Conversion of bovine pancreatic DNase I to a repair endonuclease with a high selectivity for abasic sites

ExoMeg1: a new exonuclease from metagenomic library

DNA repair mechanisms are responsible for maintaining the integrity of DNA and are essential to life. However, our knowledge of DNA repair mechanisms is based on model organisms such as Escherichia coli, and little is known about free living and uncultured microorganisms. In this study, a functional screening was applied in a metagenomic library with the goal of discovering new genes involved in the maintenance of genomic integrity. One clone was identified and the sequence analysis showed an open reading frame homolog to a hypothetical protein annotated as a member of the Exo_Endo_Phos superfamily. This novel enzyme shows 3′-5′ exonuclease activity on single and double strand DNA substrates and it is divalent metal-dependent, EDTA-sensitive and salt resistant. The clone carrying the hypothetical ORF was able to complement strains deficient in recombination or base excision repair, suggesting that the new enzyme may be acting on the repair of single strand breaks with 3′ blockers, which are substrates for these repair pathways. Because this is the first report of an enzyme obtained from a metagenomic approach showing exonuclease activity, it was named ExoMeg1. The metagenomic approach has proved to be a useful tool for identifying new genes of uncultured microorganisms.

DNase I - DNA interaction alters DNA and protein conformations

Human DNase I is an endonuclease that catalyzes the hydrolysis of double-stranded DNA predominantly by a single-stranded nicking mechanism under physiological conditions in the presence of divalent Mg and Ca cations. It binds to the minor groove and the backbone phosphate group and has no contact with the major groove of the right-handed DNA duplex. The aim of this study was to examine the effects of DNase I - DNA complexation on DNA and protein conformations. We monitored the interaction of DNA with DNase I under physiological conditions in the absence of Mg2+, with a constant DNA concentration (12.5 mmol/L; phosphate) and various protein concentrations (10-250 micromol/L). We used Fourier transfrom infrared, UV-visible, and circular dichroism spectroscopic methods to determine the protein binding mode, binding constant, and effects of polynucleotide-enzyme interactions on both DNA and protein conformations. Structural analyses showed major DNase-PO2 binding and minor groove interaction, with an overall binding constant, K, of 5.7 x 10(5) +/- 0.78 x 10(5) (mol/L)-1. We found that the DNase I - DNA interaction altered protein secondary structure, with a major reduction in alpha helix and an increase in beta sheet and random structures, and that a partial B-to-A DNA conformational change occurred. No DNA digestion was observed upon protein-DNA complexation.

AP endonuclease paralogues with distinct activities in DNA repair and bacterial pathogenesis

Oxidative stress is a principal cause of DNA damage, and mechanisms to repair this damage are among the most highly conserved of biological processes. Oxidative stress is also used by phagocytes to attack bacterial pathogens in defence of the host. We have identified and characterised two apurinic/apyrimidinic (AP) endonuclease paralogues in the human pathogen Neisseria meningitidis. The presence of multiple versions of DNA repair enzymes in a single organism is usually thought to reflect redundancy in activities that are essential for cellular viability. We demonstrate here that these two AP endonuclease paralogues have distinct activities in DNA repair: one is a typical Neisserial AP endonuclease (NApe), whereas the other is a specialised 3'-phosphodiesterase Neisserial exonuclease (NExo). The lack of AP endonuclease activity of NExo is shown to be attributable to the presence of a histidine side chain, blocking the abasic ribose-binding site. Both enzymes are necessary for survival of N. meningitidis under oxidative stress and during bloodstream infection. The novel functional pairing of NExo and NApe is widespread among bacteria and appears to have evolved independently on several occasions.

