The initiation of DNA base excision repair of dipyrimidine photoproducts

Using Yeast as a Model Organism to Study the Functional Roles of Histone Acetylation in DNA Excision Repair

Histone acetylation plays important roles in regulating DNA metabolic processes, including many DNA repair pathways. The nucleotide excision repair (NER) pathway is critical for removing bulky, helix-distorting DNA lesions, such as UV light-induced photoproducts, but the activity of this pathway is significantly inhibited when lesions reside in nucleosomes. Recent studies have indicated that histone acetyltransferase (HAT) activity may be induced in response to UV damage, in order to facilitate the repair of UV-induced lesions in chromatin. Budding yeast (Saccharomyces cerevisiae) is an important model system for studying the functional roles of histone acetylation and HATs in NER, due to the ease of genetically altering HAT activity or acetylated lysine residues in histones. Here, we describe protocols for measuring the repair of cyclobutane pyrimidine dimers (CPDs), the major UV-induced photoproduct, in yeast strains deficient in HAT activity, either due to gene deletion or rapid anchor-away depletion of the HAT enzyme. Methods for measuring CPD repair in bulk chromatin, as well as individual chromatin loci, are detailed below.

Nucleation of DNA repair factors by FOXA1 links DNA demethylation to transcriptional pioneering

FOXA1 functions in epigenetic reprogramming and is described as a 'pioneer factor'. However, exactly how FOXA1 achieves these remarkable biological functions is not fully understood. Here we report that FOXA1 associates with DNA repair complexes and is required for genomic targeting of DNA polymerase β (POLB) in human cells. Genome-wide DNA methylomes demonstrate that the FOXA1 DNA repair complex is functionally linked to DNA demethylation in a lineage-specific fashion. Depletion of FOXA1 results in localized reestablishment of methylation in a large portion of FOXA1-bound regions, and the regions with the most consistent hypermethylation exhibit the greatest loss of POLB and are represented by active promoters and enhancers. Consistently, overexpression of FOXA1 commits its binding sites to active DNA demethylation in a POLB-dependent manner. Finally, FOXA1-associated DNA demethylation is tightly coupled with estrogen receptor genomic targeting and estrogen responsiveness. Together, these results link FOXA1-associated DNA demethylation to transcriptional pioneering by FOXA1.

Distinct catalytic activity and in vivo roles of the ExoIII and EndoIV AP endonucleases from Sulfolobus islandicus

AP endonuclease cleaves the phosphodiester bond 5'- to the AP (apurinic or apyrimidinic) sites and is one of the major enzymes involved in base excision repair. So far, the properties of several archaeal AP endonuclease homologues have been characterized in vitro, but little is known about their functions in vivo. Herein, we report on the biochemical and genetic analysis of two AP endonucleases, SisExoIII and SisEndoIV, from the hyperthermophilic crenarchaeon Sulfolobus islandicus REY15A. Both SisExoIII and SisEndoIV exhibit AP endonuclease activity, but neither of them has 3'-5' exonuclease activity. SisExoIII and SisEndoIV have similar K M values on the substrate containing an AP site, but the latter cleaves the AP substrate at a dramatically higher catalytic rate than the former. Unlike other AP endonucleases identified in archaea, SisExoIII and SisEndoIV do not exhibit any cleavage activity on DNA having oxidative damage (8-oxo-dG) or uracil. Genetic analysis revealed that neither gene is essential for cell viability, and the growth of ∆SiRe_2666 (endoIV), ∆SiRe_0100 (exoIII), and ∆SiRe_0100∆SiRe_2666 is not affected under normal growth conditions. However, ∆SiRe_2666 exhibits higher sensitivity to the alkylating agent methyl methanesulfonate (MMS) than ∆SiRe_0100. Over-expression of SiRe_0100 can partially complement the sensitivity of ∆SiRe_2666 to MMS, suggesting a backup role of SisExoIII in AP site processing in vivo. Intriguingly, over-expression of SisEndoIV renders the strain more sensitive to MMS than the control. Taken together, we conclude that SisEndoIV, but not SisExoIII, is the main AP endonuclease that participates directly in base excision repair in S. islandicus.

