The C-terminal half of UvrC protein is sufficient to reconstitute (A)BC excinuclease

UvrC Coordinates an O2-Sensitive [4Fe4S] Cofactor

Recent advances have led to numerous landmark discoveries of [4Fe4S] clusters coordinated by essential enzymes in repair, replication, and transcription across all domains of life. The cofactor has notably been challenging to observe for many nucleic acid processing enzymes due to several factors, including a weak bioinformatic signature of the coordinating cysteines and lability of the metal cofactor. To overcome these challenges, we have used sequence alignments, an anaerobic purification method, iron quantification, and UV-visible and electron paramagnetic resonance spectroscopies to investigate UvrC, the dual-incision endonuclease in the bacterial nucleotide excision repair (NER) pathway. The characteristics of UvrC are consistent with [4Fe4S] coordination with 60-70% cofactor incorporation, and additionally, we show that, bound to UvrC, the [4Fe4S] cofactor is susceptible to oxidative degradation with aggregation of apo species. Importantly, in its holo form with the cofactor bound, UvrC forms high affinity complexes with duplexed DNA substrates; the apparent dissociation constants to well-matched and damaged duplex substrates are 100 ± 20 nM and 80 ± 30 nM, respectively. This high affinity DNA binding contrasts reports made for isolated protein lacking the cofactor. Moreover, using DNA electrochemistry, we find that the cluster coordinated by UvrC is redox-active and participates in DNA-mediated charge transport chemistry with a DNA-bound midpoint potential of 90 mV vs NHE. This work highlights that the [4Fe4S] center is critical to UvrC.

Comparative analysis of two phenotypically-similar but genomically-distinct Burkholderia cenocepacia-specific bacteriophages

Background

Genomic analysis of bacteriophages infecting the Burkholderia cepacia complex (BCC) is an important preliminary step in the development of a phage therapy protocol for these opportunistic pathogens. The objective of this study was to characterize KL1 (vB_BceS_KL1) and AH2 (vB_BceS_AH2), two novel Burkholderia cenocepacia-specific siphoviruses isolated from environmental samples.

Results

KL1 and AH2 exhibit several unique phenotypic similarities: they infect the same B. cenocepacia strains, they require prolonged incubation at 30°C for the formation of plaques at low titres, and they do not form plaques at similar titres following incubation at 37°C. However, despite these similarities, we have determined using whole-genome pyrosequencing that these phages show minimal relatedness to one another. The KL1 genome is 42,832 base pairs (bp) in length and is most closely related to Pseudomonas phage 73 (PA73). In contrast, the AH2 genome is 58,065 bp in length and is most closely related to Burkholderia phage BcepNazgul. Using both BLASTP and HHpred analysis, we have identified and analyzed the putative virion morphogenesis, lysis, DNA binding, and MazG proteins of these two phages. Notably, MazG homologs identified in cyanophages have been predicted to facilitate infection of stationary phase cells and may contribute to the unique plaque phenotype of KL1 and AH2.

Conclusions

The nearly indistinguishable phenotypes but distinct genomes of KL1 and AH2 provide further evidence of both vast diversity and convergent evolution in the BCC-specific phage population.

Purification and characterization of Escherichia coli and human nucleotide excision repair enzyme systems

Nucleotide excision repair is a multicomponent, multistep enzymatic system that removes a wide spectrum of DNA damage by dual incisions in the damaged strand on both sides of the lesion. The basic steps are damage recognition, dual incisions, resynthesis to replace the excised DNA, and ligation. Each step has been studied in vitro using cell extracts or highly purified repair factors and radiolabeled DNA of known sequence with DNA damage at a defined site. This chapter describes procedures for preparation of DNA substrates designed for analysis of damage recognition, either the 5' or the 3' incision event, excision (resulting from concerted dual incisions), and repair synthesis. Excision in Escherichia coli is accomplished by the three-subunit Uvr(A)BC excision nuclease and in humans by six repair factors: XPA, RPA, XPChR23B, TFIIH, XPFERCC1, and XPG. This chapter outlines methods for expression and purification of these essential repair factors and provides protocols for performing each of the in vitro repair assays with either the E. coli or the human excision nuclease.

