli cells as a consequence of incision in non-damaged DNA. Apparently, both residues are needed to prevent binding of UvrB to non-damaged DNA. The lethality of Y93A results from UvrC-mediated incisions, whereas that of Y92A is due to incisions by Cho. This difference could be ascribed to a difference in stability of the B2 subunit in the mutant UvrB-DNA complexes. We show that for 3' incision UvrC needs to displace this second UvrB subunit from the complex, whereas Cho seems capable to incise the dimer-complex. Footprint analysis of the contacts of UvrB with damaged DNA revealed that the B2 subunit interacts with the flanking DNA at the 3' side of the lesion. The B2 subunit of mutant Y92A appeared to be more firmly associated with the DNA, indicating that even when B1 is bound to a lesion, the B2 subunit probes the adjacent DNA for presence of damage. We propose this to be a reflection of the process that the UvrB dimer uses to find lesions in the DNA. In addition to preventing binding to non-damaged DNA, the Y92 and Y93 residues appear also important for making specific contacts (of B1) with the damaged site. We show that the concerted action of the two tyrosines lead to a conformational change in the DNA surrounding the lesion, which is required for the 3' incision reaction.     

Formation and enzymatic properties of the UvrB.DNA complex

The UvrA, UvrB, and UvrC proteins collectively catalyze the dual incision of a damaged DNA strand in an ATP-dependent reaction. We previously reported (Orren, D. K., and Sancar, A. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 5237-5241) that UvrA delivers UvrB to damaged sites in DNA; upon addition of UvrC to these UvrB.DNA complexes, the DNA is incised. In the present study, we have further characterized both the delivery of UvrB to DNA and the subsequent incision process, with emphasis on the role of ATP in these reactions. The UvrA-dependent delivery of UvrB onto damaged DNA is relatively slow (kon approximately 6 x 10(4) M-1 s-1) and requires ATP hydrolysis (Km = 120 microM). Although ATP enhances the stability of UvrB.DNA complexes (koff = 8.5 x 10(-5) s-1), the isolated UvrB.DNA complexes do not contain any covalently attached or stably bound nucleotide. However, ATP binding is required for the UvrC-dependent dual incision of DNA bound by UvrB. Interestingly, adenosine 5'-(3-O-thio)triphosphate can substitute for ATP at this step. The Km for ATP during incision is 2 microM, but ATP is not hydrolyzed at a detectable level during the incision reaction. The incisions made by UvrB-UvrC are on both sides of the adduct and result in the excision of the damaged nucleotide.     

Catalytic sites for 3' and 5' incision of Escherichia coli nucleotide excision repair are both located in UvrC

Nucleotide excision repair in Escherichia coli is a multistep process in which DNA damage is removed by incision of the DNA on both sides of the damage, followed by removal of the oligonucleotide containing the lesion. The two incision reactions take place in a complex of damaged DNA with UvrB and UvrC. It has been shown (Lin, J. -J., and Sancar, A. (1992) J. Biol. Chem. 267, 17688-17692) that the catalytic site for incision on the 5' side of the damage is located in the UvrC protein. Here we show that the catalytic site for incision on the 3' side is in this protein as well, because substitution R42A abolishes 3' incision, whereas formation of the UvrBC-DNA complex and the 5' incision reaction are unaffected. Arg(42) is part of a region that is homologous to the catalytic domain of the homing endonuclease I-TevI. We propose that the UvrC protein consists of two functional parts, with the N-terminal half for the 3' incision reaction and the C-terminal half containing all the determinants for the 5' incision reaction.     

