The unstructured C-terminal extension of UvrD interacts with UvrB,but is dispensable for nucleotide excision repair

During nucleotide excision repair (NER) in bacteria the UvrC nuclease and the short oligonucleotide that contains the DNA lesion are removed from the post-incision complex by UvrD, a superfamily 1A helicase. Helicases are frequently regulated by interactions with partner proteins, and immunoprecipitation experiments have previously indicated that UvrD interacts with UvrB, a component of the post-incision complex. We examined this interaction using 2-hybrid analysis and surface plasmon resonance spectroscopy, and found that the N-terminal domain and the unstructured region at the C-terminus of UvrD interact with UvrB. We analysed the properties of a truncated UvrD protein that lacked the unstructured C-terminal region and found that it showed a diminished affinity for single-stranded DNA, but retained the ability to displace both UvrC and the lesion-containing oligonucleotide from a post-incision nucleotide excision repair complex. The interaction of the C-terminal region of UvrD with UvrB is therefore not an essential feature of the mechanism by which UvrD disassembles the post-incision complex during NER. In further experiments we showed that PcrA helicase from Bacillus stearothermophilus can also displace UvrC and the excised oligonucleotide from a post-incision NER complex, which supports the idea that PcrA performs a UvrD-like function during NER in Gram-positive organisms.     

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.     

Analyzing the handoff of DNA from UvrA to UvrB utilizing DNA-protein photoaffinity labeling

To better define the molecular architecture of nucleotide excision repair intermediates it is necessary to identify the specific domains of UvrA, UvrB, and UvrC that are in close proximity to DNA damage during the repair process. One key step of nucleotide excision repair that is poorly understood is the transfer of damaged DNA from UvrA to UvrB, prior to incision by UvrC. To study this transfer, we have utilized two types of arylazido-modified photoaffinity reagents that probe residues in the Uvr proteins that are closest to either the damaged or non-damaged strands. The damaged strand probes consisted of dNTP analogs linked to a terminal arylazido moiety. These analogs were incorporated into double-stranded DNA using DNA polymerase beta and functioned as both the damage site and the cross-linking reagent. The non-damaged strand probe contained an arylazido moiety coupled to a phosphorothioate-modified backbone of an oligonucleotide opposite the damaged strand, which contained an internal fluorescein adduct. Six site-directed mutants of Bacillus caldotenax UvrB located in different domains within the protein (Y96A, E99A, R123A, R183E, F249A, and D510A), and two domain deletions (Delta2 and Deltabeta-hairpin), were assayed. Data gleaned from these mutants suggest that the handoff of damaged DNA from UvrA to UvrB proceeds in a three-step process: 1) UvrA and UvrB bind to the damaged site, with UvrA in direct contact; 2) a transfer reaction with UvrB contacting mostly the non-damaged DNA strand; 3) lesion engagement by the damage recognition pocket of UvrB with concomitant release of UvrA.     

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.     

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.     

Cooperative damage recognition by UvrA and UvrB: identification of UvrA residues that mediate DNA binding

Nucleotide excision repair (NER) is responsible for the recognition and removal of numerous structurally unrelated DNA lesions. In prokaryotes, the proteins UvrA, UvrB and UvrC orchestrate the recognition and excision of aberrant lesions from DNA. Despite the progress we have made in understanding the NER pathway, it remains unclear how the UvrA dimer interacts with DNA to facilitate DNA damage recognition. The purpose of this study was to define amino acid residues in UvrA that provide binding energy to DNA. Based on conservation among approximately 300 UvrA sequences and 3D-modeling, two positively charged residues, Lys680 and Arg691, were predicted to be important for DNA binding. Mutagenesis and biochemical analysis of Bacillus caldontenax UvrA variant proteins containing site directed mutations at these residues demonstrate that Lys680 and Arg691 make a significant contribution toward the DNA binding affinity of UvrA. Replacing these side chains with alanine or negatively charged residues decreased UvrA binding 3-37-fold. Survival studies indicated that these mutant proteins complemented a WP2 uvrA(-) strain of bacteria 10-100% of WT UvrA levels. Further analysis by DNase I footprinting of the double UvrA mutant revealed that the UvrA DNA binding defects caused a slower rate of transfer of DNA to UvrB. Consequently, the mutants initiated the oligonucleotide incision assay nearly as well as WT UvrA thus explaining the observed mild phenotype in the survival assay. Based on our findings we propose a model of how UvrA binds to DNA.     