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

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

Two forms of UvrC protein with different double-stranded DNA binding affinities

Using phosphocellulose followed by single-stranded DNA-cellulose chromatography for purification of UvrC proteins from overproducing cells, we found that UvrC elutes at two peaks: 0.4 m KCl (UvrCI) and 0.6 m KCl (UvrCII). Both forms of UvrC have a major peptide band (>95%) of the same molecular weight and identical N-terminal amino acid sequences, which are consistent with the initiation codon being at the unusual GTG site. Both forms of UvrC are active in incising UV-irradiated, supercoiled phiX-174 replicative form I DNA in the presence of UvrA and UvrB proteins; however, the specific activity of UvrCII is one-fourth that of UvrCI. The molecular weight of UvrCII is four times that of UvrCI on the basis of results of size exclusion chromatography and glutaraldehyde cross-linking reactions, indicating that UvrCII is a tetramer of UvrCI. Functionally, these two forms of UvrC proteins can be distinguished under reaction conditions in which the protein/nucleotide molar ratio is >0.06 by using UV-irradiated, (32)P-labeled DNA fragments as substrates; under these conditions UvrCII is inactive in incision, but UvrCI remains active. The activity of UvrCII in incising UV-irradiated, (32)P- labeled DNA fragments can be restored by adding unirradiated competitive DNA, and the increased level of incision corresponds to a decreased level of UvrCII binding to the substrate DNA. The sites of incision at the 5' and 3' sides of a UV-induced pyrimidine dimer are the same for UvrCI and UvrCII. Nitrocellulose filter binding and gel retardation assays show that UvrCII binds to both UV-irradiated and unirradiated double-stranded DNA with the same affinity (K(a), 9 x 10(8)/m) and in a concentration-dependent manner, whereas UvrCI does not. These two forms of UvrC were also produced by the endogenous uvrC operon. We propose that UvrCII-DNA binding may interfere with Uvr(A)(2)B-DNA damage complex formation. However, because of its low copy number and low binding affinity to DNA, UvrCII may not interfere with Uvr(A)(2)B-DNA damage complex formation in vivo, but instead through double-stranded DNA binding UvrCII may become concentrated at genomic areas and therefore may facilitate nucleotide excision repair.

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

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

Configuration of the catalytic GIY-YIG domain of intron endonuclease I-TevI: coincidence of computational and molecular findings

I-TevI is a member of the GIY-YIG family of homing endonucleases. It is folded into two structural and functional domains, an N-terminal catalytic domain and a C-terminal DNA-binding domain, separated by a flexible linker. In this study we have used genetic analyses, computational sequence analysis andNMR spectroscopy to define the configuration of theN-terminal domain and its relationship to the flexible linker. The catalytic domain is an alpha/beta structure contained within the first 92 amino acids of the 245-amino acid protein followed by an unstructured linker. Remarkably, this structured domain corresponds precisely to the GIY-YIG module defined by sequence comparisons of 57 proteins including more than 30 newly reported members of the family. Although much of the unstructured linker is not essential for activity, residues 93-116 are required, raising the possibility that this region may adopt an alternate conformation upon DNA binding. Two invariant residues of the GIY-YIG module, Arg27 and Glu75, located in alpha-helices, have properties of catalytic residues. Furthermore, the GIY-YIG sequence elements for which the module is named form part of a three-stranded antiparallel beta-sheet that is important for I-TevI structure and function.

Mapping of interaction domains between human repair proteins ERCC1 and XPF

ERCC1-XPF is a heterodimeric protein complexinvolved in nucleotide excision repair and recombinational processes. Like its homologous complex in Saccharomyces cerevisiae , Rad10-Rad1, it acts as a structure-specific DNA endonuclease, cleaving at duplex-single-stranded DNA junctions. In repair, ERCC1-XPF and Rad10-Rad1 make an incision on the the 5'-side of the lesion. No humans with a defect in the ERCC1 subunit of this protein complex have been identified and ERCC1-deficient mice suffer from severe developmental problems and signs of premature aging on top of a repair-deficient phenotype. Xeroderma pigmentosum group F patients carry mutations in the XPF subunit and generally show the clinical symptoms of mild DNA repair deficiency. All XP-F patients examined demonstrate reduced levels of XPF and ERCC1 protein, suggesting that proper complex formation is required for stability of the two proteins. To better understand the molecular and clinical consequences of mutations in the ERCC1-XPF complex, we decided to map the interaction domains between the two subunits. The XPF-binding domain comprises C-terminal residues 224-297 of ERCC1. Intriguingly, this domain resides outside the region of homology with its yeast Rad10 counterpart. The ERCC1-binding domain in XPF maps to C-terminal residues 814-905. ERCC1-XPF complex formation is established by a direct interaction between these two binding domains. A mutation from an XP-F patient that alters the ERCC1-binding domain in XPF indeed affects complex formation with ERCC1.

Function of the homologous regions of the Escherichia coli DNA excision repair proteins UvrB and UvrC in stabilization of the UvrBC-DNA complex and in 3'-incision

The nicking of damaged DNA during the nucleotide excision repair reaction in E. coli, is the result of a multi-step process involving three enzymes, UvrA, UvrB and UvrC. The UvrB protein is loaded on the site of the damage by UvrA, forming a stable UvrB-DNA complex. This complex is recognized by UvrC and in the resulting UvrBC-DNA complex dual incision takes place, first on the 3'-side and next on the 5'-side of the damaged nucleotide. A domain in the C-terminal part of UvrB has been identified to be essential for formation of the specific UvrBC-DNA complex that induces the 3'-incision [1]. The N-terminal half of UvrC contains a region that is homologous to this C-terminal domain of UvrB. Using site-directed mutagenesis of a conserved phenylalanine in the homologous regions of UvrB and UvrC two mutants were constructed, UvrB(F652L) and UvrC(F223L). Both proteins were tested in vitro using a DNA substrate with a defined cisplatin lesion. The protein-DNA and protein-protein interactions were studied using bandshift assays and DNAse I footprinting. We show that both domains are important for the binding of UvrC to the UvrB-DNA complex.