Identification of the different intermediates in the interaction of (A)BC excinuclease with its substrates by DNase I footprinting on two uniquely modified oligonucleotides

(A)BC excinuclease is the enzymatic activity resulting from the joint actions of UvrA, UvrB and UvrC proteins of Escherichia coli. The enzyme removes from DNA many types of adducts of dissimilar structures with different efficiencies. To understand the mechanism of substrate recognition and the basis of enzyme specificity, we investigated the interactions of the three subunits with two synthetic substrates, one containing a psoralen-thymine monoadduct and the other a thymine dimer. Using DNase I as a probe, we found that UvrA makes a 33 base-pair footprint around the psoralen-thymine adduct and that UvrA-UvrB make a 45 base-pair asymmetric footprint characterized by a hypersensitive site 11 nucleotides 5' to the adduct and protection mostly on the 3' side of the damage. Conditions that favor dissociation of UvrA from the UvrA-UvrB-DNA complex, such as addition of excess undamaged DNA to the reaction mixture, resulted in the formation of a 19 base-pair UvrB footprint. In contrast, a thymine dimer in a similar sequence context failed to elicit a UvrA, a UvrA-UvrB or UvrB footprint and gave rise to a relatively weak DNase I hypersensitive site typical of a UvrA-UvrB complex. Dissociation of UvrA from the UvrA-UvrB-DNA complex stimulated the rate of incision of both substrates upon addition of UvrC, leading us to conclude that UvrA is not a part of the incision complex and that it actually interferes with incision. The extent of incision of the two substrates upon addition of UvrC (70% for the psoralen adduct and 20% for the thymine dimer) was proportional to the extent of formation of the UvrA-UvrB-DNA (i.e. UvrB-DNA) complex, indicating that substrate discrimination occurs at the preincision step.     

The presence of two UvrB subunits in the UvrAB complex ensures damage detection in both DNA strands

It is generally accepted that the damage recognition complex of nucleotide excision repair in Escherichia coli consists of two UvrA and one UvrB molecule, and that in the preincision complex UvrB binds to the damage as a monomer. Using scanning force microscopy, we show here that the damage recognition complex consists of two UvrA and two UvrB subunits, with the DNA wrapped around one of the UvrB monomers. Upon binding the damage and release of the UvrA subunits, UvrB remains a dimer in the preincision complex. After association with the UvrC protein, one of the UvrB monomers is released. We propose a model in which the presence of two UvrB subunits ensures damage recognition in both DNA strands. Upon binding of the UvrA(2)B(2) complex to a putative damaged site, the DNA wraps around one of the UvrB monomers, which will subsequently probe one of the DNA strands for the presence of a lesion. When no damage is found, the DNA will wrap around the second UvrB subunit, which will check the other strand for aberrations.     

Post-incision steps of nucleotide excision repair in Escherichia coli. Disassembly of the UvrBC-DNA complex by helicase II and DNA polymerase I.

UvrA, UvrB, and UvrC initiate nucleotide excision repair by incising a damaged DNA strand on each side of the damaged nucleotide. This incision reaction is substoichiometric with regard to UvrB and UvrC, suggesting that both proteins remain bound following incision and do not "turn over." The addition of only helicase II to such reaction mixtures turns over UvrC; UvrB turnover requires the addition of helicase II, DNA polymerase I, and deoxynucleoside triphosphates. Column chromatography and psoralen photocross-linking experiments show that following incision, the damaged oligomer remains associated with the undamaged strand, UvrB, and UvrC in a post-incision complex. Helicase II releases the damaged oligomer and UvrC from this complex, making repair synthesis possible; DNase I footprinting experiments show that UvrB remains bound to the resulting gapped DNA until displaced by DNA polymerase I. The specific binding of UvrB to a psoralen adduct in DNA inhibits psoralen-mediated DNA-DNA cross-linking, yet promotes the formation of UrvB-psoralen-DNA cross-links. The discovery of psoralen-UvrB photocross-linking offers the potential of active-site labeling.     

Electron microscopic study of (A)BC excinuclease. DNA is sharply bent in the UvrB-DNA complex.