Stimulation of the UvrABC enzyme-catalyzed repair reactions by the UvrD protein (DNA helicase II).

An in vitro assay system was constructed using highly purified preparations of UvrA, UvrB, UvrC, UvrD proteins and DNA polymerase I, the objective being to analyse the role of UvrD protein in excision repair of UV-induced DNA damage. UvrABC enzyme-initiated repair synthesis was greatly enhanced by the addition of UvrD protein to the reaction mixture. Further analysis revealed that UvrD protein stimulated introduction of strand breaks in irradiated DNA by UvrABC enzyme but had no effect on the DNA polymerase I reaction. Thus, the site of action of UvrD protein is probably at the incision-excision step and not in later steps in excision repair.     

Identification of a chemical that inhibits the mycobacterial UvrABC complex in nucleotide excision repair

Bacterial DNA can be damaged by reactive nitrogen and oxygen intermediates (RNI and ROI) generated by host immunity, as well as by antibiotics that trigger bacterial production of ROI. Thus a pathogen's ability to repair its DNA may be important for persistent infection. A prominent role for nucleotide excision repair (NER) in disease caused by Mycobacterium tuberculosis (Mtb) was suggested by attenuation of uvrB-deficient Mtb in mice. However, it was unknown if Mtb's Uvr proteins could execute NER. Here we report that recombinant UvrA, UvrB, and UvrC from Mtb collectively bound and cleaved plasmid DNA exposed to ultraviolet (UV) irradiation or peroxynitrite. We used the DNA incision assay to test the mechanism of action of compounds identified in a high-throughput screen for their ability to delay recovery of M. smegmatis from UV irradiation. 2-(5-Amino-1,3,4-thiadiazol-2-ylbenzo[f]chromen-3-one) (ATBC) but not several closely related compounds inhibited cleavage of damaged DNA by UvrA, UvrB, and UvrC without intercalating in DNA and impaired recovery of M. smegmatis from UV irradiation. ATBC did not affect bacterial growth in the absence of UV exposure, nor did it exacerbate the growth defect of UV-irradiated mycobacteria that lacked uvrB. Thus, ATBC appears to be a cell-penetrant, selective inhibitor of mycobacterial NER. Chemical inhibitors of NER may facilitate studies of the role of NER in prokaryotic pathobiology.     

The role of the excision-repair enzymes in mutation-induction by cis-Pt(NH3)2Cl2.

Mutation induction by cis-Pt(NH3)2Cl2 (cisplatin) has been shown to be absent in E.coli strains carrying a deletion of the uvrB gene (1). This suggested that excision-repair, which is normally thought to be error-free, is involved in mutation induction with cisplatin. Here, the role of the excision repair enzymes UvrA, UvrB and UvrC is investigated using E.coli strains with different repair capacities. It is shown that cisplatin induced mutagenesis is dependent both on UvrA and UvrB but not on UvrC. Of the UvrB enzyme the N-terminal 113 aminoacids are sufficient for mutation induction by cisplatin.     

Interactions between UvrA and UvrB: the role of UvrB's domain 2 in nucleotide excision repair

Nucleotide excision repair (NER) is a highly conserved DNA repair mechanism present in all kingdoms of life. UvrB is a central component of the bacterial NER system, participating in damage recognition, strand excision and repair synthesis. None of the three presently available crystal structures of UvrB has defined the structure of domain 2, which is critical for the interaction with UvrA. We have solved the crystal structure of the UvrB Y96A variant, which reveals a new fold for domain 2 and identifies highly conserved residues located on its surface. These residues are restricted to the face of UvrB important for DNA binding and may be critical for the interaction of UvrB with UvrA. We have mutated these residues to study their role in the incision reaction, formation of the pre-incision complex, destabilization of short duplex regions in DNA, binding to UvrA and ATP hydrolysis. Based on the structural and biochemical data, we conclude that domain 2 is required for a productive UvrA-UvrB interaction, which is a pre-requisite for all subsequent steps in nucleotide excision repair.     

