Strand opening by the UvrA(2)B complex allows dynamic recognition of DNA damage

Helicases required for nucleotide excision repair: structure, function and mechanism

Nucleotide excision repair (NER) is a major DNA repair pathway conserved from bacteria to humans. Various DNA helicases, a group of enzymes capable of separating DNA duplex into two strands through ATP binding and hydrolysis, are required by NER to unwind the DNA duplex around the lesion to create a repair bubble and for damage verification and removal. In prokaryotes, UvrB helicase is required for repair bubble formation and damage verification, while UvrD helicase is responsible for the removal of the excised damage containing single-strand (ss) DNA fragment. In addition, UvrD facilitates transcription-coupled repair (TCR) by backtracking RNA polymerase stalled at the lesion. In eukaryotes, two helicases XPB and XPD from the transcription factor TFIIH complex fulfill the helicase requirements of NER. Interestingly, homologs of all these four helicases UvrB, UvrD, XPB, and XPD have been identified in archaea. This review summarizes our current understanding about the structure, function, and mechanism of these four helicases.

Crucial role and mechanism of transcription-coupled DNA repair in bacteria

Transcription-coupled DNA repair (TCR) is presumed to be a minor sub-pathway of nucleotide excision repair (NER) in bacteria. Global genomic repair is thought to perform the bulk of repair independently of transcription. TCR is also believed to be mediated exclusively by Mfd-a DNA translocase of a marginal NER phenotype^1-3. Here we combined in cellulo cross-linking mass spectrometry with structural, biochemical and genetic approaches to map the interactions within the TCR complex (TCRC) and to determine the actual sequence of events that leads to NER in vivo. We show that RNA polymerase (RNAP) serves as the primary sensor of DNA damage and acts as a platform for the recruitment of NER enzymes. UvrA and UvrD associate with RNAP continuously, forming a surveillance pre-TCRC. In response to DNA damage, pre-TCRC recruits a second UvrD monomer to form a helicase-competent UvrD dimer that promotes backtracking of the TCRC. The weakening of UvrD-RNAP interactions renders cells sensitive to genotoxic stress. TCRC then recruits a second UvrA molecule and UvrB to initiate the repair process. Contrary to the conventional view, we show that TCR accounts for the vast majority of chromosomal repair events; that is, TCR thoroughly dominates over global genomic repair. We also show that TCR is largely independent of Mfd. We propose that Mfd has an indirect role in this process: it participates in removing obstructive RNAPs in front of TCRCs and also in recovering TCRCs from backtracking after repair has been completed.

In vitro reconstitution of an efficient nucleotide excision repair system using mesophilic enzymes from Deinococcus radiodurans

Nucleotide excision repair (NER) is a universal and versatile DNA repair pathway, capable of removing a very wide range of lesions, including UV-induced pyrimidine dimers and bulky adducts. In bacteria, NER involves the sequential action of the UvrA, UvrB and UvrC proteins to release a short 12- or 13-nucleotide DNA fragment containing the damaged site. Although bacterial NER has been the focus of numerous studies over the past 40 years, a number of key questions remain unanswered regarding the mechanisms underlying DNA damage recognition by UvrA, the handoff to UvrB and the site-specific incision by UvrC. In the present study, we have successfully reconstituted in vitro a robust NER system using the UvrABC proteins from the radiation resistant bacterium, Deinococcus radiodurans. We have investigated the influence of various parameters, including temperature, salt, protein and ATP concentrations, protein purity and metal cations, on the dual incision by UvrABC, so as to find the optimal conditions for the efficient release of the short lesion-containing oligonucleotide. This newly developed assay relying on the use of an original, doubly-labelled DNA substrate has allowed us to probe the kinetics of repair on different DNA substrates and to determine the order and precise sites of incisions on the 5′ and 3′ sides of the lesion. This new assay thus constitutes a valuable tool to further decipher the NER pathway in bacteria.

Reconstitution of D radiodurans nucleotide excision repair provides insights into the kinetics of repair on different DNA substrates and determines the order and precise sites of incisions on the 5’ and 3’ sides of the lesion.

Real-time investigation of the roles of ATP hydrolysis by UvrA and UvrB during DNA damage recognition in nucleotide excision repair

Nucleotide excision repair (NER) stands out among other DNA repair systems for its ability to process a diverse set of unrelated DNA lesions. In bacteria, NER damage detection is orchestrated by the UvrA and UvrB proteins, which form the UvrA₂-UvrB₂ (UvrAB) damage sensing complex. The highly versatile damage recognition is accomplished in two ATP-dependent steps. In the first step, the UvrAB complex samples the DNA in search of lesion. Subsequently, the presence of DNA damage is verified within the UvrB-DNA complex after UvrA has dissociated. Although the mechanism of bacterial NER damage detection has been extensively investigated, the role of ATP binding and hydrolysis by UvrA and UvrB during this process remains incompletely understood. Here, we report a pre-steady state kinetics Förster resonance energy transfer (FRET) study of the real-time interaction between UvrA, UvrB, and damaged DNA during lesion detection. By using UvrA and UvrB mutants harboring site-specific mutations in the ATP binding sites, we show for the first time that the dissociation of UvrA from the UvrAB-DNA complex does not require ATP hydrolysis by UvrB. We find that ATP hydrolysis by UvrA is not essential, but somehow facilitates the formation of UvrB-DNA complex, with ATP hydrolysis at the proximal site of UvrA playing a more critical role. Consistent with previous reports, our results indicated that the ATPase activity of UvrB is essential for the formation of UvrB-DNA complex but is not required for the binding of the UvrAB complex to DNA.

The mechanisms underlying antigenic variation and maintenance of genomic integrity in Mycoplasma pneumoniae and Mycoplasma genitalium

Mycoplasma pneumoniae and Mycoplasma genitalium are important causative agents of infections in humans. Like all other mycoplasmas, these species possess genomes that are significantly smaller than that of other prokaryotes. Moreover, both organisms possess an exceptionally compact set of DNA recombination and repair-associated genes. These genes, however, are sufficient to generate antigenic variation by means of homologous recombination between specific repetitive genomic elements. At the same time, these mycoplasmas have likely evolved strategies to maintain the stability and integrity of their 'minimal' genomes. Previous studies have indicated that there are considerable differences between mycoplasmas and other bacteria in the composition of their DNA recombination and repair machinery. However, the complete repertoire of activities executed by the putative recombination and repair enzymes encoded by Mycoplasma species is not yet fully understood. In this paper, we review the current knowledge on the proteins that likely form part of the DNA repair and recombination pathways of two of the most clinically relevant Mycoplasma species, M. pneumoniae and M. genitalium. The characterization of these proteins will help to define the minimal enzymatic requirements for creating bacterial genetic diversity (antigenic variation) on the one hand, while maintaining genomic integrity on the other.