Mutations in the alpha8 loop of human APE1 alter binding and cleavage of DNA containing an abasic site

Recent crystallographic studies reveal loops in human AP endonuclease 1 (APE1) that interact with the major and minor grooves of DNA containing apurinic/apyrimidinic (AP) sites. These loops are postulated to stabilize the DNA helix and the flipped out AP residue. The loop alpha8 interacts with the major groove on the 3' side of the AP site. To determine the essentiality of the amino acids that constitute the alpha8 loop, we created a mutant library containing random nucleotides at codons 222-229 that, in wild-type APE1, specify the sequence NPKGNKKN. Upon expression of the library (2 x 10(6) different clones) in Escherichia coli and multiple rounds of selection with the alkylating agent methyl-methane sulfonate (MMS), we obtained approximately 2 x 10(5) active mutants that complemented the MMS sensitivity of AP endonuclease-deficient E. coli. DNA sequencing showed that active mutants tolerated amino acid substitutions at all eight randomized positions. Basic and uncharged polar amino acids together comprised the majority of substitutions, reflecting the positively charged, polar character of the wild-type loop. Asn-222, Asn-226, and Asn-229 exhibited the least mutability, consistent with x-ray data showing that each asparagine contacts a DNA phosphate. Substitutions at residues 226-229, located nearer to the AP site, that reduced basicity or hydrogen bonding potential, increased Km 2- to 6-fold and decreased AP site binding; substitutions at residues 222-225 exhibited lesser effects. This initial mutational analysis of the alpha8 loop supports and extends the conclusion of crystallographic studies that the loop is important for binding of AP.DNA and AP site incision.

Total sequence decomposition distinguishes functional modules, "molegos" in apurinic/apyrimidinic endonucleases

BACKGROUND

Total sequence decomposition, using the web-based MASIA tool, identifies areas of conservation in aligned protein sequences. By structurally annotating these motifs, the sequence can be parsed into individual building blocks, molecular legos ("molegos"), that can eventually be related to function. Here, the approach is applied to the apurinic/apyrimidinic endonuclease (APE) DNA repair proteins, essential enzymes that have been highly conserved throughout evolution. The APEs, DNase-1 and inositol 5'-polyphosphate phosphatases (IPP) form a superfamily that catalyze metal ion based phosphorolysis, but recognize different substrates.

RESULTS

MASIA decomposition of APE yielded 12 sequence motifs, 10 of which are also structurally conserved within the family and are designated as molegos. The 12 motifs include all the residues known to be essential for DNA cleavage by APE. Five of these molegos are sequentially and structurally conserved in DNase-1 and the IPP family. Correcting the sequence alignment to match the residues at the ends of two of the molegos that are absolutely conserved in each of the three families greatly improved the local structural alignment of APEs, DNase-1 and synaptojanin. Comparing substrate/product binding of molegos common to DNase-1 showed that those distinctive for APEs are not directly involved in cleavage, but establish protein-DNA interactions 3' to the abasic site. These additional bonds enhance both specific binding to damaged DNA and the processivity of APE1.

CONCLUSION

A modular approach can improve structurally predictive alignments of homologous proteins with low sequence identity and reveal residues peripheral to the traditional "active site" that control the specificity of enzymatic activity.

Determinants in nuclease specificity of Ape1 and Ape2, human homologues of Escherichia coli exonuclease III

Abasic sites and non-conventional 3'-ends, e.g. 3'-oxidized fragments (including 3'-phosphate groups) and 3'-mismatched nucleotides, arise at significant frequency in the genome due to spontaneous decay, oxidation or replication errors. To avert the potentially mutagenic or cytotoxic effects of these chromosome modifications/intermediates, organisms are equipped with apurinic/apyrimidinic (AP) endonucleases and 3'-nucleases that initiate repair. Ape1, which shares homology with Escherichia coli exonuclease III (ExoIII), is the major abasic endonuclease in mammals and an important, yet selective, contributor to 3'-end processing. Mammals also possess a second protein (Ape2) with sequence homology to ExoIII, but this protein exhibits comparatively weak AP site-specific and 3'-nuclease activities. Prompted by homology modeling studies, we found that substitutions in the hydrophobic pocket of Ape1 (comprised of F266, W280 and L282) reduce abasic incision potency about fourfold to 450,000-fold, while introduction of an ExoIII-like pocket into Ape2 enhances its AP endonuclease function. We demonstrate that mutations at F266 and W280 of Ape1 increase 3' to 5' DNA exonuclease activity. These results, coupled with prior comparative sequence analysis, indicate that this active-site hydrophobic pocket influences the substrate specificity of a diverse set of sequence-related proteins possessing the conserved four-layered alpha/beta-fold. Lastly, we report that wild-type Ape1 excises 3'-mismatched nucleotides at a rate up to 374-fold higher than correctly base-paired nucleotides, depending greatly on the structure and sequence of the DNA substrate, suggesting a novel, selective role for the human protein in 3'-mismatch repair.