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.     

uvrC Gene Function in Excision Repair in Toluene-Treated Escherichia coli

We have examined the role of the uvrC gene in UV excision repair by studying incision, excision, repair synthesis, and DNA strand reformation in Escherichia coli mutants made permeable to nucleoside triphosphates by toluene treatment. After irradiation, incisions occur normally in uvrC cells in the presence of nicotinamide mononucleotide (NMN), a ligase-blocking agent, but cannot be detected otherwise. We conclude that repair incisions are followed by a ligation event in uvrC mutants, masking incision. However, a uvrC polA12 mutant accumulates incisions only slightly less efficiently than a polA12 strain without NMN. Excision of pyrimidine dimers is defective in uvrC mutants (polA(+) or polA12) irrespective of the presence or absence of NMN. DNA polymerase I-dependent, NMN-stimulated repair synthesis, which is demonstrable in wild-type cells, is absent in uvrC polA(+) cells, but the uvrC polA12 mutant exhibits a UV-specific, ATP-dependent repair synthesis like parental polA12 strains. A DNA polymerase I-mediated reformation of high-molecular-weight DNA takes place efficiently in uvrC polA(+) mutants after incision accumulation, and the uvrC polA12 mutant shows more reformation than the polA12 strain after incision. These results indicate that normal incision occurs in uvrC mutants, but there appears to be a defect in the excision of pyrimidine dimers, allowing resealing via ligation at the site of the incision. The lack of NMN-stimulated repair synthesis in uvrC polA(+) cells indicates that incision is not the only requirement for repair synthesis.     

A Structural Model for the Damage-sensing Complex in Bacterial Nucleotide Excision Repair

Nucleotide excision repair is distinguished from other DNA repair pathways by its ability to process a wide range of structurally unrelated DNA lesions. In bacteria, damage recognition is achieved by the UvrA·UvrB ensemble. Here, we report the structure of the complex between the interaction domains of UvrA and UvrB. These domains are necessary and sufficient for full-length UvrA and UvrB to associate and thereby form the DNA damage-sensing complex of bacterial nucleotide excision repair. The crystal structure and accompanying biochemical analyses suggest a model for the complete damage-sensing complex.Nucleotide excision repair is distinguished from other DNA repair pathways by its ability to process a diverse set of lesions. In bacteria, the initial steps are carried out by three proteins: UvrA, UvrB, and UvrC. The UvrA·UvrB complex conducts surveillance of DNA and recognizes damage. Having located a lesion, UvrA “loads” UvrB onto the DNA at the damaged sites and then dissociates. Damage searching, formation of the UvrB·DNA “preincision” complex, and dissociation of UvrA are regulated by ATP (1). UvrB subsequently recruits the endonuclease UvrC, which catalyzes incisions on either side of the lesion (2, 3). Following incision, UvrC and the damage-containing oligonucleotide are removed by UvrD (helicase II), whereas UvrB remains bound to the gapped DNA and recruits DNA polymerase I for repair synthesis. Sealing of the single-stranded nick completes the repair process and restores the original DNA sequence (4).Since its discovery more than 40 years ago, bacterial nucleotide excision repair has been extensively studied, resulting in a large body of work that describes the protein components and the details of how they operate. Notwithstanding the trove of genetic and biochemical data, several key questions remain unanswered. For example, how does the same set of proteins handle a diverse set of lesions while maintaining specificity? How do UvrA and UvrB cooperate during damage recognition, and what is the precise role of ATP? Ongoing studies in the field, including those described below, aim to address these issues.Recently, we reported the structure of Geobacillus stearothermophilus UvrA and the identification of binding sites for DNA and UvrB (5). We also established that the identified UvrB-binding domain is necessary and sufficient to mediate the UvrA-UvrB interaction and that the isolated interaction domains of UvrA (5) and UvrB (6) bind to each other in solution.To understand the interaction between UvrA and UvrB, we have determined the crystal structure of the complex between the two isolated interaction domains. The structure revealed that UvrA-UvrB interaction interface is largely polar, mediated by several highly conserved charged residues. Site-directed mutagenesis and biochemical characterization of the mutant proteins confirmed the importance of the observed interactions. Based on the interaction domain complex structure, we have constructed a structural model for the full-length UvrA·UvrB ensemble and propose two models for lesion recognition that will serve as a basis for future experiments.     

A Physical Interaction of UvrD with Nucleotide Excision Repair Protein UvrB

The dual-incision nature of the reaction of UV-irradiated DNA catalyzed by the UvrABC complex potentially leads to excision of a damaged fragment. However, neither fragment release under nondenaturing conditions nor the UvrBC proteins are turned over. The addition of the UvrD protein to the incised DNA-UvrBC complex results in excision of the incised damaged strand and in the turnover of the UvrC protein. In an effort to better understand the involvement of UvrD in the excision step, immunoprecipitation was used to detect interacting proteins with UvrD in the DNA repair. In this communication, it is shown that UvrA and UvrB are precipitated with UvrD in solution but the UvrAB complex is not. In the incision complex, UvrB could be precipitated and the preincubation of UvrD with UvrB revealed an inhibitory effect on the turnover of the incision complex. These data imply that UvrB in the incision complex seems to recruit UvrD to the 3 incised site of the incised strand by protein-protein interaction and to allow initiation of unwinding by UvrD from the resulting nick in a 3 to 5 direction.     