Mechanism of DNA Lesion Homing and Recognition by the Uvr Nucleotide Excision Repair System

Nucleotide excision repair (NER) is an essential DNA repair system distinguished from other such systems by its extraordinary versatility. NER removes a wide variety of structurally dissimilar lesions having only their bulkiness in common. NER can also repair several less bulky nucleobase lesions, such as 8-oxoguanine. Thus, how a single DNA repair system distinguishes such a diverse array of structurally divergent lesions from undamaged DNA has been one of the great unsolved mysteries in the field of genome maintenance. Here we employ a synthetic crystallography approach to obtain crystal structures of the pivotal NER enzyme UvrB in complex with duplex DNA, trapped at the stage of lesion-recognition. These structures coupled with biochemical studies suggest that UvrB integrates the ATPase-dependent helicase/translocase and lesion-recognition activities. Our work also conclusively establishes the identity of the lesion-containing strand and provides a compelling insight to how UvrB recognizes a diverse array of DNA lesions.

Investigation of the probable homo-dimer model of the Xeroderma pigmentosum complementation group A (XPA) protein to represent the DNA-binding core

The Xeroderma pigmentosum complementation group A (XPA) protein functions as a primary damage verifier and as a scaffold protein in nucleotide excision repair (NER) in all higher organisms. New evidence of XPA's existence as a dimer and the redefinition of its DNA-binding domain (DBD) raises new questions regarding the stability and functional position of XPA in NER. Here, we have investigated XPA's dimeric status with respect to its previously defined DBD (XPA_98-219) as well as with its redefined DBD (XPA_98-239). We studied the stability of XPA_98-210 and XPA_98-239 homo-dimer systems using all-atom molecular dynamics simulation, and we have also characterized the protein-protein interactions (PPI) of these two homo-dimeric forms of XPA. After conducting the root mean square deviation (RMSD) analyses, it was observed that the XPA_98-239 homo-dimer has better stability than XPA_98-210. It was also found that XPA_98-239 has a larger number of hydrogen bonds, salt bridges, and hydrophobic interactions than the XPA_98-210 homo-dimer. We further found that Lys, Glu, Gln, Asn, and Arg residues shared the major contribution toward the intermolecular interactions in XPA homo-dimers. The binding free energy (BFE) analysis, which used the molecular mechanics Poisson-Boltzmann method (MM-PBSA) and the generalized Born and surface area continuum solvation model (GBSA) for both XPA homo-dimers, also substantiated the positive result in favor of the stability of the XPA_98-239 homo-dimer. Communicated by Ramaswamy H. Sarma.

Mycobacterium tuberculosis UvrB Is a Robust DNA-Stimulated ATPase That Also Possesses Structure-Specific ATP-Dependent DNA Helicase Activity

Much is known about the Escherichia coli nucleotide excision repair (NER) pathway; however, very little is understood about the proteins involved and the molecular mechanism of NER in mycobacteria. In this study, we show that Mycobacterium tuberculosis UvrB (MtUvrB), which exists in solution as a monomer, binds to DNA in a structure-dependent manner. A systematic examination of MtUvrB substrate specificity reveals that it associates preferentially with single-stranded DNA, duplexes with 3' or 5' overhangs, and linear duplex DNA with splayed arms. Whereas E. coli UvrB (EcUvrB) binds weakly to undamaged DNA and has no ATPase activity, MtUvrB possesses intrinsic ATPase activity that is greatly stimulated by both single- and double-stranded DNA. Strikingly, we found that MtUvrB, but not EcUvrB, possesses the DNA unwinding activity characteristic of an ATP-dependent DNA helicase. The helicase activity of MtUvrB proceeds in the 3' to 5' direction and is strongly modulated by a nontranslocating 5' single-stranded tail, indicating that in addition to the translocating strand it also interacts with the 5' end of the substrate. The fraction of DNA unwound by MtUvrB decreases significantly as the length of the duplex increases: it fails to unwind duplexes longer than 70 bp. These results, on one hand, reveal significant mechanistic differences between MtUvrB and EcUvrB and, on the other, support an alternative role for UvrB in the processing of key DNA replication intermediates. Altogether, our findings provide insights into the catalytic functions of UvrB and lay the foundation for further understanding of the NER pathway in M. tuberculosis.

Conservation and Divergence in Nucleotide Excision Repair Lesion Recognition

Nucleotide excision repair is an important and highly conserved DNA repair mechanism with an exceptionally large range of chemically and structurally unrelated targets. Lesion verification is believed to be achieved by the helicases UvrB and XPD in the prokaryotic and eukaryotic processes, respectively. Using single molecule atomic force microscopy analyses, we demonstrate that UvrB and XPD are able to load onto DNA and pursue lesion verification in the absence of the initial lesion detection proteins. Interestingly, our studies show different lesion recognition strategies for the two functionally homologous helicases, as apparent from their distinct DNA strand preferences, which can be rationalized from the different structural features and interactions with other nucleotide excision repair protein factors of the two enzymes.

Dissociation Dynamics of XPC-RAD23B from Damaged DNA Is a Determining Factor of NER Efficiency

XPC-RAD23B (XPC) plays a critical role in human nucleotide excision repair (hNER) as this complex recognizes DNA adducts to initiate NER. To determine the mutagenic potential of structurally different bulky DNA damages, various studies have been conducted to define the correlation of XPC-DNA damage equilibrium binding affinity with NER efficiency. However, little is known about the effects of XPC-DNA damage recognition kinetics on hNER. Although association of XPC is important, our current work shows that the XPC-DNA dissociation rate also plays a pivotal role in achieving NER efficiency. We characterized for the first time the binding of XPC to mono- versus di-AAF-modified sequences by using the real time monitoring surface plasmon resonance technique. Strikingly, the half-life (t1/2 or the retention time of XPC in association with damaged DNA) shares an inverse relationship with NER efficiency. This is particularly true when XPC remained bound to clustered adducts for a much longer period of time as compared to mono-adducts. Our results suggest that XPC dissociation from the damage site could become a rate-limiting step in NER of certain types of DNA adducts, leading to repression of NER.

A dynamic checkpoint in oxidative lesion discrimination by formamidopyrimidine-DNA glycosylase

In contrast to proteins recognizing small-molecule ligands, DNA-dependent enzymes cannot rely solely on interactions in the substrate-binding centre to achieve their exquisite specificity. It is widely believed that substrate recognition by such enzymes involves a series of conformational changes in the enzyme-DNA complex with sequential gates favoring cognate DNA and rejecting nonsubstrates. However, direct evidence for such mechanism is limited to a few systems. We report that discrimination between the oxidative DNA lesion, 8-oxoguanine (oxoG) and its normal counterpart, guanine, by the repair enzyme, formamidopyrimidine-DNA glycosylase (Fpg), likely involves multiple gates. Fpg uses an aromatic wedge to open the Watson-Crick base pair and everts the lesion into its active site. We used molecular dynamics simulations to explore the eversion free energy landscapes of oxoG and G by Fpg, focusing on structural and energetic details of oxoG recognition. The resulting energy profiles, supported by biochemical analysis of site-directed mutants disturbing the interactions along the proposed path, show that Fpg selectively facilitates eversion of oxoG by stabilizing several intermediate states, helping the rapidly sliding enzyme avoid full extrusion of every encountered base for interrogation. Lesion recognition through multiple gating intermediates may be a common theme in DNA repair enzymes.