Identification of nuclei associated proteins by 2D-gel electrophoresis and mass spectrometry

In clinical neuroscience as well as in many other clinical disciplines, the completion of the human genome project offers a new possibility to identify and localize the products of the genes, the proteins. Nuclear proteins are synthesized in the cytoplasm and imported into the nucleus by multiple pathways. The mechanisms by which nuclear accumulation of different molecular species occur are unclear but it is apparent that changes in the cellular and molecular events associated with the accumulation of nuclear proteins sometimes precedes transformation of cells into diseased states. The significance of the accumulation and the operation of nuclear proteins remain to be elucidated in detail. Such knowledge will play a key role in the understanding of the regulation of transcription and its disturbances in several of our most devastating diseases. In this paper we present a strategy to identify nuclear associated proteins in small samples by using two-dimensional electrophoresis and mass spectrometry. We have used human blood lymphocytes as a model, but the method should be rather general for any kind of tissue. Twenty two proteins were randomly chosen, and of these 18 proteins were identified by database searching of mass spectrometric data, obtained from in-gel tryptic digests of the spots. Thirteen proteins recently described with nuclear localization and function were identified, and five proteins; calgranulin B, glyceraldehyde-3-phosphate dehydrogenase (G3P2), a TATA-binding protein (ATBP), tubulin beta chain and moesin were also identified as being nuclear associated. The presented data clearly shows of the great role of two-dimensional gel electrophoresis and modern mass spectrometry in the excavation of the protein patterns on the subcellular level, and the ability to use small samples well suited for clinical screening.

The major human abasic endonuclease: formation, consequences and repair of abasic lesions in DNA

DNA continuously suffers the loss of its constituent bases, and thereby, a loss of potentially vital genetic information. Sites of missing bases--termed abasic or apurinic/apyrimidinic (AP) sites--form spontaneously, through damage-induced hydrolytic base release, or by enzyme-catalyzed removal of modified or mismatched bases during base excision repair (BER). In this review, we discuss the structural and biological consequences of abasic lesions in DNA, as well as the multiple repair pathways for such damage, while emphasizing the mechanistic operation of the multi-functional human abasic endonuclease APE1 (or REF-1) and its potential relationship to disease.

New insights into the structure of abasic DNA from molecular dynamics simulations

Abasic (AP) sites constitute a common form of DNA damage, arising from the spontaneous or enzymatic breakage of the N-glycosyl bond and the loss of a nucleotide base. To examine the effects of such damage on DNA structure, especially in the vicinity of the abasic sugar, four 1.5 ns molecular dynamics simulations of double-helical DNA dodecamers with and without a single abasic (tetrahydrofuran, X) lesion in a 5'-d(CXT) context have been performed and analyzed. The results indicate that the abasic site does not maintain a hole or gap in the DNA, but instead perturbs the canonical structure and induces additional flexibility close to the abasic site. In the apurinic simulations (i.e., when a pyrimidine is opposite the AP site), the abasic sugar flipped in and out of the minor groove, and the gap was water filled, except during the occurrence of a novel non-Watson-Crick C-T base pair across the abasic site. The apyrimidinic gap was not penetrated by water until the abasic sugar flipped out and remained extrahelical. Both AP helices showed kinks of 20-30 degrees at the abasic site. The Watson-Crick hydrogen bonds are more transient throughout the DNA double helices containing an abasic site. The abasic sugar displayed an unusually broad range of sugar puckers centered around the northern pucker. The increased motion of the bases and backbone near the abasic site appear to correlate with sequence-dependent helical stability. The data indicate that abasic DNA contorts more easily and in specific ways relative to unmodified DNA, an aspect likely to be important in abasic site recognition and hydrolysis.

