A new mechanism for repairing oxidative damage to DNA: (A)BC excinuclease removes AP sites and thymine glycols from DNA

Escherichia coli (A)BC excinuclease is the major enzyme responsible for removing bulky adducts, such as pyrimidine dimers and 6-4 photoproducts, from DNA. Mutants deficient in this enzyme are extremely sensitive to UV and UV-mimetic agents, but not to oxidizing agents, or ionizing radiation which damages DNA in part by generating active oxygen species. DNA glycosylases and AP1 endonucleases play major roles in repairing oxidative DNA damage, and thus it has been assumed that nucleotide excision repair has no role in cellular defense against damage by ionizing radiation and oxidative damage. In this study we show that the E. coli nucleotide excision repair enzyme (A)BC excinuclease removes from DNA the two major products of oxidative damage, thymine glycol and the baseless sugar (AP site). We conclude that nucleotide excision repair is an important cellular defense mechanism against oxidizing agents.     

(A)BC excinuclease: the Escherichia coli nucleotide excision repair enzyme

Nucleotide excision repair is the major pathway for removing damage from DNA. (A)BC excinuclease is the nuclease activity which initiates nucleotide excision repair in Escherichia coli. In this review, we focus on current understanding of the structure-function of the enzyme and the reaction mechanism of the repair pathway. In addition, recent biochemical studies on preferential repair of actively transcribed genes in E. coli are summarized.     

Substrate overlap and functional competition between human nucleotide excision repair and Escherichia coli photolyase and (a)BC excision nuclease

Human cell free extract prepared by the method of Manley et al. (1980) carries out repair synthesis on UV-irradiated DNA. Removal of pyrimidine dimers by photoreactivation with DNA photolyase reduces repair synthesis by about 50%. With excess enzyme in the reaction mixture photolyase reduced the repair signal by the same amount even in the absence of photoreactivating light, presumably by binding to pyrimidine dimers and interfering with the binding of human damage recognition protein. Similarly, the UvrB subunit of Escherichia coli (A)BC excinuclease when loaded onto UV-irradiated or psoralen-adducted DNA inhibited repair synthesis by cell-free extract by 75-80%. The opposite was true also as HeLa cell free extract specifically inhibited the photorepair of a thymine dimer by DNA photolyase and its removal by (A)BC excinuclease. Cell-free extracts from xeroderma pigmentosum (XP) complementation groups A and C were equally effective in blocking the E. coli repair proteins, while extracts from complementation groups D and E were ineffective in blocking the E. coli enzyme. These results suggest that XP-D and XP-E cells are defective in the damage recognition subunit(s) of human excision nuclease.     

Noncovalent drug-DNA binding interactions that inhibit and stimulate (A)BC excinuclease.

(A)BC excinuclease from Escherichia coli catalyzes the initial step of nucleotide excision repair. It recognizes and binds to many types of covalent modifications in DNA and incises the damaged strand on both sides of the lesion. We employed a variety of noncovalent DNA binding drugs to examine in vitro the mechanisms and the nature of the DNA-drug interactions responsible for two phenomena: inhibition of excision repair by caffeine and other noncovalent DNA binding compounds; incision of undamaged DNA produced by (A)BC excinuclease in the presence of the bisintercalating drug ditercalinium. All of the chemicals examined (e.g., actinomycin D, caffeine, ethidium bromide, and Hoechst 33258) inhibited incision of a covalent adduct by (A)BC excinuclease, and direct evidence is given for a common mechanism in which UvrA is depleted by binding to drug-undamaged DNA complexes. In the absence of significant amounts of undamaged DNA, another mechanism of inhibition was observed, in which enzyme bound to noncovalent drug-DNA complexes in the vicinity of the lesion prevents formation of preincision complexes at the lesion. Ditercalinium and unexpectedly all of the other drugs examined promoted the incision of undamaged DNA when the enzyme was present at high concentration. Thus, this activity contrary to previous assumptions is not unique to bisintercalators. Another unexpected finding was stimulation of incision at certain sites of photodamage in DNA produced by low concentrations of noncovalent DNA binding chemicals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nucleotide excision repair: from E. coli to man