Protein Recognition in Drug-Induced DNA Alkylation: When the Moonlight Protein GAPDH Meets S23906-1/DNA Minor Groove Adducts

DNA alkylating drugs have been used in clinics for more than seventy years. The diversity of their mechanism of action (major/minor groove; mono-/bis-alkylation; intra-/inter-strand crosslinks; DNA stabilization/destabilization, etc.) has undoubtedly major consequences on the cellular response to treatment. The aim of this review is to highlight the variety of established protein recognition of DNA adducts to then particularly focus on glyceraldehyde-3-phosphate dehydrogenase (GAPDH) function in DNA adduct interaction with illustration using original experiments performed with S23906-1/DNA adduct. The introduction of this review is a state of the art of protein/DNA adducts recognition, depending on the major or minor groove orientation of the DNA bonding as well as on the molecular consequences in terms of double-stranded DNA maintenance. It reviews the implication of proteins from both DNA repair, transcription, replication and chromatin maintenance in selective DNA adduct recognition. The main section of the manuscript is focusing on the implication of the moonlighting protein GAPDH in DNA adduct recognition with the model of the peculiar DNA minor groove alkylating and destabilizing drug S23906-1. The mechanism of action of S23906-1 alkylating drug and the large variety of GAPDH cellular functions are presented prior to focus on GAPDH direct binding to S23906-1 adducts.

Repair of hydantoin lesions and their amine adducts in DNA by base and nucleotide excision repair

An important feature of the common DNA oxidation product 8-oxo-7,8-dihydroguanine (OG) is its susceptibility to further oxidation that produces guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp) lesions. In the presence of amines, G or OG oxidation produces hydantoin amine adducts. Such adducts may form in cells via interception of oxidized intermediates by protein-derived nucleophiles or naturally occurring amines that are tightly associated with DNA. Gh and Sp are known to be substrates for base excision repair (BER) glycosylases; however, large Sp-amine adducts would be expected to be more readily repaired by nucleotide excision repair (NER). A series of Sp adducts differing in the size of the attached amine were synthesized to evaluate the relative processing by NER and BER. The UvrABC complex excised Gh, Sp, and the Sp-amine adducts from duplex DNA, with the greatest efficiency for the largest Sp-amine adducts. The affinity of UvrA for all of the lesion duplexes was found to be similar, whereas the efficiency of UvrB loading tracked with the efficiency of UvrABC excision. In contrast, the human BER glycosylase NEIL1 exhibited robust activity for all Sp-amine adducts irrespective of size. These studies suggest that both NER and BER pathways mediate repair of a diverse set of hydantoin lesions in cells.

Structural and thermodynamic insight into Escherichia coli UvrABC-mediated incision of cluster diacetylaminofluorene adducts on the NarI sequence

Cluster DNA damage refers to two or more lesions in a single turn of the DNA helix. Such clustering may occur with bulky DNA lesions, which may be responsible for their sequence-dependent repair and mutational outcomes. Here we prepared three 16-mer cluster duplexes in which two fluoroacetylaminofluorene adducts (dG-FAAF) are separated by zero, one, and two nucleotides in the Escherichia coli NarI mutational hot spot (5'-CTCTCG1G2CG3CCATCAC-3'): 5'-CG1*G2*CG3CC-3', 5'-CG1G2*CG3*CC-3', and 5'-CG1*G2CG3*CC-3' (G* = dG-FAAF), respectively. We conducted spectroscopic, thermodynamic, and molecular dynamics studies of these di-FAAF duplexes, and the results were compared with those of the corresponding mono-FAAF adducts in the same NarI sequence [Jain, V., et al. (2012) Nucleic Acids Res. 40, 3939-3951]. Our nucleotide excision repair results showed the diadducts were more reparable than the corresponding monoadducts. Moreover, we observed dramatic flanking base sequence effects on their repair efficiency in the following order: NarI-G2G3 > NarI-G1G3 > NarI-G1G2. The nuclear magnetic resonance, circular dichroism, ultraviolet melting, and molecular dynamics simulation results revealed that in contrast to the monoadducts, diadducts produced a synergistic effect on duplex destabilization. In addition, dG-FAAF at G2G3 and G1G3 destacks the neighboring bases, with greater destabilization occurring with the former. Overall, the results indicate the importance of base stacking and related thermal and thermodynamic destabilization in the repair of bulky cluster arylamine DNA adducts.

Real-time single-molecule imaging reveals a direct interaction between UvrC and UvrB on DNA tightropes

Nucleotide excision DNA repair is mechanistically conserved across all kingdoms of life. In prokaryotes, this multi-enzyme process requires six proteins: UvrA–D, DNA polymerase I and DNA ligase. To examine how UvrC locates the UvrB–DNA pre-incision complex at a site of damage, we have labeled UvrB and UvrC with different colored quantum dots and quantitatively observed their interactions with DNA tightropes under a variety of solution conditions using oblique angle fluorescence imaging. Alone, UvrC predominantly interacts statically with DNA at low salt. Surprisingly, however, UvrC and UvrB together in solution bind to form the previously unseen UvrBC complex on duplex DNA. This UvrBC complex is highly motile and engages in unbiased one-dimensional diffusion. To test whether UvrB makes direct contact with the DNA in the UvrBC–DNA complex, we investigated three UvrB mutants: Y96A, a β-hairpin deletion and D338N. These mutants affected the motile properties of the UvrBC complex, indicating that UvrB is in intimate contact with the DNA when bound to UvrC. Given the in vivo excess of UvrB and the abundance of UvrBC in our experiments, this newly identified complex is likely to be the predominant form of UvrC in the cell.

Prokaryotic nucleotide excision repair

Nucleotide excision repair (NER) has allowed bacteria to flourish in many different niches around the globe that inflict harsh environmental damage to their genetic material. NER is remarkable because of its diverse substrate repertoire, which differs greatly in chemical composition and structure. Recent advances in structural biology and single-molecule studies have given great insight into the structure and function of NER components. This ensemble of proteins orchestrates faithful removal of toxic DNA lesions through a multistep process. The damaged nucleotide is recognized by dynamic probing of the DNA structure that is then verified and marked for dual incisions followed by excision of the damage and surrounding nucleotides. The opposite DNA strand serves as a template for repair, which is completed after resynthesis and ligation.

