Endonuclease VII of phage T4 nicks N-2-acetylaminofluorene-induced DNA structures in vitro

Role of DNA repair in the protection against genotoxic stress

The genome of all organisms is constantly attacked by a variety of environmental and endogenous mutagens that cause cell death, apoptosis, senescence, genetic diseases and cancer. To mitigate these deleterious endpoints of genotoxic reactions, living organisms have evolved one or more mechanisms for repairing every type of naturally occurring DNA lesion. For example, double-strand breaks are rapidly religated by non-homologous end-joining. Homologous recombination is used for the high-fidelity repair of interstrand cross-links, double-strand breaks and other DNA injuries that disrupt the replication fork. Some genotoxic lesions inflicted by alkylating agents can be repaired by direct reversal of DNA damage. The base excision repair pathway takes advantage of multiple DNA glycosylases to remove modified or incorrect bases. Finally, the nucleotide excision repair machinery provides a versatile strategy to monitor DNA quality and eliminate all forms of helix-distorting DNA lesions, including a wide diversity of carcinogen adducts. The efficiency of DNA repair responses is enhanced by their coupling to transcription and coordination with the cell cycle circuit.

DNA repair triggered by sensors of helical dynamics

Nucleotide excision repair is a constitutive stress response that eliminates DNA lesions induced by multiple genotoxic agents. Unlike the immune system, which generates billions of immunoglobulins and T cell receptors for antigen recognition, the nucleotide excision repair complex uses only a few generic factors to detect an astounding diversity of DNA modifications. New data favor an unexpected strategy whereby damage recognition is initiated by the detection of abnormal oscillations in the undamaged strand opposite to DNA lesions. Another core subunit recognizes the increased susceptibility of DNA to be kinked at injured sites. We suggest that early nucleotide excision repair factors gain substrate versatility by avoiding direct contacts with modified residues and exploiting instead the altered dynamics of damaged DNA duplexes.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Restriction site mutation (RSM) analysis of 2-acetylaminofluorene (2-AAF)-induced mouse liver mutations and comparison with the measurement of in vivo micronucleus induction in the bone marrows of (2-AAF)-treated mice

We report here the successful application of the restriction site mutation (RSM) assay in detecting 2-acetylaminofluorene (2-AAF)-induced mouse liver mutations. A total of seven 2-AAF-induced liver mutations were detected out of a total of 304 analyses performed on 2-AAF-treated liver tissue. No mutations were detected in the 190 RSM analyses performed on untreated liver tissue. The 2-AAF-induced point mutations comprised 60% GC-->TA transversions, 30% GC-->AT transitions, 10% GC-->CG transversions, and 1 insertional event was also detected. All seven mutations were detected in intron 6 of the mouse p53 gene, with no mutations detectable in exons 4 or 5, supporting our previous data on the greater mutability of intron regions. In addition to the RSM analysis, we also report the application of the in vivo bone marrow micronucleus assay in detecting the clastogenicity of 2-AAF. We detected a small, but statistically significant, increase in the number of micronuclei induced by 2-AAF, but only after 2,000 cells were scored. This also confirms previous data showing that 2-AAF is a weak clastogen. Finally, we attempted to compare the sensitivity of the two assays to 2-AAF-induced genotoxicity, as had been previously undertaken with ENU. Both assays detected genotoxicity in their respective tissues; however, different endpoints were analysed. The RSM assay appears to be more adaptable than the micronucleus assay, due to its tissue and organism independence and has the potential to provide more molecular information on genotoxicity. Teratogenesis Carcinog. Mutagen. 20:107-117, 2000.

Localization and characterization of the dimerization domain of holliday structure resolving endonuclease VII of phage T4

Endonuclease VII (Endo VII) is a Holliday structure resolving enzyme of bacteriophage T4. Its nucleolytic activity depends on subactivities, which in order of execution are: (i) dimerization, (ii) binding to DNA, (iii) and cleavage of DNA. In an effort to assign these subfunctions to the primary sequence of the protein, a series of spontaneous point mutations deficient in DNA cleavage was isolated. Some of these mutations affected the dimerization of Endo VII. Compared with wild-type protein, which dimerizes completely in solution, more than 95% of one of the mutant proteins (W87R) remained in the monomeric state. Only the dimeric fraction of this protein bound to DNA. The dimerization domain of Endo VII was mapped by truncating the gene from both ends and analysing the dimerization ability of the purified peptides by crosslinking with glutaraldehyde. The dimerization domain was thus determined to reside between amino acid residues 55 and 105. Computer analyses predicted two alpha-helices (H2 and H3) in this section of the protein. As demonstrated by heterodimer formation, two copies of helix H3, but only one copy of helix H2, are required for dimerization. Helical wheel analyses revealed that both helices expose a hydrophobic face along their axes, suggesting that hydrophobic interaction between helices H3 mediate formation of Endo VII dimers, while helices H2 stabilize them.