Dynamics of the UvrABC nucleotide excision repair proteins analyzed by fluorescence resonance energy transfer

UvrB plays a key role in bacterial nucleotide excision repair. It is the ultimate damage-binding protein that interacts with both UvrA and UvrC. The oligomeric state of UvrB and the UvrAB complex have been subject of debate for a long time. Using fluorescence resonance energy transfer (FRET) between GFP and YFP fused to the C-terminal end of Escherichia coli UvrB, we unambiguously show that in solution two UvrB subunits bind to UvrA, most likely as part of a UvrA2B2 complex. This complex is most stable when both UvrA and UvrB are in the ATP-bound form. Analysis of a truncated form of UvrB shows that binding to UvrA promotes dimerization of the two C-terminal domain 4 regions of UvrB. The presence of undamaged DNA leads to dissociation of the UvrA2B2 complex, but when the ATPase site of UvrB is inactivated, the complex is trapped on the DNA. When the complex is bound to a damaged site, FRET between the two UvrB subunits could still be detected, but only as long as UvrA remains associated. Dissociation of UvrA from the damage-bound UvrB dimer leads to the reduction of the magnitude of the FRET signal, indicating that the domain 4 regions no longer interact. We propose that the UvrA-induced dimerization of the domain 4 regions serves to shield these domains from premature UvrC binding. Only after specific binding of the UvrB dimer to a damaged site and subsequent release of UvrA is the contact between the domain 4 regions broken, allowing recruitment of UvrC and subsequent incisions.     

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.     

Oligomerization of the UvrB nucleotide excision repair protein of Escherichia coli.

A combination of hydrodynamic and cross-linking studies were used to investigate self-assembly of the Escherichia coli DNA repair protein UvrB. Though the procession of steps leading to incision of DNA at sites flanking damage requires that UvrB engage in an ordered series of complexes, successively with UvrA, DNA, and UvrC, the potential for self-association had not yet been reported. Gel permeation chromatography, nondenaturing polyacrylamide gel electrophoresis, and chemical cross-linking results combine to show that UvrB stably assembles as a dimer in solution at concentrations in the low micromolar range. Smaller populations of higher order oligomeric species are also observed. Unlike the dimerization of UvrA, an initial step promoted by ATP binding, the monomer-dimer equilibrium for UvrB is unaffected by the presence of ATP. The insensitivity of cross-linking efficiency to a 10-fold variation in salt concentration further suggests that UvrB self-assembly is driven largely by hydrophobic interactions. Self-assembly is significantly weakened by proteolytic removal of the carboxyl terminus of the protein (generating UvrB*), a domain also known to be required for the interaction with UvrC leading to the initial incision of damaged DNA. This suggests that the C terminus may be a multifunctional binding domain, with specificity regulated by protein conformation.     

Structure of the uvrB gene of Escherichia coli. Homology with other DNA repair enzymes and characterization of the uvrB5 mutation.

The complete nucleotide sequence of the Escherichia coli uvrB gene has been determined. The coding region of the uvrB gene consists of 2019 nucleotides which direct the synthesis of a 673 amino-acid long polypeptide with a calculated molecular weight of 76.614 daltons. Comparison of the UvrB protein sequence to other known DNA repair enzymes revealed that 2 domains of the UvrB protein (domain I = 6 amino acids, domain II = 14 amino acids) are also present in the protein sequence of the uvrC gene. We show that the structural homologies between UvrB and UvrC are as well reflected by the cross-reactivity of anti-uvrB and anti-uvrC antibodies with UvrC and UvrB protein respectively. In the N-terminal part of UvrB, domain III (17 amino acids) shows a strong homology with one part of the AlkA gene product. Adjacent to domain III, an ATP binding site consensus sequence is found in domain IV. The uvrB5 mutant gene from strain AB1885 has been cloned on plasmid pBL01. We show that the uvrB5 mutation is due to a point deletion of a CG basepair and results in the synthesis of an 18 kD protein composed of the 113 N-terminal amino acids of the wild type uvrB gene and a 43 amino acid long tail coded in the -1 frame.