Nucleotide excision repair in Escherichia coli is initiated by the UvrA, UvrB and UvrC proteins. UvrA is the damage recognition subunit, makes an A2B1 complex with the targeting subunit UvrB, and the complex binds to the lesion site; UvrA dissociates leaving behind a very stable UvrB-DNA complex that is recognized by the trigger subunit, UvrC, and the ensuing UvrB-UvrC heterodimer makes two incisions, one on either side of the lesion. Using electron microscopy, we investigated the structures of these early A, A-B intermediates on DNA containing ultraviolet light photoproducts. UvrA, which is known to bind to DNA as a dimer and produce a DNase I footprint of 33 base-pairs does not change the trajectory of DNA appreciably. The A2B1 complex clearly shows a bipartite structure and its effect on the trajectory of the DNA was not consistently straight or kinked. In contrast, the DNA in the preincision UvrB-DNA complex appears to be severely kinked; 43% of the molecules are bent by 80 degrees or more, with an average bending angle of 127 degrees. It appears that protein-induced bending is an important step on the pathway leading to excision of the damaged nucleotide by (A)BC excinuclease.     

DNase I footprint of ABC excinuclease

The incision and excision steps of nucleotide excision repair in Escherichia coli are mediated by ABC excinuclease, a multisubunit enzyme composed of three proteins, UvrA, UvrB, and UvrC. To determine the DNA contact sites and the binding affinity of ABC excinuclease for damaged DNA, it is necessary to engineer a DNA fragment uniquely modified at one nucleotide. We have recently reported the construction of a 40 base pair (bp) DNA fragment containing a psoralen adduct at a central TpA sequence (Van Houten, B., Gamper, H., Hearst, J. E., and Sancar, A. (1986a) J. Biol. Chem. 261, 14135-14141). Using similar methodology a 137-bp fragment containing a psoralen-thymine adduct was synthesized, and this substrate was used in DNase I-footprinting experiments with the subunits of ABC excinuclease. It was found that the UvrA subunit binds specifically to the psoralen modified 137-bp fragment with an apparent equilibrium constant of K8 = 0.7 - 1.5 X 10(8) M-1, while protecting a 33-bp region surrounding the DNA adduct. The equilibrium constant for the nonspecific binding of UvrA was Kns = 0.7 - 2.9 X 10(5) M-1 (bp). In the presence of the UvrB subunit, the binding affinity of UvrA for the damaged substrate increased to K8 = 1.2 - 6.7 X 10(8) M-1 while the footprint shrunk to 19 bp. In addition the binding of the UvrA and UvrB subunits to the damaged substrate caused the 11th phosphodiester bond 5' to the psoralen-modified thymine to become hypersensitive to DNase I cleavage. These observations provide evidence of an alteration in the DNA conformation which occurs during the formation of the ternary UvrA.UvrB.DNA complex. The addition of the UvrC subunit to the UvrA.UvrB.DNA complex resulted in incisions on both sides of the adduct but did not cause any detectable change in the footprint. Experiments with shorter psoralen-modified DNA fragments (20-40 bp) indicated that ABC excinuclease is capable of incising a DNA fragment extending either 3 or 1 bp beyond the normal 5' or 3' incision sites, respectively. These results suggest that the DNA beyond the incision sites, while contributing to ABC excinuclease-DNA complex formation, is not essential for cleavage to occur.     

Active site of (A)BC excinuclease. I. Evidence for 5' incision by UvrC through a catalytic site involving Asp399, Asp438, Asp466, and His538 residues.

(A)BC excinuclease of Escherichia coli removes damaged nucleotides from DNA by hydrolyzing the 8th phosphodiester bond 5' and the 15th phosphodiester bond 3' to the modified base. The activity results from the ordered action of UvrA, UvrB, and UvrC proteins. The role of UvrA is to help assemble the UvrB.DNA complex, and it is not involved in the actual incision reactions which are carried out by UvrB and UvrC. To investigate the role of UvrC in the nuclease activity a subset of His, Asp, and Glu residues in the C-terminal half of the protein were mutagenized in vitro. The effect of these mutations on UV resistance in vivo and incision activity in vitro were investigated. Mutations, H538F, D399A, D438A, and D466A conferred extreme UV sensitivity. Enzyme reconstituted with these mutant proteins carried out normal 3' incision but was completely defective in 5' incision activity. Our data suggest that UvrC makes the 5' incision by employing a mechanism whereby the three carboxylates acting in concert with H538 and a Mg2+ ion facilitate nucleophilic attack by an active site water molecule.     