Processing of recombination intermediates by the RuvABC proteins

The RuvA, RuvB, and RuvC proteins in Escherichia coli play important roles in the late stages of homologous genetic recombination and the recombinational repair of damaged DNA. Two proteins, RuvA and RuvB, form a complex that promotes ATP-dependent branch migration of Holliday junctions, a process that is important for the formation of heteroduplex DNA. Individual roles for each protein have been defined, with RuvA acting as a specificity factor that targets RuvB, the branch migration motor to the junction. Structural studies indicate that two RuvA tetramers sandwich the junction and hold it in an unfolded square-planar configuration. Hexameric rings of RuvB face each other across the junction and promote a novel dual helicase action that "pumps" DNA through the RuvAB complex, using the free energy provided by ATP hydrolysis. The third protein, RuvC endonuclease, resolves the Holliday junction by introducing nicks into two DNA strands. Genetic and biochemical studies indicate that branch migration and resolution are coupled by direct interactions between the three proteins, possibly by the formation of a RuvABC complex.

A new Holliday junction resolving enzyme from Schizosaccharomyces pombe that is homologous to CCE1 from Saccharomyces cerevisiae

The resolution of Holliday junctions is a critical stage in recombination. We describe the identification and initial biochemical characterisation of a new Holliday junction resolvase from Schizosaccharomyces pombe. Resolvase activity was initially detected in partially purified cell-free extracts of S. pombe. Resolution of X-junction DNA occurred by the introduction of symmetrical cuts in strands of the same polarity. All cuts occurred 3' of thymine nucleotides with a possible preference for cleavage one nucleotide 3' from the point of strand crossover. During the course of these studies, a potential S. pombe homologue of the Saccharomyces cerevisiae Cruciform Cutting Endonuclease I was identified in the database (SpCCE1). The gene was cloned by PCR, overexpressed in Escherichia coli and its product purified as a His-tagged fusion protein. Purified SpCCE1 binds to X-junctions in a structure-specific manner and resolves them to nicked linear duplex products that are repairable by DNA ligase. SpCCE1 cuts X-junctions in precisely the same way as the resolvase activity from partially purified extracts of S. pombe, indicating that they are probably the same. Finally, we show that SpCCE1 can function as a Holliday junction resolvase in vivo by its ability to complement a resolvase-deficient strain of E. coli.

Recognition and manipulation of branched DNA structure by junction-resolving enzymes

The junction-resolving enzymes are a class of nucleases that introduce paired cleavages into four-way DNA junctions. They are important in DNA recombination and repair, and are found throughout nature, from eubacteria and their bacteriophages through to higher eukaryotes and their viruses. These enzymes exhibit structure-selective binding to DNA junctions; although cleavage may be more or less sequence-dependent, binding affinity is purely related to the branched structure of the DNA. Binding and cleavage events can be separated for a number of the enzymes by mutagenesis, and mutant proteins that are defective in cleavage while retaining normal junction-selective binding have been isolated. Critical acidic residues have been identified in several resolving enzymes, suggesting a role in the coordination of metal ions that probably deliver the hydrolytic water molecule. The resolving enzymes all bind to junctions in dimeric form, and the subunits introduce independent cleavages within the lifetime of the enzyme-junction complex to ensure resolution of the four-way junction. In addition to recognising the structure of the junction, recent data from four different junction-resolving enzymes indicate that they also manipulate the global structure. In some cases this results in severe distortion of the folded structure of the junction. Understanding the recognition and manipulation of DNA structure by these enzymes is a fascinating challenge in molecular recognition.