Methods to study transcription-coupled repair in chromatin

The effect of endogenous and exogenous DNA damage on the cellular metabolism can be studied at the genetic and molecular level. A paradigmatic case is the repair of UV-induced pyrimidine dimers (PDs) by nucleotide excision repair (NER) in Saccharomyces cerevisiae. To follow the formation and repair of PDs at specific chromosome loci, cells are irradiated with UV-light and incubated in the dark to allow repair by NER. Upon DNA isolation, cyclobutane pyrimidine dimers, which account for about 90 % of PDs, can be cleaved in vitro by the DNA nicking activity of the T4 endonuclease V repair enzyme. Subsequently, strand-specific repair in a suitable restriction fragment is determined by denaturing gel electrophoresis followed by Southern blot and indirect end-labeling using a single-stranded DNA probe. Noteworthy, this protocol could potentially be adapted to other kind of DNA lesions, as long as a DNA nick is formed or a lesion-specific endonuclease is available.Transcription-coupled repair (TC-NER) is a sub-pathway of NER that catalyzes the repair of the transcribed strand of active genes. RNA polymerase II is essential for TC-NER, and its occupancy on a damaged template can be analyzed by chromatin immunoprecipitation (ChIP). In this chapter, we provide an up-dated protocol for both the DNA repair analysis and ChIP approaches to study TC-NER in yeast chromatin.

Methods to study transcription-coupled repair in chromatin

Transcription-coupled repair (TCR) is a sub-pathway of nucleotide excision repair that allows for the enhanced repair of the transcribed strand of active genes. A classical method to study DNA repair in vivo consists in the molecular analysis of UV-induced DNA damages at specific loci. Cells are irradiated with a defined dose of UV light leading to the formation of DNA lesions and incubated in the dark to allow repair. About 90% of the photoproducts consist of cyclobutane pyrimidine dimers, which can be cleaved by the DNA nicking activity of the T4 endonuclease V (T4endoV) repair enzyme. Strand-specific repair in a suitable restriction fragment is determined by alkaline gel electrophoresis followed by Southern blot transfer and indirect end-labeling using a single-stranded probe. Recent approaches have assessed the role of transcription factors in TCR by analyzing RNA polymerase II occupancy on a damaged template by chromatin immunoprecipitation (ChIP). Cells are treated with formaldehyde in vivo to cross-link proteins to DNA and enrichment of a protein of interest is done by subsequent immunoprecipitation. Upon reversal of the protein-DNA cross-links, the amount of coprecipitated DNA fragments can be detected by quantitative PCR. To perform ChIP on UV-damaged templates, we included an in vitro photoreactivation step prior to PCR analysis to ensure that all precipitated DNA fragments serve as substrates for the PCR reaction. Here, we provide a detailed protocol for both the DNA repair analysis and the ChIP approaches to study TCR in chromatin.

Structure and mechanism for DNA lesion recognition

A fundamental question in DNA repair is how a lesion is detected when embedded in millions to billions of normal base pairs. Extensive structural and functional studies reveal atomic details of DNA repair protein and nucleic acid interactions. This review summarizes seemingly diverse structural motifs used in lesion recognition and suggests a general mechanism to recognize DNA lesion by the poor base stacking. After initial recognition of this shared structural feature of lesions, different DNA repair pathways use unique verification mechanisms to ensure correct lesion identification and removal.

Base-excision repair of oxidative DNA damage by DNA glycosylases

Oxidative damage to DNA caused by free radicals and other oxidants generate base and sugar damage, strand breaks, clustered sites, tandem lesions and DNA-protein cross-links. Oxidative DNA damage is mainly repaired by base-excision repair in living cells with the involvement of DNA glycosylases in the first step and other enzymes in subsequent steps. DNA glycosylases remove modified bases from DNA, generating an apurinic/apyrimidinic (AP) site. Some of these enzymes that remove oxidatively modified DNA bases also possess AP-lyase activity to cleave DNA at AP sites. DNA glycosylases possess varying substrate specificities, and some of them exhibit cross-activity for removal of both pyrimidine- and purine-derived lesions. Most studies on substrate specificities and excision kinetics of DNA glycosylases were performed using oligonucleotides with a single modified base incorporated at a specific position. Other studies used high-molecular weight DNA containing multiple pyrimidine- and purine-derived lesions. In this case, substrate specificities and excision kinetics were found to be different from those observed with oligonucleotides. This paper reviews substrate specificities and excision kinetics of DNA glycosylases for removal of pyrimidine- and purine-derived lesions in high-molecular weight DNA.