Nucleotide excision repair is both a 'wide spectrum' DNA repair pathway and the sole system for repairing bulky damages such as UV lesions or benzo[a]pyrene adducts. The mechanisms of nucleotide excision repair are known in considerable detail in Escherichia coli. Similarly, in the past 5 years important advances have been made towards understanding the biochemical mechanisms of excision repair in humans. The overall strategy of the repair is the same in the two species: damage recognition through a multistep mechanism involving a molecular matchmaker and an ATP-dependent unwinding of the damaged duplex; dual incisions at both sides of the lesion by two different nucleases, the 3' incision being followed by the 5'; removal of the damaged oligomer; resynthesis of the repair patch, whose length matches the gap size. Despite these similarities, the two systems are biochemically different and do not even share structural homology. E. coli excinuclease employs three proteins in contrast to 16/17 polypeptides in man; the excised fragment is longer in man: the procaryotic excinuclease is not able by itself to remove the excised oligomer whereas the human enzyme does. Thus, the excinuclease mode of action is well conserved throughout evolution, but not the biochemical tools: this represents a case of evolutionary convergence.     

Repair of N-methyl-N''-nitro-N-nitrosoguanidine-induced DNA damage by ABC excinuclease.

Escherichia coli has several overlapping DNA repair pathways which act in concert to eliminate the DNA damage caused by a diverse array of physical and chemical agents. The ABC excinuclease which is encoded by the uvrA, uvrB, and uvrC genes mediates both the incision and excision steps of nucleotide excision repair. Traditionally, this repair pathway has been assumed to be active against DNA adducts that cause major helical distortions. To determine the level of helical deformity required for recognition and repair by ABC excinuclease, we have evaluated the substrate specificity of this enzyme by using DNA damaged by N-methyl-N'-nitro-N-nitrosoguanidine. ABC excinuclease incised methylated DNA in vitro in a dose-dependent manner in a reaction that was ATP dependent and specific for the fully reconstituted enzyme. In vivo studies with various alkylation repair-deficient mutants indicated that the excinuclease participated in the repair of DNA damage induced by N-methyl-N'-nitro-N-nitrosoguanidine.     

Human and E.coli excinucleases are affected differently by the sequence context of acetylaminofluorene-guanine adduct.

Synthetic DNA substrates containing an acetylaminofluorene (AAF) adduct at each of the three guanine in the G1G2CG3CC sequence were constructed and tested as substrates for reconstituted E.coli (A)BC excinuclease and human excinuclease in HeLa cell-free extract (CFE). The (A)BC excinulcease repaired the three substrates with relative efficiencies of G1:G2:G3 of 100:18:66 in agreement with an earlier report [Seeberg, E., and Fuchs, R.P.P. (1990) Proc. Natl Acad. Sci. USA 87, 191-194]. The same lesions were repaired by the human excinuclease with the strikingly different efficiencies of G1:G2:G3 as 38:100:68. These results reveal that the human excinuclease is affected by the sequence context of the lesion in a different manner than its prokaryotic counterpart.     

Sequence effect on incision by (A)BC excinuclease of 4NQO adducts and UV photoproducts.

Nucleotide excision repair in Escherichia coli is initiated by (A)BC excinuclease, an enzyme which incises DNA on both sides of bulky adducts and removes the damaged nucleotide as a 12-13 base long oligomer. The incision pattern of the enzyme was examined using DNA modified by 4-nitroquinoline 1-oxide (4NQO) and UV light. Similar to the cleavage pattern of UV photoproducts and other bulky adducts, the enzyme incises the 8th phosphodiester bond 5' and 5th phosphodiester bond 3' to the 4NQO-modifed base, primarily guanine. The extent of DNA damage by these agents was determined using techniques which quantitatively cleave the DNA or stop at the site of the adduct. By comparison of the intensity of gel bands created by (A)BC excinuclease and the specific cleavage at the damaged site, the efficiency of (A)BC excinuclease incision at 13 different 4NQO-induced adducts and 13 different photoproducts was determined by densitometric scanning. In general, incisions made at 4NQO-induced adducts are proportional to the extent of damage, though the efficiency of cutting throughout the sequence tested varies from 25 to 75%. Incisions made at pyrimidine dimers are less efficient than at 4NQO-adducts, ranging from 13 to 65% incision relative to modification, though most are around 50%. The two (6-4) photoproducts within the region tested are incised more efficiently than any pyrimidine dimer.     