Repair of DNA-containing pyrimidine dimers

Ultraviolet light-induced pyrimidine dimers in DNA are recognized and repaired by a number of unique cellular surveillance systems. The most direct biochemical mechanism responding to this kind of genotoxicity involves direct photoreversal by flavin enzymes that specifically monomerize pyrimidine:pyrimidine dimers monophotonically in the presence of visible light. Incision reactions are catalyzed by a combined pyrimidine dimer DNA-glycosylase:apyrimidinic endonuclease found in some highly UV-resistant organisms. At a higher level of complexity, Escherichia coli has a uvr DNA repair system comprising the UvrA, UvrB, and UvrC proteins responsible for incision. There are several preincision steps governed by this pathway, which includes an ATP-dependent UvrA dimerization reaction required for UvrAB nucleoprotein formation. This complex formation driven by ATP binding is associated with localized topological unwinding of DNA. This same protein complex can catalyze an ATPase-dependent 5'----3'-directed strand displacement of D-loop DNA or short single strands annealed to a single-stranded circular or linear DNA. This putative translocational process is arrested when damaged sites are encountered. The complex is now primed for dual incision catalyzed by UvrC. The remainder of the repair process involves UvrD (helicase II) and DNA polymerase I for a coordinately controlled excision-resynthesis step accompanied by UvrABC turnover. Furthermore, it is proposed that levels of repair proteins can be regulated by proteolysis. UvrB is converted to truncated UvrB* by a stress-induced protease that also acts at similar sites on the E. coli Ada protein. Although UvrB* can bind with UvrA to DNA, it cannot participate in helicase or incision reactions. It is also a DNA-dependent ATPase.     

The beta -hairpin motif of UvrB is essential for DNA binding, damage processing, and UvrC-mediated incisions.

UvrB plays a major role in recognition and processing of DNA lesions during nucleotide excision repair. The crystal structure of UvrB revealed a similar fold as found in monomeric DNA helicases. Homology modeling suggested that the beta-hairpin motif of UvrB might be involved in DNA binding (Theis, K., Chen, P. J., Skorvaga, M., Van Houten, B., and Kisker, C. (1999) EMBO J. 18, 6899-6907). To determine a role of the beta-hairpin of Bacillus caldotenax UvrB, we have constructed a deletion mutant, Deltabetah UvrB, which lacks residues Gln-97-Asp-112 of the beta-hairpin. Deltabetah UvrB does not form a stable UvrB-DNA pre-incision complex and is inactive in UvrABC-mediated incision. However, Deltabetah UvrB is able to bind to UvrA and form a complex with UvrA and damaged DNA, competing with wild type UvrB. In addition, Deltabetah UvrB shows wild type-like ATPase activity in complex with UvrA that is stimulated by damaged DNA. In contrast to wild type UvrB, the ATPase activity of mutant UvrB does not lead to a destabilization of the damaged duplex. These results indicate that the conserved beta-hairpin motif is a major factor in DNA binding.     

Crystal structure of Thermus thermophilus HB8 UvrB protein, a key enzyme of nucleotide excision repair

In the nucleotide excision repair system, UvrB plays a central role in damage recognition and DNA incision by interacting with UvrA and UvrC. We have determined the crystal structure of Thermus thermophilus HB8 UvrB at 1.9 A resolution. UvrB comprises four domains, two of which have an alpha/beta structure resembling the core domains of DNA and RNA helicases. Additionally, UvrB has an alpha-helical domain and a domain consisting of antiparallel beta-sheets (beta-domain). The sequence similarity suggests that the beta-domain interacts with UvrA. Based on the distribution of the conserved regions and the structure of the PcrA-DNA complex, a model for the UvrB-DNA complex is proposed.