Unusual sequence effects on nucleotide excision repair of arylamine lesions: DNA bending/distortion as a primary recognition factor

The environmental arylamine mutagens are implicated in the etiology of various sporadic human cancers. Arylamine-modified dG lesions were studied in two fully paired 11-mer duplexes with a -G*CN- sequence context, in which G* is a C8-substituted dG adduct derived from fluorinated analogs of 4-aminobiphenyl (FABP), 2-aminofluorene (FAF) or 2-acetylaminofluorene (FAAF), and N is either dA or dT. The FABP and FAF lesions exist in a simple mixture of 'stacked' (S) and 'B-type' (B) conformers, whereas the N-acetylated FAAF also samples a 'wedge' (W) conformer. FAAF is repaired three to four times more efficiently than FABP and FAF. A simple A- to -T polarity swap in the G*CA/G*CT transition produced a dramatic increase in syn-conformation and resulted in 2- to 3-fold lower nucleotide excision repair (NER) efficiencies in Escherichia coli. These results indicate that lesion-induced DNA bending/thermodynamic destabilization is an important DNA damage recognition factor, more so than the local S/B-conformational heterogeneity that was observed previously for FAF and FAAF in certain sequence contexts. This work represents a novel 3'-next flanking sequence effect as a unique NER factor for bulky arylamine lesions in E. coli.

Surviving the sun: repair and bypass of DNA UV lesions

Structural studies of UV-induced lesions and their complexes with repair proteins reveal an intrinsic flexibility of DNA at lesion sites. Reduced DNA rigidity stems primarily from the loss of base stacking, which may manifest as bending, unwinding, base unstacking, or flipping out. The intrinsic flexibility at UV lesions allows efficient initial lesion recognition within a pool of millions to billions of normal DNA base pairs. To bypass the damaged site by translesion synthesis, the specialized DNA polymerase η acts like a molecular "splint" and reinforces B-form DNA by numerous protein-phosphate interactions. Photolyases and glycosylases that specifically repair UV lesions interact directly with UV lesions in bent DNA via surface complementation. UvrA and UvrB, which recognize a variety of lesions in the bacterial nucleotide excision repair pathway, appear to exploit hysteresis exhibited by DNA lesions and conduct an ATP-dependent stress test to distort and separate DNA strands. Similar stress tests are likely conducted in eukaryotic nucleotide excision repair.

Conformational and thermodynamic properties modulate the nucleotide excision repair of 2-aminofluorene and 2-acetylaminofluorene dG adducts in the NarI sequence

Nucleotide excision repair (NER) is a major repair pathway that recognizes and corrects various lesions in cellular DNA. We hypothesize that damage recognition is an initial step in NER that senses conformational anomalies in the DNA caused by lesions. We prepared three DNA duplexes containing the carcinogen adduct N-(2'-deoxyguanosin-8-yl)-7-fluoro-2-acetylaminofluorene (FAAF) at G(1), G(2) or G(3) of NarI sequence (5'-CCG(1)G(2)CG(3)CC-3'). Our (19)F-NMR/ICD results showed that FAAF at G(1) and G(3) prefer syn S- and W-conformers, whereas anti B-conformer was predominant for G(2). We found that the repair of FAAF occurs in a conformation-specific manner, i.e. the highly S/W-conformeric G(3) and -G(1) duplexes incised more efficiently than the B-type G(2) duplex (G(3)∼G(1)> G(2)). The melting and thermodynamic data indicate that the S- and W-conformers produce greater DNA distortion and thermodynamic destabilization. The N-deacetylated N-(2'-deoxyguanosin-8-yl)-7-fluoro-2-aminofluorene (FAF) adducts in the same NarI sequence are repaired 2- to 3-fold less than FAAF: however, the incision efficiency was in order of G(2)∼G(1)> G(3), a reverse trend of the FAAF case. We have envisioned the so-called N-acetyl factor as it could raise conformational barriers of FAAF versus FAF. The present results provide valuable conformational insight into the sequence-dependent UvrABC incisions of the bulky aminofluorene DNA adducts.

Role of the two ATPase domains of Escherichia coli UvrA in binding non-bulky DNA lesions and interaction with UvrB

The UvrA protein is the initial DNA damage-sensing protein in bacterial nucleotide excision repair and detects a wide variety of structurally unrelated lesions. After initial recognition of DNA damage, UvrA loads the UvrB protein onto the DNA. This protein then verifies the presence of a lesion, after which UvrA is released from the DNA. UvrA contains two ATPase domains, both belonging to the ABC ATPase superfamily. We have determined the activities of two mutants, in which a single domain was deactivated. Inactivation of either one ATPase domain in Escherichia coli UvrA results in a complete loss of ATPase activity, indicating that both domains function in a cooperative way. We could show that this ATPase activity is not required for the recognition of bulky lesions by UvrA, but it does promote the specific binding to the less distorting cyclobutane-pyrimidine dimer (CPD). The two ATPase mutants also show a difference in UvrB-loading, depending on the length of the DNA substrate. The ATPase domain I mutant was capable of loading UvrB on a lesion in a 50 bp fragment, but this loading was reduced on a longer substrate. For the ATPase domain II mutant the opposite was found: UvrB could not be loaded on a 50 bp substrate, but this loading was rescued when the length of the fragment was increased. This differential loading of UvrB by the two ATPase mutants could be related to different interactions between the UvrA and UvrB subunits.

DNA-Destabilizing Agents as an Alternative Approach for Targeting DNA: Mechanisms of Action and Cellular Consequences

DNA targeting drugs represent a large proportion of the actual anticancer drug pharmacopeia, both in terms of drug brands and prescription volumes. Small DNA-interacting molecules share the ability of certain proteins to change the DNA helix's overall organization and geometrical orientation via tilt, roll, twist, slip, and flip effects. In this ocean of DNA-interacting compounds, most stabilize both DNA strands and very few display helix-destabilizing properties. These types of DNA-destabilizing effect are observed with certain mono- or bis-intercalators and DNA alkylating agents (some of which have been or are being developed as cancer drugs). The formation of locally destabilized DNA portions could interfere with protein/DNA recognition and potentially affect several crucial cellular processes, such as DNA repair, replication, and transcription. The present paper describes the molecular basis of DNA destabilization, the cellular impact on protein recognition, and DNA repair processes and the latter's relationships with antitumour efficacy.