Identification of amino acids of endonuclease VII essential for binding and cleavage of cruciform DNA

Endonuclease VII is a Holliday-structure-resolving enzyme of bacteriophage T4. The active protein is a homodimer with 157 amino acids/monomer. An amber mutation (amE727 in codon 151) inactivates the nuclease completely, indicating the importance of the seven C-terminal amino acids for nucleolytic activity. The influence of these amino acids on cruciform-DNA binding and cleavage was investigated through functional analysis of C-terminal-truncated proteins derived from deletion constructs. It was found that the three C-terminal amino acids are not necessary for binding and cleavage. A transition from active to inactive protein occurs gradually with truncations of the next four amino acids. Reduction of DNA-binding ability, as measured by electrophoretic mobility shift assays, was determined to be the primary defect in the cleavage-deficient proteins. This was further concluded by the finding that EVII-(1-150)-peptide(amber), a protein with fairly low affinity to cruciform DNA, contributes cleavage activity to reactions of wild-type EVII with cruciform DNA. [Asp62]EVII-(1-156)-peptide lacking one C-terminal amino acid, contains a point mutation in codon 62 that eliminates the nucleolytic activity of the protein while retaining its DNA-binding proficiency. By mixing binding-deficient and cleavage-deficient mutants in the same assay, cleavage of cruciform DNA resumed. Evidence is presented that complementation occurs by heterodimer formation. Our results show that the zinc-binding motif of EVII is not sufficient for cruciform-DNA binding.

The RuvC protein dimer resolves Holliday junctions by a dual incision mechanism that involves base-specific contacts

The Escherichia coli RuvC protein resolves DNA intermediates produced during genetic recombination. In vitro, RuvC binds specifically to Holliday junctions and resolves them by the introduction of nicks into two strands of like polarity. In contrast to junction recognition, which occurs without regard for DNA sequence, resolution occurs preferentially at sequences that exhibit the consensus 5'-(A/T)TT/(G/C)-3' (where / indicates the site of incision). Synthetic Holliday junctions containing modified cleavage sequences have been used to investigate the mechanism of cleavage. The results indicate that specific DNA sequences are required for the correct docking of DNA into the two active sites of the RuvC dimer. In addition, using chemically modified oligonucleotides to introduce a hydrolysis-resistant 3'-S-phosphorothiolate linkage at the cleavage site, it was found that, as long as the sequence requirements are fulfilled, the two incisions could be uncoupled from each other. These results indicate that RuvC protein resolves Holliday junctions by a mechanism similar to that exhibited by certain restriction enzymes.

Mutagenicity and mutation spectra of 2-acetylaminofluorene at frameshift and base-substitution alleles in four DNA repair backgrounds of Salmonella

We used colony probe hybridization procedures to determine the mutations in approximately 600 revertants of the -1 frameshift allele hisD3052 and approximately 200 revertants of the base-substitution allele hisG46 of Salmonella typhimurium induced by 2-acetylaminofluorene (2-AAF) in the presence of Aroclor-induced rat liver S9. 2-AAF was primarily a frameshift mutagen, exhibiting 5 times more frameshift than base-substitution activity. The only frameshift mutation 2-AAF induced at the hisD3052 allele was a hotspot (-2) deletion within the sequence CGCGCGCG. The addition of the pKM101 plasmid had a small effect on the mutagenic potency of 2-AAF at this allele in a uvr+ background and no effect on the mutation spectra in either a uvr+ or uvr- background. The small amount of base-substitution activity exhibited by 2-AAF at the hisG46 allele required the presence of both the pKM101 plasmid and the uvrB mutation. The base substitutions were G.C-->T.A transversions (86%) and G.C-->A.T transitions (14%), and 85% of the substitutions were at the second position of the CCC target of the hisG46 allele; the remainder were at the first position. We propose that the hotspot frameshift may be initiated by N-acetyl-2-aminofluorene adducts located at the C(8) position of any of the guanines except the first one in the CGCGCGCG hotspot sequence. The mutation might then result from correct incorporation of cytosine opposite the adducted guanine, followed by a 2-base slippage according to our recently proposed correct-incorporation/slippage model. The hotspot mutation may also result from a 2-AAF-induced B- to Z-DNA transition at the repeating GpC site as well as by the action of enzymes involved in DNA metabolism, such as DNA resolvases or topoisomerases, on DNA structures that have been distorted by 2-AAF adducts. The small amount of 2-AAF-induced base-substitution activity may be due to mispairing of adenine opposite the minor aminofluorene adduct at the C(8) position of guanine.

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.