A recombinant exonuclease III homologue of the thermophilic archaeon Methanothermobacter thermautotrophicus

AP endonucleases catalyse an important step in the base excision repair (BER) pathway by incising the phosphodiester backbone of damaged DNA immediately 5' to an abasic site. Here, we report the cloning and expression of the 774 bp Mth0212 gene from the thermophilic archaeon Methanothermobacter thermautotrophicus, which codes for a putative AP endonuclease. The 30.3 kDa protein shares 30% sequence identity with exonuclease III (ExoIII) of Escherichia coli and 40% sequence identity with the human AP endonuclease Ape1. The gene was amplified from a culture sample and cloned into an expression vector. Using an E. coli host, the thermophilic protein could be produced and purified. Characterization of the enzymatic activity revealed strong binding and Mg2+-dependent nicking activity on undamaged double-stranded (ds) DNA at low ionic strength, even at temperatures below the optimum growth temperature of M. thermautotrophicus (65 degrees C). Additionally, a much faster nicking activity on AP site containing DNA was demonstrated. Unspecific incision of undamaged ds DNA was nearly inhibited at KCl concentration of approximately 0.5 M, whereas incision at AP sites was still complete at such salt concentrations. Nicked DNA was further degraded at temperatures above 50 degrees C, probably by an exonucleolytic activity of the enzyme, which was also found on recessed 3' ends of linearized ds DNA. The enzyme was active at temperatures up to 70 degrees C and, using circular dichroism spectroscopy, shown to denature at temperatures approaching 80 degrees C. Considering the high intracellular potassium ion concentration in M. thermautotrophicus, our results suggest that the characterized thermophilic enzyme acts as an AP endonuclease in vivo with similar activities as Ape1.

Crystal structure of a DNA decamer containing a cis-syn thymine dimer

It is well known that exposure to UV induces DNA damage, which is the first step in mutagenesis and a major cause of skin cancer. Among a variety of photoproducts, cyclobutane-type pyrimidine photodimers (CPD) are the most abundant primary lesion. Despite its biological importance, the precise relationship between the structure and properties of DNA containing CPD has remained to be elucidated. Here, we report the free (unbound) crystal structure of duplex DNA containing a CPD lesion at a resolution of 2.0 A. Our crystal structure shows that the overall helical axis bends approximately 30 degrees toward the major groove and unwinds approximately 9 degrees, in remarkable agreement with some previous theoretical and experimental studies. There are also significant differences in local structure compared with standard B-DNA, including pinching of the minor groove at the 3' side of the CPD lesion, a severe change of the base pair parameter in the 5' side, and serious widening of both minor and major groves both 3' and 5' of the CPD. Overall, the structure of the damaged DNA differs from undamaged DNA to an extent that DNA repair proteins may recognize this conformation, and the various components of the replicational and transcriptional machinery may be interfered with due to the perturbed local and global structure.

Rpb4 and Rpb9 mediate subpathways of transcription-coupled DNA repair in Saccharomyces cerevisiae

Rpb9, a non-essential subunit of RNA polymerase II, mediates a transcription-coupled repair (TCR) subpathway in Saccharomyces cerevisiae. This subpathway initiates at the same upstream site as the previously identified Rad26 subpathway. However, the Rpb9 subpathway operates more effectively in the coding region than in the region upstream of the transcription start site, whereas the Rad26 subpathway operates equally in the two regions. Rpb4, another non-essential subunit of RNA polymerase II, plays a dual role in regulating the two subpathways, suppressing the Rpb9 subpathway and facilitating the Rad26 subpathway. Simultaneous deletion of RPB9 and RAD26 genes completely abolishes TCR in both the coding and upstream regions, indicating that no other TCR subpathway exists in RNA polymerase II-transcribed genes.

