Characterization of Bacillus subtilis ExoA protein: a multifunctional DNA-repair enzyme similar to the Escherichia coli exonuclease III.

To discover the physiological role of the Bacillus subtilis ExoA protein, which is similar in amino acid sequence to Escherichia coli exonuclease III, an exoA::Cm disruption was constructed in the chromosomal DNA of B. subtilis. There was no clear difference in tolerance to hydrogen peroxide and alkylating agents between the disruptant and the wild type strain. An expression plasmid of the ExoA in E. coli was constructed by inserting the exoA gene into the expression vector pKP1500. The purified ExoA was used to clarify enzymatic characterizations using synthetic DNA oligomers as substrates. A DNA oligomer containing a 1', 2'-dideoxyribose residue as an AP site, a DNA-RNA chimera oligomer, and a 3' end 32P-labeled oligomer were synthesized. It has been shown that the ExoA has AP endonuclease, 3'-5' exonuclease, ribonuclease H, and 3'-phosphomonoesterase activities. Thus, it has been confirmed that ExoA is a multifunctional DNA-repair enzyme in B. subtilis that is very similar to E. coli exonuclease III except that ExoA has lower 3'-5' exonuclease activity than that of E. coli exonuclease III.     

DNase I-tRNA interaction

Deoxyribonuclease I (DNase I) binds right-handed DNA duplex via a minor groove and the backbone phosphate group with no contact to the major groove. It hydrolyses double-stranded DNA predominantly by a single-stranded nicking mechanism under physiological conditions, in the presence of divalent Mg and Ca cations. Even though DNase-RNA interaction was observed, less is known about the protein-RNA binding mode and the effect of such complexation on both protein and RNA conformations. The aim of this study was to examine the effects of DNase I-tRNA interaction on tRNA and protein conformations. The interaction of DNase I with tRNA is monitored under physiological conditions, in the absence of Mg2+, using constant DNA concentration of 12.5 mM (phosphate) and various protein contents (10 microM to 250 microM). FTIR, UV-visible, and CD spectroscopic methods were used to analyze the protein binding mode, the binding constant, and the effects of polynucleotide-enzyme interaction on both tRNA and protein conformations. Spectroscopic evidence showed major DNase-PO2 and minor groove interactions with overall binding constant of K = 2.1 (+/-0.7) x 10(4) M(-1). The DNase I-tRNA interaction alters protein secondary structure with major reduction of the alpha-helix, and increases the random coil, beta-anti and turn structures, while tRNA remains in the A-conformation. No digestion of tRNA by DNase I was observed in the protein-tRNA complexes.     

DNase I-induced DNA conformation. 2 A structure of a DNase I-octamer complex.

The structure of a complex between DNase I and d(GCGATCGC)2 has been solved by molecular replacement and refined to an R-factor of 0.174 for all data between 6 and 2 A resolution. The nicked octamer duplexes have lost a dinucleotide from the 3' ends of one strand and are hydrogen-bonded across a 2-fold axis to form a quasi-continuous double helix of 14 base-pairs. DNase I is bound in the minor groove of the B-type DNA duplex forming contacts in and along both sides of the minor groove extending over a total of six base-pairs. As a consequence of binding of DNase I to the DNA-substrate the minor groove opens by about 3 A and the duplex bends towards the major groove by about 20 degrees. Apart from these more global distortions the bound duplex also shows significant deviations in local geometry. A major cause for the observed perturbations in the DNA conformation seems to be the stacking type interaction of a tyrosine ring (Y76) with a deoxyribose. In contrast, the enzyme structure is nearly unchanged compared to free DNase I (0.49 A root-mean-square deviations for main-chain atoms) thus providing a rigid framework to which the DNA substrate has to adapt on binding. These results confirm the hypothesis that groove width and stiffness are major factors determining the global sequence dependence of the enzyme's cutting rates. The nicked octamer present in the crystals did not allow us to draw detailed conclusions about the catalytic mechanism but confirmed the location of the active site near H134 on top of the central beta-sheets. A second cut of the DNA induced by diffusion of Mn2+ into the crystals may suggest the presence of a secondary active site in DNase I.     

Physical and biochemical characterization of cloned sbcB and xonA mutations from Escherichia coli K-12.