Mutational analysis of the human nucleotide excision repair gene ERCC1

The human DNA repair protein ERCC1 resides in a complex together with the ERCC4, ERCC11 and XP-F correcting activities, thought to perform the 5' strand incision during nucleotide excision repair (NER). Its yeast counterpart, RAD1-RAD10, has an additional engagement in a mitotic recombination pathway, probably required for repair of DNA cross-links. Mutational analysis revealed that the poorly conserved N-terminal 91 amino acids of ERCC1 are dispensable for both repair functions, in contrast to a deletion of only four residues from the C-terminus. A database search revealed a strongly conserved motif in this C-terminus sharing sequence homology with many DNA break processing proteins, indicating that this part is primarily required for the presumed structure-specific endonuclease activity of ERCC1. Most missense mutations in the central region give rise to an unstable protein (complex). Accordingly, we found that free ERCC1 is very rapidly degraded, suggesting that protein-protein interactions provide stability. Survival experiments show that the removal of cross-links requires less ERCC1 than UV repair. This suggests that the ERCC1-dependent step in cross-link repair occurs outside the context of NER and provides an explanation for the phenotype of the human repair syndrome xeroderma pigmentosum group F.

The C-terminal region of the UvrB protein of Escherichia coli contains an important determinant for UvrC binding to the preincision complex but not the catalytic site for 3'-incision

The UvrABC endonuclease from Escherichia coli repairs damage in the DNA by dual incision of the damaged strand on both sides of the lesion. The incisions are in an ordered fashion, first on the 3'-side and next on the 5'-side of the damage, and they are the result of binding of UvrC to the UvrB-DNA preincision complex. In this paper, we show that at least the C-terminal 24 amino acids of UvrB are involved in interaction with UvrC and that this binding is important for the 3'-incision. The C-terminal region of UvrB, which shows homology with a domain of the UvrC protein, is part of a region that is predicted to be able to form a coiled-coil. We therefore propose that UvrB and UvrC interact through the formation of such a structure. The C-terminal region of UvrB only interacts with UvrC when present in the preincision complex, indicating that the conformational change in UvrB accompanying the formation of this complex exposes the UvrC binding domain. Binding of UvrC to the C-terminal region of UvrB is not important for the 5'-incision, suggesting that for this incision a different interaction of UvrC with the UvrB-DNA complex is required. Truncated UvrB mutants that lack up to 99 amino acids from the C terminus still give rise to significant incision (1-2%), indicating that this C-terminal region of UvrB does not participate in the formation of the active site for 3'-incision. This region, however, contains the residue (Glu-640) that was proposed to be involved in 3'-catalysis, since a mutation of the residue (E640A) fails to promote 3'-incision (Lin, J.J., Phillips, A.M., Hearst, J.E., and Sancar, A. (1992) J. Biol. Chem. 267, 17693-17700). We have isolated a mutant UvrB with the same E640A substitution, but this protein shows normal UvrC binding and incision in vitro and also results in normal survival after UV irradiation in vivo. As a consequence of these results, it is still an open question as to whether the catalytic site for 3'-incision is located in UvrB, in UvrC, or is formed by both proteins.

Functions of the gene products of Escherichia coli

A list of currently identified gene products of Escherichia coli is given, together with a bibliography that provides pointers to the literature on each gene product. A scheme to categorize cellular functions is used to classify the gene products of E. coli so far identified. A count shows that the numbers of genes concerned with small-molecule metabolism are on the same order as the numbers concerned with macromolecule biosynthesis and degradation. One large category is the category of tRNAs and their synthetases. Another is the category of transport elements. The categories of cell structure and cellular processes other than metabolism are smaller. Other subjects discussed are the occurrence in the E. coli genome of redundant pairs and groups of genes of identical or closely similar function, as well as variation in the degree of density of genetic information in different parts of the genome.

Nucleotide excision repair

Nucleotide excision repair is the major DNA repair mechanism in all species tested. This repair system is the sole mechanism for removing bulky adducts from DNA, but it repairs essentially all DNA lesions, and thus, in addition to its main function, it plays a back-up role for other repair systems. In both pro- and eukaryotes nucleotide excision is accomplished by a multisubunit ATP-dependent nuclease. The excision nuclease of prokaryotes incises the eighth phosphodiester bond 5' and the fourth or fifth phosphodiester bond 3' to the modified nucleotide and thus excises a 12-13-mer. The excision nuclease of eukaryotes incises the 22nd, 23rd, or 24th phosphodiester bond 5' and the fifth phosphodiester bond 3' to the lesion and thus removes the adduct in a 27-29-mer. A transcription repair coupling factor encoded by the mfd gene in Escherichia coli and the ERCC6 gene in humans directs the excision nuclease to RNA polymerase stalled at a lesion in the transcribed strand and thus ensures preferential repair of this strand compared to the nontranscribed strand.

(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.