Chlorella virus pyrimidine dimer glycosylase excises ultraviolet radiation- and hydroxyl radical-induced products 4,6-diamino-5-formamidopyrimidine and 2,6-diamino-4-hydroxy-5-formamidopyrimidine from DNA

A DNA glycosylase specific for UV radiation-induced pyrimidine dimers has been identified from the Chlorella virus Paramecium Bursaria Chlorella virus-1. This enzyme (Chlorella virus pyrimidine dimer glycosylase [cv-pdg]) exhibits a 41% amino acid identity with endonuclease V from bacteriophage T4 (T4 pyrimidine dimer glycosylase [T4-pdg]), which is also specific for pyrimidine dimers. However, cv-pdg possesses a higher catalytic efficiency and broader substrate specificity than T4-pdg. The latter excises 4,6-diamino-5-formamidopyrimidine (FapyAde), a UV radiation- and hydroxyl radical-induced monomeric product of adenine in DNA. Using gas chromatography-isotope-dilution mass spectrometry and y-irradiated DNA, we show in this work that cv-pdg also displays a catalytic activity for excision of FapyAde and, in addition, it excises 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua). Kinetic data show that FapyAde is a better substrate for cv-pdg than FapyGua. On the other hand, cv-pdg possesses a greater efficiency for the extension of FapyAde than T4-pdg. These two enzymes exhibit different substrate specificities despite substantial structural similarities.

Keynote: past, present, and future aspects of base excision repair

Covalent alterations of DNA bases, which may have promutagenic or cytotoxic effects, are major consequences of endogenous DNA damage caused by hydrolysis, reactive oxygen species, and several metabolites and coenzymes. A common strategy for initiation of DNA base excision repair (BER) involves a DNA glycosylase that binds the altered deoxynucleoside in an extrahelical position and catalyzes cleavage of the base-sugar bond. Subsequently, an AP endonuclease or AP lyase activity incises the abasic site, followed by short-patch gap-filling, excision of the base-free sugar-phosphate residue, and ligation. The initial work that resulted in the discovery of DNA glycosylases and AP endonucleases is briefly reviewed. In recent years, it has been shown that the latter steps of the BER pathway differ greatly between mammalian cells and microorganisms such as yeast and bacteria. Three distinct subpathways of BER occur in mammalian cells, and these have been individually reconstituted with purified enzymes. Gene knockout mice are now revealing specific roles and backup mechanisms for repair functions in murine cells, and the results in general are also applicable to human cells. Future developments in the field of base excision repair include definition by proteomics of all factors involved in handling many different types of DNA lesions, clarification of mechanisms of repair of chromatin at a high level of accuracy, manifestation of repair proteins as drug targets for cellular sensitization to ionizing radiation and anticancer medicines, and elucidation of cross-talk between the base excision repair factors and other cellular proteins involved in a variety of stress responses.

Potential double-flipping mechanism by E. coli MutY

To understand the structural basis of the recognition and removal of specific mismatched bases in double-stranded DNAs by the DNA repair glycosylase MutY, a series of structural and functional analyses have been conducted. MutY is a 39-kDa enzyme from Escherichia coli, which to date has been refractory to structural determination in its native, intact conformation. However, following limited proteolytic digestion, it was revealed that the MutY protein is composed of two modules, a 26-kDa domain that retains essential catalytic function (designated p26MutY) and a 13-kDa domain that is implicated in substrate specificity and catalytic efficiency. Several structures of the 26-kDa domain have been solved by X-ray crystallographic methods to a resolution of up to 1.2 A. The structure of a catalytically incompetent mutant of p26MutY complexed with an adenine in the substrate-binding pocket allowed us to propose a catalytic mechanism for MutY. Since reporting the structure of p26MutY, significant progress has been made in solving the solution structure of the noncatalytic C-terminal 13-kDa domain of MutY by NMR spectroscopy. The topology and secondary structure of this domain are very similar to that of MutT, a pyrophosphohydrolase. Molecular modeling techniques employed to integrate the two domains of MutY with DNA suggest that MutY can wrap around the DNA and initiate catalysis by potentially flipping adenine and 8-oxoguanine out of the DNA helix.