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

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

Utilization of DNA photolyase, pyrimidine dimer endonucleases, and alkali hydrolysis in the analysis of aberrant ABC excinuclease incisions adjacent to UV-induced DNA photoproducts.

ABC excinuclease of Escherichia coli removes 6-4 photoproducts and pyrimidine dimers from DNA by making two single strand incisions, one 8 phosphodiester bonds 5' and another 4 or 5 phosphodiester bonds 3' to the lesion. We describe in this communication a method, which utilizes DNA photolyase from E. coli, pyrimidine dimer endonucleases from M. luteus and bacteriophage T4, and alkali hydrolysis, for analyzing the ABC excinuclease incision pattern corresponding to each of these photoproducts in a DNA fragment. On occasion, ABC excinuclease does not incise DNA exclusively 8 phosphodiester bonds 5' or 4 or 5 phosphodiester bonds 3' to the photoproduct. Both the nature of the adduct (6-4 photoproduct or pyrimidine dimer) and the sequence of neighboring nucleotides influence the incision pattern of ABC excinuclease. We show directly that photolyase stimulates the removal of pyrimidine dimers (but not 6-4 photoproducts) by the excinuclease. Also, photolyase does not repair CC pyrimidine dimers efficiently while it does repair TT or TC pyrimidine dimers.     

RecA-dependent incision of psoralen-crosslinked DNA by (A)BC excinuclease.

Previous work to elucidate the mechanism of crosslink repair by (A)BC excinuclease has shown that a psoralen-crosslinked duplex is selectively incised in the furan-side strand, while a three-stranded structure is incised in the pyrone-side strand of the crosslink. These observations support a sequential incision and recombination model for the complete error-free repair of a psoralen crosslink. The work presented here extends these findings by demonstrating that in the presence of RecA protein and a homologous DNA oligonucleotide, (A)BC excinuclease is induced to incise the pyrone-side strand of a crosslinked double-stranded plasmid molecule. This finding adds further support to the current model for error-free crosslink repair.     

Microinjection of Escherichia coli UvrA, B, C and D proteins into fibroblasts of xeroderma pigmentosum complementation groups A and C does not result in restoration of UV-induced unscheduled DNA synthesis

The UV-induced unscheduled DNA synthesis (UDS) in cultured human fibroblasts of repair-deficient xeroderma pigmentosum complementation groups A and C was assayed after injection of identical activities of either Uvr excinuclease (UvrA, B, C and D) from Escherichia coli or endonuclease V from phage T4. Under conditions where the T4 enzyme was able to induce repair synthesis in both XP complementation groups in agreement with earlier observations (de Jonge et al., 1985), no effect of the UvrABCD excinuclease could be observed either when the enzymatic complex was injected into the cytoplasm, or when it was delivered directly into the nucleus. In addition, no effect of the E. coli excinuclease was found on the repair ability of normal repair-proficient human fibroblasts. We conclude that the UvrABCD excinuclease may not work on DNA lesions in human chromatin.     

Escherichia coli uracil- and ethenocytosine-initiated base excision DNA repair: rate-limiting step and patch size distribution

The rate, extent, and DNA synthesis patch size of base excision repair (BER) were measured using Escherichia coli GM31 cell-free extracts and a pGEM (form I) DNA substrate containing a site-specific uracil or ethenocytosine target. The rate of complete BER was stimulated (approximately 3-fold) by adding exogenous E. coli DNA ligase to the cell-free extract, whereas addition of E. coli Ung, Nfo, Fpg, or Pol I did not stimulate BER. Hence, DNA ligation was identified as the rate-limiting step in the E. coli BER pathway. The addition of exogenous DNA polymerase I caused modest inhibition of BER, which was overcome by concomitant addition of DNA ligase. Repair patch size determinations were performed to assess the distribution of DNA synthesis associated with both uracil- and ethenocytosine-initiated BER. During the early phase (0-5 min) of the BER reaction, the large majority of repair events resulted from short patch (1-nucleotide) DNA synthesis. However, during the late phase (>10 min) both short and long (2-20 nucleotide) patches were observed, with long patch BER progressively dominating the repair process. In addition, the patch size distribution was influenced by the ratio of DNA polymerase I to DNA ligase activity in the reaction. A novel mode of BER was identified that involved DNA synthesis tracts of >205 nucleotides in length and termed very-long patch BER. This BER process was dependent upon DNA polymerase I since very-long patch BER was inhibited by DNA polymerase I antibody and addition of excess DNA polymerase I reversed this inhibition.     