In Escherichia coli K-12, sbcB/xonA is the structural gene for exonuclease I, an enzyme that hydrolyzes single-stranded DNA to mononucleotides in the 3'-to-5' direction. This enzyme has been implicated in the DNA repair and recombination pathways mediated by the recB and recC gene products (exonuclease V). We have cloned several sbcB/xonA mutant alleles in bacterial plasmids and have partially characterized the cloned genes and their protein products. Two of the mutations (xonA2 and xonA6) retain no detectable exonucleolytic activity on single-stranded DNA. The xonA6 allele was shown to harbor an insertion of an IS30-related genetic element near the 3' end of the gene. Two other mutations, sbcB15 and xonA8, exhibited significantly reduced levels of exonuclease I activity as compared to the cloned wild-type gene. A correlation was observed between levels of exonuclease I activity and the ability of the sbcB/xonA mutations to suppress UV sensitivity in recB and recC strains. Also, recombinant plasmids bearing either the sbcB15 or xonA6 allele exhibited a high degree of instability during growth of their bacterial hosts. The results suggest that the sbcB/xonA gene product is a bi- or multifunctional protein that interacts with single-stranded DNA and possibly with other proteins in the suppression of genetic recombination and DNA-repair deficiencies in recB and recC mutants.     

The exoA gene of Streptococcus pneumoniae and its product, a DNA exonuclease with apurinic endonuclease activity.

The gene encoding the major DNA exonuclease of Streptococcus pneumoniae, exoA, was cloned in a streptococcal host vector system. Its location was determined by subcloning and by insertion mutations. Transfer of a DNA segment containing the gene to an Escherichia coli expression vector showed that exoA was the structural gene for the enzyme and that it was adjacent to its promoter. DNA sequence determination indicated that the gene encoded a protein, ExoA, of molecular weight 31,263. Under hyperexpression conditions, the ExoA protein constituted 10% of total cellular protein. In addition to previously demonstrated 3' to 5' exonuclease and 3'-phosphatase activities, ExoA was shown to make single-strand breaks at apurinic sites in DNA. Its enzymatic activities are thus similar to those of exonuclease III of E. coli and other gram-negative bacteria. The nucleotide sequence of exoA revealed it to be homologous to xth of E. coli, with 26% identity of amino acid residues in the predicted proteins. So far, no null chromosomal mutants of exoA have been obtained, and the biological function of ExoA remains unknown.     

The partition locus of plasmid pSC101 is a specific binding site for DNA gyrase.

A protein in extracts of Escherichia coli that specifically binds the stabilizing par sequence of pSC101 was identified as DNA gyrase. The purified enzyme protects par against digestion by DNase I and exonuclease III. Competition assays demonstrate that gyrase has a 40-fold higher affinity for the 100-bp par sequence than for nonspecific DNA and that par is the major gyrase-binding site in pSC101 derivatives used in this and other studies. Within par, AT-rich sequences occur with a pronounced 10-bp periodicity that is shifted by 5 bp from a similar periodicity of GC-rich sequences. As judged by DNase I digestion, the GC sequences are exposed on the outside of the DNA wrapped around gyrase. The data suggest that the site-specificity of DNA gyrase may be partly determined by the bendability of the DNA. A 4-bp deletion that interferes with Par function in vivo also reduces the affinity for gyrase in vitro. However, a deletion of par causes little reduction in superhelical density in vivo. We conclude that DNA gyrase, while involved in the Par function, may not affect plasmid stability through its supercoiling activity or by an influence on DNA replication.     

Exonuclease activity associated with a multiprotein form of HeLa cell DNA polymerase alpha. Purification and properties of the exonuclease

The DNase that is associated with a multiprotein form of HeLa cell DNA polymerase alpha (polymerase alpha 2) has two distinct exonuclease activities: the major activity initiates hydrolysis from the 3' terminus and the other from the 5' terminus of single-stranded DNA. The two exonuclease activities show identical rates of thermal inactivation and coincidental migration during chromatofocusing, glycerol gradient centrifugation, and nondenaturing polyacrylamide gel electrophoresis of the DNase. Moreover, the purified DNase shows a single protein band of Mr 69,000 following nondenaturing polyacrylamide and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The 3'----5' exonuclease activity hydrolyzes only single-stranded DNA substrates and the products are 5' mononucleotides. This activity recognizes and excizes mismatched bases at the 3' terminus of double-stranded DNA substrates. The 3'----5' exonuclease does not hydrolyze 3' phosphoryl terminated single-stranded DNA substrates. The 5'----3' exonuclease activity also only hydrolyzes single-stranded DNA substrates. The rate of hydrolysis, however is only about 1/25th the rate of the 3'----5' exonuclease. This exonuclease activity requires a 5' single-stranded terminus in order to initiate hydrolysis and does not proceed into double-stranded regions. The products of hydrolysis by 5'----3' exonuclease are also 5' nucleoside monophosphates.     