Intron conservation in the DNA polymerase gene encoded by Chlorella viruses

Previously we reported that 19 of 42 viruses that infect Chlorella strain NC64A (NC64A viruses) contain a short, nuclear-located, spliceosomal-processed intron in a pyrimidine dimer-specific glycosylase/apyrimidine lyase (pdg) gene. Surprisingly, the nucleotide sequence of the intron region is more conserved than the exon regions of the gene (L. Sun et al., 2000, J. Mol. Evol. 50, 82-92). For comparative purposes, we determined the nucleotide sequence of a similar intron type and its flanking coding regions in the DNA polymerase (dnapol) gene from the same 42 NC64A viruses and also 5 viruses that infect Chlorella strain Pbi. Thirty-eight of the 42 NC64A viruses contained a 101-nucleotide intron and the remaining 4 had an 86-nucleotide intron located in the same position in dnapol. The 4 viruses with the smaller intron in dnapol also have a smaller intron in their pdg gene. There was no intron in the dnapol gene of the 5 Pbi viruses. Phylogenetic analyses indicate that the dnapol genes containing the 86-nucleotide intron represent the ancestral condition among the NC64A viruses. The intron in the dnapol gene is phase 0 (keeps codons intact), which differs from the phase 1 intron in the pdg gene. The intron in the dnapol gene, unlike the pdg intron, was conserved (83 to 100% identical) to about the same extent as the coding regions of the gene (78 to 100% identical).

Alternative forms of formamidopyrimidine-DNA glycosylase from Arabidopsis thaliana

Formamidopyrimidine-DNA glycosylase (FPG) catalyzes the initial steps in the repair of DNA containing oxidized purines. Two complementary DNA clones encoding homologs of bacterial FPG, designated Atfpg-1 and Atfpg-2, have been isolated from Arabidopsis thaliana. They are products of alternative splicing of the transcript of a single gene. Proteins encoded by both clones, AtFPG-1 and AtFPG-2, engineered to contain oligohistidine sequences on their C-terminal ends, were expressed in Escherichia coli and purified, and their activities were assayed. Both proteins cleaved DNA that contained apurinic sites, indicating that they have abasic lyase activity. AtFPG-1, but not AtFPG-2, showed significant cleavage of a double-stranded oligonucleotide that contained 8-oxo-guanine, indicating that the structural differences between the two proteins influence their enzymatic activities. However, both proteins were able to cleave the same sites in DNA that was treated with visible light in the presence of methylene blue.

Improved method for measuring the ensemble average of strand breaks in genomic DNA

The cis-syn cyclobutane pyrimidine dimer (CPD) is the major photoproduct induced in DNA by low wavelength ultraviolet radiation. An improved method was developed to detect CPD formation and removal in genomic DNA that avoids the problems encountered with the standard method of endonuclease detection of these photoproducts. Since CPD-specific endonucleases make single-strand cuts at CPD sites, quantification of the frequency of CPDs in DNA is usually done by denaturing gel electrophoresis. The standard method of ethidium bromide staining and gel photography requires more than 10 microg of DNA per gel lane, and correction of the photographic signal for the nonlinear film response. To simplify this procedure, a standard Southern blot protocol, coupled with phosphorimage analysis, was developed. This method uses random hybridization probes to detect genomic sequences with minimal sequence bias. Because of the vast linearity range of phosphorimage detection, scans of the signal profiles for the heterogeneous population of DNA fragments can be integrated directly to determine the number-average size of the population.

Partial complementation of the DNA repair defects in cells from xeroderma pigmentosum groups A, C, D and F but not G by the denV gene from bacteriophage T4