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

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

Effect of the diaminocyclohexane carrier ligand on platinum adduct formation, repair, and lethality

Platinum compounds with the diaminocyclohexane (dach) carrier ligand are of particular interest because cell lines that have developed resistance to platinum compounds in general often retain sensitivity to dach-platinum compounds, suggesting that the dach carrier ligand affects the formation, repair, or lethality of platinum-DNA adducts. The effect of the dach ligand on platinum adduct formation was assessed by using the (HaeIII-HindIII)146 fragment of pBR322 treated to give equal amounts of dach- or ethylene-diamine-platinum adducts. The sites of adduct formation were mapped by digestion with Escherichia coli ABC excinuclease. There were no significant effects of the dach carrier ligand on the types or sites of platinum adduct formation. The effect of the dach ligand on platinum adduct repair was determined by using synthetic oligomers designed to have single, specific platinum adducts (G monoadduct; GG, AG, or GNG diadduct) with either the dach or ethylenediamine (en) carrier ligand. These adducts differed significantly in their ability to serve as substrates for ABC excinuclease with GNG greater than or equal to G greater than AG greater than GG. The dach carrier ligand had little effect on the recognition of AG and GG adducts by ABC excinuclease, but significantly improved the ability of ABC excinuclease to excise G monoadducts and GNG diadducts. These data suggest that if the carrier ligand has any effect on the repair of platinum adducts, it is more likely to exert that effect on the repair of platinum monoadducts or GNG diadducts rather than on the more abundant AG or GG diadducts. [14C]Thiourea incorporation was used to quantitate the rate of monoadduct to diadduct conversion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Repair of psoralen and acetylaminofluorene DNA adducts by ABC excinuclease

Escherichia coli UvrA, UvrB and UvrC proteins acting in concert remove the major ultraviolet light-induced photoproduct, the pyrimidine dimer, from DNA in the form of a 12 to 13-nucleotide long single-stranded fragment. In vivo data indicate that the UvrABC enzyme is also capable of removing other nucleotide diadducts as well as certain nucleotide monoadducts from DNA and initiating the repair process that leads to removal of interstrand crosslinks caused by some bifunctional chemical agents. We have determined the action mechanism of the enzyme on nucleotide monoadducts produced by 4'-hydroxymethyl-4,5',8-trimethylpsoralen and N-acetoxy-N-2-acetylaminofluorene. In both cases we find that the enzyme hydrolyzes the eighth phosphodiester bond 5' and the fifth phosphodiester bond 3' to the modified base. This cutting pattern is similar to that observed with diadduct substrate, the only difference being that while the enzyme incises the fourth or fifth phosphodiester bond 3' to the pyrimidine dimer it always hydrolyzes the fifth bond relative to monoadducts. Our results also suggest that ABC excinuclease cuts the same two phosphodiester bonds on both sides of a T whether that T has a psoralen monoadduct or is involved in psoralen-mediated interstrand crosslink.     

Mutagenesis induced by site specifically placed 4''-hydroxymethyl-4,5'',8-trimethylpsoralen adducts.

Closed circular double stranded M13mp19 DNA containing a site-specifically placed HMT (4'-hydroxymethyl-4-5'-8-trimethylpsoralen) monoadduct or crosslink was synthesized in vitro. The damaged DNA were scored for loss of infectivity by transfection into repair proficient or deficient E. coli and into SOS induced E. coli. Mutant phages were detected by the loss of alpha-complementation between the viral and the host Lac Z genes or by the acquisition of resistance to kpn I digestion. Our results indicate that HMT mutagenesis is targeted and that deletion or transversion of the modified thymidine is the predominant sequence change elicited by a monoadduct or a crosslink. Transfection of the monoadducted DNA into a Uvr A deficient strain did not change the mutation pattern but did increase the respective mutation frequencies. Transfection of the crosslinked DNA into a SOS induced host resulted in the appearence of other types of mutations attributable to an increase in both targeted and untargeted mutations.