Mapping the protein-DNA interface and the metal-binding site of the major human apurinic/apyrimidinic endonuclease

Apurinic/apyrimidinic (AP) endonuclease Ape1 is a key enzyme in the mammalian base excision repair pathway that corrects AP sites in the genome. Ape1 cleaves the phosphodiester bond immediately 5' to AP sites through a hydrolytic reaction involving a divalent metal co-factor. Here, site-directed mutagenesis, chemical footprinting techniques, and molecular dynamics simulations were employed to gain insights into how Ape1 interacts with its metal cation and AP DNA. It was found that Ape1 binds predominantly to the minor groove of AP DNA, and that residues R156 and Y128 contribute to protein-DNA complex stability. Furthermore, the Ape1-AP DNA footprint does not change along its reaction pathway upon active-site coordination of Mg(2+) or in the presence of DNA polymerase beta (polbeta), an interactive protein partner in AP site repair. The DNA region immediately 5' to the abasic residue was determined to be in close proximity to the Ape1 metal-binding site. Experimental evidence is provided that amino acid residues E96, D70, and D308 of Ape1 are involved in metal coordination. Molecular dynamics simulations, starting from the active site of the Ape1 crystal structure, suggest that D70 and E96 bind directly to the metal, while D308 coordinates the cation through the first hydration shell. These studies define the Ape1-AP DNA interface, determine the effect of polbeta on the Ape1-DNA interaction, and reveal new insights into the Ape1 active site and overall protein dynamics.

The role of Mg2+ and specific amino acid residues in the catalytic reaction of the major human abasic endonuclease: new insights from EDTA-resistant incision of acyclic abasic site analogs and site-directed mutagenesis

Ape1, the major protein responsible for excising apurinic/apyrimidinic (AP) sites from DNA, cleaves 5' to natural AP sites via a hydrolytic reaction involving Mg2+. We report here that while Ape1 incision of the AP site analog tetrahydrofuran (F-DNA) was approximately 7300-fold reduced in 4 mM EDTA relative to Mg2+, cleavage of ethane (E-DNA) and propane (P-DNA) acyclic abasic site analogs was only 20 and 30-fold lower, respectively, in EDTA compared to Mg2+. This finding suggests that the primary role of the metal ion is to promote a conformational change in the ring-containing abasic DNA, priming it for enzyme-mediated hydrolysis. Mutating the proposed metal-coordinating residue E96 to A or Q resulted in a approximately 600-fold reduced incision activity for both P and F-DNA in Mg2+compared to wild-type. These mutants, while retaining full binding activity for acyclic P-DNA, were unable to incise this substrate in EDTA, pointing to an alternative or an additional function for E96 besides Mg2+-coordination. Other residues proposed to be involved in metal coordination were mutated (D70A, D70R, D308A and D308S), but displayed a relatively minor loss of incision activity for F and P-DNA in Mg2+, indicating a non-essential function for these amino acid residues. Mutations at Y171 resulted in a 5000-fold reduced incision activity. A Y171H mutant was fourfold less active than a Y171F mutant, providing evidence that Y171 does not operate as the proton donor in catalysis and that the additional role of E96 may be in establishing the appropriate active site environment via a hydrogen-bonding network involving Y171. D210A and D210N mutant proteins exhibited a approximately 25,000-fold reduced incision activity, indicating a critical role for this residue in the catalytic reaction. A D210H mutant was 15 to 20-fold more active than the mutants D210A or D210N, establishing that D210 likely operates as the leaving group proton donor.