Endonuclease V (denV) from bacteriophage T4 was examined for its ability to complement the DNA repair defect in xeroderma pigmentosum (XP) cells from complementation groups A, C, D, F and G. The denV gene was introduced into SV40-transformed normal and XP cells using a retroviral vector. Expression of denV resulted in partial correction of UV sensitivity and increased host cell reactivation (HCR) of a UV-damaged reporter gene for XP cells from groups A, C and D, but not those from group G. Expression of denV in XP-F cells resulted in enhanced HCR of a UV-damaged reporter but did not affect UV sensitivity. The observed partial complementation is thought to reflect denV-mediated repair of cyclobutane-pyrimidine dimers (CPD), and is incomplete as denV does not recognize other UV-induced lesions, and may not even efficiently remove all CPD. As XP-F cells are believed to retain near-normal levels of CPD repair in the bulk of the genome, we believe that the disparity in the ability of denV to complement the repair deficiency in these cells results from an increased rate, but not level, of CPD repair. Furthermore, we suggest that the lack of correction in the XP-G cells examined results from an inability to process denV-incised CPD by the base excision repair pathway, as has been suggested for cells from the related genetic disorder, Cockayne syndrome. Expression of denV in repair proficient normal cells also resulted in increased HCR of the UV-damaged reporter construct, possibly arising from an increased rate of CPD repair in these cells.

Two glycosylase/abasic lyases from Neisseria mucosa that initiate DNA repair at sites of UV-induced photoproducts

Diverse organisms ranging from Escherichia coli to humans contain a variety of DNA repair proteins that function in the removal of damage caused by shortwave UV light. This study reports the identification, purification, and biochemical characterization of two DNA glycosylases with associated abasic lyase activity from Neisseria mucosa. These enzymes, pyrimidine dimer glycosylase I and II (Nmu-pdg I and Nmu-pdg II), were purified 30,000- and 10,000-fold, respectively. SDS-polyacrylamide gel electrophoresis analysis indicated that Nmu-pdg I is approximately 30 kDa, whereas Nmu-pdg II is approximately 19 kDa. The N-terminal amino acid sequence of Nmu-pdg II exhibits 64 and 66% identity with E. coli and Hemophilus parainfluenzae endonuclease III, respectively. Both Nmu-pdg I and Nmu-pdg II were found to have broad substrate specificities, as evidenced by their ability to incise DNA containing many types of UV and some types of oxidative damage. Consistent with other glycosylase/abasic lyases, the existence of a covalent enzyme-DNA complex could be demonstrated for both Nmu-pdg I and II when reactions were carried out in the presence of sodium borohydride. These data indicate the involvement of an amino group in the catalytic reaction mechanism of both enzymes.

Initiation of base excision repair: glycosylase mechanisms and structures

The base excision repair pathway is an organism's primary defense against mutations induced by oxidative, alkylating, and other DNA-damaging agents. This pathway is initiated by DNA glycosylases that excise the damaged base by cleavage of the glycosidic bond between the base and the DNA sugar-phosphate backbone. A subset of glycosylases has an associated apurinic/apyrimidinic (AP) lyase activity that further processes the AP site to generate cleavage of the DNA phosphate backbone. Chemical mechanisms that are supported by biochemical and structural data have been proposed for several glycosylases and glycosylase/AP lyases. This review focuses on the chemical mechanisms of catalysis in the context of recent structural information, with emphasis on the catalytic residues and the active site conformations of several cocrystal structures of glycosylases with their substrate DNAs. Common structural motifs for DNA binding and damage specificity as well as conservation of acidic residues and amino groups for catalysis are discussed.

Purification and characterization of a novel UV lesion-specific DNA glycosylase/AP lyase from Bacillus sphaericus

The purification and characterization of a pyrimidine dimer-specific glycosylase/AP lyase from Bacillus sphaericus (Bsp-pdg) are reported. Bsp-pdg is highly specific for DNA containing the cis-syn cyclobutane pyrimidine dimer, displaying no detectable activity on oligonucleotides with trans-syn I, trans-syn II, (6-4), or Dewar photoproducts. Like other glycosylase/AP lyases that sequentially cleave the N--glycosyl bond of the 5' pyrimidine of a cyclobutane pyrimidine dimer, and the phosphodiester backbone, this enzyme appears to utilize a primary amine as the attacking nucleophile. The formation of a covalent enzyme-DNA imino intermediate is evidenced by the ability to trap this protein-DNA complex by reduction with sodium borohydride. Also consistent with its AP lyase activity, Bsp-pdg was shown to incise an AP site-containing oligonucleotide, yielding beta- and delta-elimination products. N-terminal amino acid sequence analysis of this 26 kDa protein revealed little amino acid homology to any previously reported protein. This is the first report of a glycosylase/AP lyase enzyme from Bacillus sphaericus that is specific for cis-syn pyrimidine dimers.