Revisiting plus-strand DNA synthesis in retroviruses and long terminal repeat retrotransposons: dynamics of enzyme: substrate interactions

Although polypurine tract (PPT)-primed initiation of plus-strand DNA synthesis in retroviruses and LTR-containing retrotransposons can be accurately duplicated, the molecular details underlying this concerted series of events remain largely unknown. Importantly, the PPT 3' terminus must be accommodated by ribonuclease H (RNase H) and DNA polymerase catalytic centers situated at either terminus of the cognate reverse transcriptase (RT), and in the case of the HIV-1 enzyme, ∼70Å apart. Communication between RT and the RNA/DNA hybrid therefore appears necessary to promote these events. The crystal structure of the HIV-1 RT/PPT complex, while informative, positions the RNase H active site several bases pairs from the PPT/U3 junction, and thus provides limited information on cleavage specificity. To fill the gap between biochemical and crystallographic approaches, we review a multidisciplinary approach combining chemical probing, mass spectrometry, NMR spectroscopy and single molecule spectroscopy. Our studies also indicate that nonnucleoside RT inhibitors affect enzyme orientation, suggesting initiation of plus-strand DNA synthesis as a potential therapeutic target.

DNA wrapping is required for DNA damage recognition in the Escherichia coli DNA nucleotide excision repair pathway

Localized DNA melting may provide a general strategy for recognition of the wide array of chemically and structurally diverse DNA lesions repaired by the nucleotide excision repair (NER) pathway. However, it is not clear what causes such DNA melting and how it is driven. Here, we show a DNA wrapping-melting model supported by results from dynamic monitoring of the key DNA-protein and protein-protein interactions involved in the early stages of the Escherichia coli NER process. Using an analytical technique involving capillary electrophoresis coupled with laser-induced fluorescence polarization, which combines a mobility shift assay with conformational analysis, we demonstrate that DNA wrapping around UvrB, mediated by UvrA, is an early event in the damage-recognition process during E. coli NER. DNA wrapping of UvrB was confirmed by Förster resonance energy transfer and fluorescence lifetime measurements. This wrapping did not occur with readily denaturable damaged DNA substrates ("bubble" DNA), suggesting that DNA wrapping of UvrB plays an important role in the induction of DNA melting around the damage site. Analysis of DNA wrapping of mutant UvrB Y96A further suggests that a cooperative interaction between DNA wrapping of UvrA(2)B and contact of the beta-hairpin of UvrB with the bulky damage moiety may be involved in the local DNA melting at the damage site.

Dual role of NER in mutagenesis in Pseudomonas putida

Nucleotide excision repair (NER) is one of the most important repair systems which counteracts different forms of DNA damage either induced by various chemicals or irradiation. At the same time, less is known about the functions of NER in repair of DNA that is not exposed to exogenous DNA-damaging agents. We have investigated the role of NER in mutagenesis in Pseudomonas putida. The genome of this organism contains two uvrA genes, uvrA and uvrA2. Genetic studies on the effects of uvrA, uvrA2, uvrB and UvrC in mutagenic processes revealed that all of these genes are responsible for the repair of UV-induced DNA damage in P. putida. However, uvrA plays more important role in this process than uvrA2 since the deletion of uvrA2 gene had an effect on the UV-tolerance of bacteria only in the case when uvrA was also inactivated. Interestingly, the lack of functional uvrB, uvrC or uvrA2 gene reduced the frequency of stationary-phase mutations. The contribution of uvrA2, uvrB and uvrC to the mutagenesis appeared to be most significant in the case of 1-bp deletions whose emergence is dependent on error-prone DNA polymerase Pol IV. These data imply that NER has a dual role in mutagenesis in P. putida-besides functioning in repair of damaged DNA, NER is also important in generation of mutations. We hypothesize that NER enzymes may initiate gratuitous DNA repair and the following DNA repair synthesis might be mutagenic.

Specific and efficient binding of xeroderma pigmentosum complementation group A to double-strand/single-strand DNA junctions with 3'- and/or 5'-ssDNA branches

Human XPA is an important DNA damage recognition protein in nucleotide excision repair (NER). We previously observed that XPA binds to the DNA lesion as a homodimer [Liu, Y., Liu, Y., Yang, Z., Utzat, C., Wang, G., Basu, A. K., and Zou, Y. (2005) Biochemistry 44, 7361-7368]. Herein we report that XPA recognized undamaged DNA double-strand/single-strand (ds-ssDNA) junctions containing ssDNA branches with binding affinity (Kd = 49.1 +/- 5.1 nM) much higher than its ability to bind to DNA damage. The recognized DNA junction structures include the Y-shape junction (with both 3'- and 5'-ssDNA branches), 3'-overhang junction (with a 3'-ssDNA branch), and 5'-overhang junction (with a 5'-ssDNA branch). Using gel filtration chromatography and gel mobility shift assays, we showed that the highly efficient binding appeared to be carried out by the XPA monomer and that the binding was largely independent of RPA. Furthermore, XPA efficiently bound to six-nucleotide mismatched DNA bubble substrates with or without DNA adducts including C8 guanine adducts of AF, AAF, and AP and the T[6,4]T photoproducts. Using a set of defined DNA substrates with varying degrees of DNA bending, we also found that the XPC-HR23B complex recognized DNA bending, whereas neither XPA nor the XPA-RPA complex could bind to bent DNA. We propose that, besides DNA damage recognition, XPA may also play a novel role in stabilizing, via its high affinity to ds-ssDNA junctions, the DNA strand opening surrounding the lesion for stable formation of preincision NER intermediates. Our results provide a plausible mechanistic interpretation for the indispensable requirement of XPA for both global genome and transcription-coupled repairs. Since ds-ssDNA junctions are common intermediates in many DNA metabolic pathways, the additional potential role of XPA in cellular processes is discussed.

Identification and characterization of two uvrA genes of Xanthomonas axonopodis pathovar citri

Two uvrA-like genes, designated uvrA1 and uvrA2, that may be involved in nucleotide excision repair in Xanthomonas axonopodis pv. citri (X. a. pv. citri) strain XW47 were characterized. The uvrA1 gene was found to be 2,964 bp in length capable of encoding a protein of 987 amino acids. The uvrA2 gene was determined to be 2,529 bp with a coding potential of 842 amino acids. These two proteins share 71 and 39% identity, respectively, in amino acid sequence with the UvrA protein of Escherichia coli. Analyses of the deduced amino acid sequence revealed that UvrA1 and UvrA2 have structures characteristic of UvrA proteins, including the Walker A and Walker B motifs, zinc finger DNA binding domains, and helix-turn-helix motif with a polyglycine hinge region. The uvrA1 or uvrA2 mutant, constructed by gene replacement, was more sensitive to DNA-damaging agents methylmethane sulfonate (MMS), mitomycin C (MMC), or ultraviolet (UV) than the wild type. The uvrA1 mutant was four orders of magnitude more sensitive to UV irradiation and two orders of magnitude more sensitive to MMS than the uvrA2 mutant. The uvrA1uvrA2 double mutant was one order of magnitude more sensitive to MMS, MMC, or UV than the uvrA1 single mutant. These results suggest that UvrA1 plays a more important role than UvrA2 in DNA repair in X. a. pv. citri. Both uvrA1 and uvrA2 genes were found to be constitutively expressed in the wild type and lexA1 or lexA2 mutant of X. a. pv. citri, and treatment of these cells with sublethal dose of MMC did not alter the expression of these two genes. Results of electrophoresis mobility shift assays revealed that LexA1 or LexA2 does not bind to either the uvrA1 or the uvrA2 promoter. These results suggest that uvrA expression in X. a. pv. citri is not regulated by the SOS response system.

Targeted deletion of the uvrBA operon and biological containment in the industrially important Bacillus licheniformis

From a Bacillus licheniformis wild type as well as a defined asporogenous derivative, stable UV hypersensitive mutants were generated by targeted deletion of the uvrBA operon, encoding highly conserved key components of the nucleotide excision repair. Comparative studies, which included the respective parental strains, revealed no negative side effects of the deletion, neither on enzyme secretion nor on vegetative propagation. Thus, the uvrBA locus proved to be a useful deletion target for achieving biological containment in this industrially exploited bacterium. In contrast to recA mutants, which also display UV hypersensitivity, further strain development via homologous recombination techniques will be still possible in such uvr mutants.

Robust incision of Benoz[a]pyrene-7,8-dihyrodiol-9,10-epoxide-DNA adducts by a recombinant thermoresistant interspecies combination UvrABC endonuclease system

Prokaryotic DNA repair nucleases are useful reagents for detecting DNA lesions. UvrABC endonuclease, encoded by the UvrA, UvrB, and UvrC genes can incise DNA containing bulky nucleotide adducts and intrastrand cross-links. UvrA, UvrB, and UvrC were cloned from Bacillus caldotenax (Bca)and UvrC from Thermatoga maritima (Tma), and recombinant proteins were overexpressed in and purified from Escherichia coli. Incision activities of UvrABC composed of all Bca-derived subunits (UvrABC(Bca)) and an interspecies combination UvrABC composed of Bca-derived UvrA and UvrB and Tma-derived UvrC (UvrABC(Tma)) were compared on benoz[a]pyrene-7,8-dihyrodiol-9,10-epoxide (BPDE)-adducted substrates. Both UvrABC(Bca) and UvrABC(Tma) specifically incised both BPDE-adducted plasmid DNAs and site-specifically modified 50-bp oligonucleotides containing a single (+)-trans- or (+)-cis-BPDE adduct. Incision activity was maximal at 55-60 degrees C. However, UvrABC(Tma) was more robust than UvrABC(Bca) with 4-fold greater incision activity on BPDE-adducted oligonucleotides and 1.5-fold greater on [(3)H]BPDE-adducted plasmid DNAs. Remarkably, UvrABC(Bca) incised only at the eighth phosphodiester bond 5' to the BPDE-modified guanosine. In contrast, UvrABC(Tma) performed dual incision, cutting at both the fifth phosphodiester bond 3' and eighth phosphodiester bond 5' from BPDE-modified guanosine. BPDE adduct stereochemistry influenced incision activity, and cis adducts on oligonucleotide substrates were incised more efficiently than trans adducts by both UvrABC(Bca) and UvrABC(Tma). UvrAB-DNA complex formation was similar with (+)-trans- and (+)-cis-BPDE-adducted substrates, suggesting that UvrAB binds both adducts equally and that adduct configuration modifies UvrC recognition of the UvrAB-DNA complex. The dual incision capabilities and higher incision activity of UvrABC(Tma) make it a robust tool for DNA adduct studies.

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.

UvrB domain 4, an autoinhibitory gate for regulation of DNA binding and ATPase activity

UvrB, a central DNA damage recognition protein in bacterial nucleotide excision repair, has weak affinity for DNA, and its ATPase activity is activated by UvrA and damaged DNA. Regulation of DNA binding and ATP hydrolysis by UvrB is poorly understood. Using atomic force microscopy and biochemical assays, we found that truncation of domain 4 of Bacillus caldotenax UvrB (UvrBDelta4) leads to multiple changes in protein function. Protein dimerization decreases with an approximately 8-fold increase of the equilibrium dissociation constant and an increase in DNA binding. Loss of domain 4 causes the DNA binding mode of UvrB to change from dimer to monomer, and affinity increases with the apparent dissociation constants on nondamaged and damaged single-stranded DNA decreasing 22- and 14-fold, respectively. ATPase activity by UvrBDelta4 increases 14- and 9-fold with and without single-stranded DNA, respectively, and UvrBDelta4 supports UvrA-independent damage-specific incision by Cho on a bubble DNA substrate. We propose that other than its previously discovered role in regulating protein-protein interactions, domain 4 is an autoinhibitory domain regulating the DNA binding and ATPase activities of UvrB.

Structural basis for DNA recognition and processing by UvrB

DNA-damage recognition in the nucleotide excision repair (NER) cascade is a complex process, operating on a wide variety of damages. UvrB is the central component in prokaryotic NER, directly involved in DNA-damage recognition and guiding the DNA through repair synthesis. We report the first structure of a UvrB-double-stranded DNA complex, providing insights into the mechanism by which UvrB binds DNA, leading to formation of the preincision complex. One DNA strand, containing a 3' overhang, threads behind a beta-hairpin motif of UvrB, indicating that this motif inserts between the strands of the double helix, thereby locking down either the damaged or undamaged strand. The nucleotide directly behind the beta-hairpin is flipped out and inserted into a small, highly conserved pocket in UvrB.

Examining Ty3 polypurine tract structure and function by nucleoside analog interference

We have combined nucleoside analog interference with chemical footprinting, thermal denaturation, NMR spectroscopy, and biochemical studies to understand recognition of the polypurine tract (PPT) primer of the Saccharomyces cerevisiae long terminal repeat-containing retrotransposon Ty3 by its cognate reverse transcriptase. Locked nucleic acid analogs, which constrain sugar ring geometry, were introduced pairwise throughout the PPT (-)-DNA template, whereas abasic tetrahydrofuran linkages, which lack the nucleobase but preserve the sugar phosphate backbone, were introduced throughout the (-)-strand DNA template and (+)-strand RNA primer. Collectively, our data suggest that both the 5'- and 3'-portions of the PPT-containing RNA/DNA hybrid are sensitive to nucleoside analog substitution, whereas the intervening region can be modified without altering cleavage specificity. These two regions most likely correspond to portions of the PPT that make close contact with the Ty3 reverse transcriptase thumb subdomain and RNase H catalytic center, respectively. Achieving a similar phenotype with nucleoside analogs that have different effects on duplex geometry reveals structural features that are important mediators of Ty3 PPT recognition. Finally, the results from introducing tetrahydrofuran lesions around the scissile PPT/unique 3'-sequence junction indicate that template nucleobase -1 is dispensable for catalysis, whereas a primer nucleobase on either side of the junction is necessary.