Xeroderma pigmentosum complementation group A protein acts as a processivity factor

We have previously shown that endonucleases present in a protein complex, which has specificity for cyclobutane pyrimidine dimers, locate sites of damage in DNA by a processive mechanism of action in normal human lymphoblastoid cells. In contrast, the endonucleases present in this complex from xeroderma pigmentosum complementation group A (XPA) cells locate damage sites by a distributive or significantly less processive mechanism. Since the XPA protein has been shown to be responsible for the DNA repair defect in XPA cells, this protein was examined for involvement in the mechanism of target site location of these endonucleases. A recombinant XPA protein, produced by expression of the normal XPA cDNA in E. coli, was isolated and purified. The results show that the recombinant XPA protein was able to correct the defect in ability of the XPA endonucleases to act by a processive mechanism of action on UVC irradiated DNA. These studies indicate that the XPA protein, in addition to a role in damage recognition or damage verification, may function as a processivity factor.

Active-site determination of a pyrimidine dimer glycosylase

One mechanism for the repair of UV-induced DNA damage is the base excision repair pathway. The initial step in this pathway and the specificity for the type of damage that is to be repaired reside in DNA glycosylase/abasic (AP) lyases. Cleavage of the glycosyl bond of the 5' pyrimidine of a cyclobutane pyrimidine dimer is hypothesized to occur through the destabilization of the glycosyl bond by protonation of the base or sugar with a concomitant nucleophilic attack on C1' of the deoxyribose moiety. Based on mechanistic biochemical information from several glycosylase/AP lyases and the structural information on the bacteriophage T4 pyrimidine dimer glycosylase (T4-pdg), the catalytic mechanism has been investigated for the Chlorella virus pyrimidine dimer glycosylase (cv-pdg). As predicted from modeling studies and reaction mechanisms, the primary amine that initiates the nucleophilic displacement reaction could be trapped as a covalent imine intermediate and its identity determined by sequential Edman degradation. The primary amine was identified as the alpha-amino group on the N-terminal Thr2. Site-directed mutagenesis was subsequently used to confirm the conclusions that the alpha-amino group of cv-pdg is the active-site nucleophile.

The catalytic mechanism of a pyrimidine dimer-specific glycosylase (pdg)/abasic lyase, Chlorella virus-pdg

The repair of UV light-induced cyclobutane pyrimidine dimers can proceed via the base excision repair pathway, in which the initial step is catalyzed by DNA glycosylase/abasic (AP) lyases. The prototypical enzyme studied for this pathway is endonuclease V from the bacteriophage T4 (T4 bacteriophage pyrimidine dimer glycosylase (T4-pdg)). The first homologue for T4-pdg has been found in a strain of Chlorella virus (strain Paramecium bursaria Chlorella virus-1), which contains a gene that predicts an amino acid sequence homology of 41% with T4-pdg. Because both the structure and critical catalytic residues are known for T4-pdg, homology modeling of the Chlorella virus pyrimidine dimer glycosylase (cv-pdg) predicted that a conserved glutamic acid residue (Glu-23) would be important for catalysis at pyrimidine dimers and abasic sites. Site-directed mutations were constructed at Glu-23 to assess the necessity of a negatively charged residue at that position (Gln-23) and the importance of the length of the negatively charged side chain (Asp-23). E23Q lost glycosylase activity completely but retained low levels of AP lyase activity. In contrast, E23D retained near wild type glycosylase and AP lyase activities on cis-syn dimers but completely lost its activity on the trans-syn II dimer, which is very efficiently cleaved by the wild type cv-pdg. As has been shown for other glyscosylases, the wild type cv-pdg catalyzes the cleavage at dimers or AP sites via formation of an imino intermediate, as evidenced by the ability of the enzyme to be covalently trapped on substrate DNA when the reactions are carried out in the presence of a strong reducing agent; in contrast, E23D was very poorly trapped on cis-syn dimers but was readily trapped on DNA containing AP sites. It is proposed that Glu-23 protonates the sugar ring, so that the imino intermediate can be formed.