Transcription-coupled repair: a complex affair

Transcription-coupled repair (TCR) is generally observed as more rapid or more efficient removal of certain types of DNA damage from the transcribed strands of expressed genes compared with the nontranscribed strands. It has been clearly demonstrated to be a subpathway of nucleotide excision repair (NER) in E. coli, yeast and mammalian cells. Genetic and biochemical studies indicate that it is a highly complex process and requires the participation of the NER pathway, the RNA polymerase complex and additional factors. An early event in TCR is likely the blocking of RNA polymerase complex elongation by damage present in the transcribed strands of expressed genes. Whether TCR is involved in base excision repair pathways or the repair of common forms of oxidative damage is less clear. This review is focused on the description of possible mechanisms of TCR in E. coli and mammalian cells.

'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.

Recognition and incision of gamma-radiation-induced cross-linked guanine-thymine tandem lesion G[8,5-Me]T by UvrABC nuclease

Nucleotide excision repair (NER) plays an important role in maintaining the integrity of DNA by removing various types of bulky or distorting DNA adducts in both prokaryotic and eukaryotic cells. In Escherichia coli, the excision repair proteins UvrA, UvrB, and UvrC recognize and incise the bulky DNA damages induced by UV light and chemical carcinogens. In this process, when a putative lesion in DNA is identified initially by UvrA, a subsequent strand opening is carried out by UvrB that not only ensures that the distortion is indeed due to a damaged nucleotide but also recognizes the chemical structure of the modified nucleotides with varying efficiencies. UvrB also recruits UvrC that catalyzes both the 3'- and the 5'-incisions. Herein, we examined the interaction of UvrABC with a DNA substrate containing a single G[8,5-Me]T cross-link and compared it with T[6,4]T (the 6-4 pyrimidine-pyrimidone photoproduct) and the C8 guanine adduct of N-acetyl-2-aminofluorene (AAF). The intrastrand vicinal cross-link G[8,5-Me]T containing a covalent bond between the C8 position of guanine and the 5-methyl carbon of the 3'-thymine is formed by X-radiation, while T[6,4]T is a vicinal cross-link induced by the UV light. We also selected the AAF adduct for comparison because it represents a highly distorting monoadduct containing a covalent linkage at the C8 position of guanine. The dissociation constants (K(d)) for UvrA protein binding to DNA substrates containing the G[8,5-Me]T, T[6,4]T, and AAF adducts, as determined by gel mobility shift assays, were 3.1 +/- 1.3, 2.8 +/- 0.9, and 8.2 +/- 1.9, respectively. Although UvrA had a considerably higher affinity for G[8,5-Me]T than for the AAF adduct, the G[8,5-Me]T intrastrand cross-link was incised by UvrABC much less efficiently than the T[6,4]T intrastrand cross-link and the AAF adduct. Similar incision results also were obtained with the DNA substrates containing the adducts in a six-nucleotide bubble, indicating that the inefficient incision of G[8,5-Me]T cross-link by UvrABC was probably due to the lack of efficient recognition of the adduct by UvrB at the second step of DNA damage recognition in the E. coli NER. Indeed, as compared to T[6,4]T and AAF substrates, which clearly showed UvrB-DNA complex formation, very little UvrB complex was detectable with the G[8,5-Me]T substrate. Our result suggests that G[8,5-Me]T intrastrand cross-link is more resistant to excision repair in comparison with the T[6,4]T and AAF adducts and thus will likely persist longer in E. coli cells.

Nitrogen mustard- and half-mustard-induced damage in Escherichia coli requires different DNA repair pathways

Bifunctional alkylating agents are used in tumor chemotherapy to induce the death of malignant cells through blockage of DNA replication. Nitrogen mustards are commonly used chemotherapeutic agents that can bind mono- or bifunctionally to guanines in DNA. Mustard HN1 is considered a monofunctional analog of bifunctional mustard HN2 (mechlorethamine). Escherichia coli K12 mutant strains deficient in nucleotide excision repair (NER) or base excision repair (BER) were submitted to increasing concentrations of HN2 or HN1, and the results revealed that damage induced by each chemical demands different DNA repair pathways. Damage induced by HN2 demands the activity of NER with a minor requirement of the BER pathway, while HN1 damage repair depends on BER action, without any requirement of NER function. Taken together, our data suggest that HN1 and HN2 seem to induce different types of damage, since their repair depends on distinct pathways in E. coli.

Investigating HIV-1 polypurine tract geometry via targeted insertion of abasic lesions in the (-)-DNA template and (+)-RNA primer

A variety of biochemical and structural studies indicate that two regions of the human immunodeficiency virus type 1 (HIV-1) polypurine tract (PPT)-containing RNA/DNA hybrid deviate from standard Watson-Crick geometry. However, it is unclear whether and how these regions cooperate to ensure PPT primer selection by reverse transcriptase-associated ribonuclease H and subsequent removal from nascent (+)-DNA. To address these issues, we synthesized oligonucleotides containing abasic lesions in either the PPT (+)-RNA primer or (-)-DNA template to locally remove nucleobases, although retaining the sugar-phosphate backbone. KMnO(4) footprinting indicates such lesions locally alter duplex structure, whereas thermal melting studies show significantly reduced stability when lesions are positioned around the scissile bond. Substituting the (-)-DNA template between positions -15 and -13 altered cleavage specificity, whereas equivalent substitutions of the (+)-RNA had almost no effect. The unpaired base of the DNA template observed crystallographically (-11C) could also be removed without significant loss of cleavage specificity. With respect to the scissile -1/+1 phosphodiester bond, template nucleobases could be removed without loss of cleavage specificity, whereas equivalent lesions in the RNA primer were inhibitory. Our data suggest an interaction between the p66 thumb subdomain of HIV-1 reverse transcriptase, and the DNA template in the "unzipped" portion of the RNA/DNA hybrid could aid in positioning the ribonuclease H catalytic center at the PPT/U3 junction and also provides insights into nucleic acid geometry around the scissile bond required for hydrolysis.

Transcription and DNA adducts: what happens when the message gets cut off?

DNA damage located within a gene's transcription unit can cause RNA polymerase to stall at the modified site, resulting in a truncated transcript, or progress past, producing full-length RNA. However, it is not immediately apparent why some lesions pose strong barriers to elongation while others do not. Studies using site-specifically damaged DNA templates have demonstrated that a wide range of lesions can impede the progress of elongating transcription complexes. The collected results of this work provide evidence for the idea that subtle structural elements can influence how an RNA polymerase behaves when it encounters a DNA adduct during elongation. These elements include: (1) the ability of the RNA polymerase active site to accommodate the damaged base; (2) the size and shape of the adduct, which includes the specific modified base; (3) the stereochemistry of the adduct; (4) the base incorporated into the growing transcript; and (5) the local DNA sequence.

Structural insights into the first incision reaction during nucleotide excision repair

Nucleotide excision repair is a highly conserved DNA repair mechanism present in all kingdoms of life. The incision reaction is a critical step for damage removal and is accomplished by the UvrC protein in eubacteria. No structural information is so far available for the 3' incision reaction. Here we report the crystal structure of the N-terminal catalytic domain of UvrC at 1.5 A resolution, which catalyzes the 3' incision reaction and shares homology with the catalytic domain of the GIY-YIG family of intron-encoded homing endonucleases. The structure reveals a patch of highly conserved residues surrounding a catalytic magnesium-water cluster, suggesting that the metal binding site is an essential feature of UvrC and all GIY-YIG endonuclease domains. Structural and biochemical data strongly suggest that the N-terminal endonuclease domain of UvrC utilizes a novel one-metal mechanism to cleave the phosphodiester bond.

Identification of residues within UvrB that are important for efficient DNA binding and damage processing

The UvrB protein is the central recognition protein in bacterial nucleotide excision repair. We have shown previously that the highly conserved beta-hairpin motif in Bacillus caldotenax UvrB is essential for DNA binding, damage recognition, and UvrC-mediated incision, as deletion of the upper part of the beta-hairpin (residues 97-112) results in the inability of UvrB to be loaded onto damaged DNA, defective incision, and the lack of strand-destabilizing activity. In this work, we have further examined the role of the beta-hairpin motif of UvrB by a mutational analysis of 13 amino acids within or in the vicinity of the beta-hairpin. These amino acids are predicted to be important for the interaction of UvrB with both damaged and non-damaged DNA strands as well as the formation of salt bridges between the beta-hairpin and domain 1b of UvrB. The resulting mutants were characterized by standard functional assays such as oligonucleotide incision, electrophoretic mobility shift, strand-destabilizing, and ATPase assays. Our data indicated a direct role of Tyr96, Glu99, and Arg123 in damage-specific DNA binding. In addition, Tyr93 plays an important but less essential role in DNA binding by UvrB. Finally, the formation of salt bridges between the beta-hairpin and domain 1b, involving amino acids Lys111 bound to Glu307 and Glu99 bound to Arg367 or Arg289, are important but not essential for the function of UvrB.

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.

DNA damage recognition of mutated forms of UvrB proteins in nucleotide excision repair

The DNA repair protein UvrB plays an indispensable role in the stepwise and sequential damage recognition of nucleotide excision repair in Escherichia coli. Our previous studies suggested that UvrB is responsible for the chemical damage recognition only upon a strand opening mediated by UvrA. Difficulties were encountered in studying the direct interaction of UvrB with adducts due to the presence of UvrA. We report herein that a single point mutation of Y95W in which a tyrosine is replaced by a tryptophan results in an UvrB mutant that is capable of efficiently binding to structure-specific DNA adducts even in the absence of UvrA. This mutant is fully functional in the UvrABC incisions. The dissociation constant for the mutant-DNA adduct interaction was less than 100 nM at physiological temperatures as determined by fluorescence spectroscopy. In contrast, similar substitutions at other residues in the beta-hairpin with tryptophan or phenylalanine do not confer UvrB such binding ability. Homology modeling of the structure of E. coli UvrB shows that the aromatic ring of residue Y95 and only Y95 directly points into the DNA binding cleft. We have also examined UvrB recognition of both "normal" bulky BPDE-DNA and protein-cross-linked DNA (DPC) adducts and the roles of aromatic residues of the beta-hairpin in the recognition of these lesions. A mutation of Y92W resulted in an obvious decrease in the efficiency of UvrABC incisions of normal adducts, while the incision of the DPC adduct is dramatically increased. Our results suggest that Y92 may function differently with these two types of adducts, while the Y95 residue plays an unique role in stabilizing the interaction of UvrB with DNA damage, most likely by a hydrophobic stacking.

Effects of DNA adduct structure and sequence context on strand opening of repair intermediates and incision by UvrABC nuclease

DNA damage recognition of nucleotide excision repair (NER) in Escherichia coli is achieved by at least two steps. In the first step, a helical distortion is recognized, which leads to a strand opening at the lesion site. The second step involves the recognition of the type of chemical modification in the single-stranded region of DNA during the processing of the lesions by UvrABC. In the current work, by comparing the efficiencies of UvrABC incision of several types of different DNA adducts, we show that the size and position of the strand opening are dependent on the type of DNA adducts. Optimal incision efficiency for the C8-guanine adducts of 2-aminofluorene (AF) and N-acetyl-2-aminofluorene (AAF) was observed in a bubble of three mismatched nucleotides, whereas the same for C8-guanine adduct of 1-nitropyrene and N(2)-guanine adducts of benzo[a]pyrene diol epoxide (BPDE) was noted in a bubble of six mismatched nucleotides. This suggests that the size of the aromatic ring system of the adduct might influence the extent and number of bases associated with the opened strand region catalyzed by UvrABC. We also showed that the incision efficiency of the AF or AAF adduct was affected by the neighboring DNA sequence context, which, in turn, was the result of differential binding of UvrA to the substrates. The sequence context effect on both incision and binding disappeared when a bubble structure of three bases was introduced at the adduct site. We therefore propose that these effects relate to the initial step of damage recognition of DNA structural distortion. The structure-function relationships in the recognition of the DNA lesions, based on our results, have been discussed.

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

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

Reduced sulfhydryls maintain specific incision of BPDE-DNA adducts by recombinant thermoresistant Bacillus caldotenax UvrABC endonuclease

Prokaryotic DNA repair nucleases are useful reagents for detecting DNA lesions. Escherichia coli UvrABC endonuclease can incise DNA containing UV photoproducts and bulky chemical adducts. The limited stability of the E. coli UvrABC subunits leads to difficulty in estimating incision efficiency and quantitative adduct detection. To develop a more stable enzyme with greater utility for the detection of DNA adducts, thermoresistant UvrABC endonuclease was cloned from the eubacterium Bacillus caldotenax (Bca) and individual recombinant protein subunits were overexpressed in and purified from E. coli. Here, we show that Bca UvrC that had lost activity or specificity could be restored by dialysis against buffer containing 500 mM KCl and 20mM dithiothreitol. Our data indicate that UvrC solubility depended on high salt concentrations and UvrC nuclease activity and the specificity of incisions depended on the presence of reduced sulfhydryls. Optimal conditions for BCA UvrABC-specific cleavage of plasmid DNAs treated with [3H](+)-7R,8S-dihydroxy-9S,10R-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE) (1-5 lesions/plasmid) were developed. Preincubation of substrates with UvrA and UvrB enhanced incision efficiency on damaged substrates and decreased non-specific nuclease activity on undamaged substrates. Under optimal conditions for damaged plasmid incision, approximately 70% of adducts were incised in 1 nM plasmid DNA (2 BPDE adducts/5.4 kbp plasmid) with UvrA at 2.5 nM, UvrB at 62.5 nM, and UvrC at 25 nM. These results demonstrate the potential usefulness of the Bca UvrABC for monitoring the distribution of chemical carcinogen-induced lesions in DNA.