Site-directed Mutagenesis of the Catalytic Residues of Bovine Pancreatic Deoxyribonuclease I

Bovine pancreatic deoxyribonuclease I (DNase I) is a well characterised endonuclease which cleaves double-stranded DNA to yield 5′ phosphory lated polynucleotides. Co-crystal structures of DNase I with two different oligonucleotides have revealed the presence of several residues (R9, E78, H134, D168, D212 and H252) close to the scissile phosphate. The roles that these amino acids play in the catalytic mechanism have been investigated using site-directed mutagenesis. The following variants were used: R9A, E78T, H134Q, D168S, D212S and H252Q. The kinetics of all six mutants with both DNA and a small chromophoric substrate, thymidine-3′,5′-di(p- nitrophenyl)-phosphate, were studied. Only R9A and E78T showed any significant turnover of the two substrates. D168S, H134Q, D212S and H252Q showed vanishingly low activities towards DNA and no detectable activity with thymidine-3′,5′-di-n(p-nitrophenyl)-phosphate. These results demonstrate that H134, D168, D212 and H252 play a critical role in the catalytic mechanism. It is suggested that H134 and H252 (which are hydrogen-bonded to E78 and D212, respectively) provided general acid and general base catalysis. DNase I also requires Mg^{2 +}and E39 has been identified as a ligand for this metal ion. We propose that D168 serves as a ligand for a second Mg^{2 +}, and thus DNase I, uses a two metal-ion hydrolytic mechanism. Both magnesium ions are used to supply electrophilic catalysis. Role assignment is based on the mutagenesis results, structural information, homologies between DNase I from different species and a comparison with exonuclease III. However, it is still not feasible to unequivocally assign a particular catalytic role to each amino acid/metal ion.     

Site-directed mutagenesis of the human DNA repair enzyme HAP1: identification of residues important for AP endonuclease and RNase H activity.

HAP1 protein, the major apurinic/apyrimidinic (AP) endonuclease in human cells, is a member of a homologous family of multifunctional DNA repair enzymes including the Escherichia coli exonuclease III and Drosophila Rrp1 proteins. The most extensively characterised member of this family, exonuclease III, exhibits both DNA- and RNA-specific nuclease activities. Here, we show that the RNase H activity characteristic of exonuclease III has been conserved in the human homologue, although the products resulting from RNA cleavage are dissimilar. To identify residues important for enzymatic activity, five mutant HAP1 proteins containing single amino acid substitutions were purified and analysed in vitro. The substitutions were made at sites of conserved amino acids and targeted either acidic or histidine residues because of their known participation in the active sites of hydrolytic nucleases. One of the mutant proteins (replacement of Asp-219 by alanine) showed a markedly reduced enzymatic activity, consistent with a greatly diminished capacity to bind DNA and RNA. In contrast, replacement of Asp-90, Asp-308 or Glu-96 by alanine led to a reduction in enzymatic activity without significantly compromising nucleic acid binding. Replacement of His-255 by alanine led to only a very small reduction in enzymatic activity. Our data are consistent with the presence of a single catalytic active site for the DNA- and RNA-specific nuclease activities of the HAP1 protein.     

Escherichia coli recA protein protects single-stranded DNA or gapped duplex DNA from degradation by RecBC DNase

RecA- mutants of Escherichia coli extensively degrade their DNA following UV irradiation. Most of this degradation is due to the recBC DNase, which suggests that the recA gene is involved in the control of recBC DNase in vivo. We have shown that purified recA protein inhibits the endonuclease and exonuclease activities of recBC DNase on single-stranded DNA. The extent of inhibition is dependent on the relative concentration of recA protein, recBC DNase, and the DNA substrate; inhibition is greatest when the concentrations of DNA and recBC DNase are low and the concentrations of recA protein is high. At fixed concentrations of recA protein and recBC DNase, inhibition is eliminated at high concentrations of DNA. In the presence of adenosine 5'-O-(3-thiotriphosphate), an ATP analog which stabilizes the binding of recA protein to both single- and double-stranded DNA, recA protein is a more potent inhibitor of the nuclease activities on single-stranded DNA and is a weak inhibitor of the exonuclease activity on double-stranded DNA. Inhibition of the latter is enhanced by oligodeoxynucleotides, which stimulate the binding of recA protein to double-stranded DNA. In the presence of adenosine 5'-O-(3-thiotriphosphate), recA protein also inhibits the action of exonuclease I on single-stranded DNA and of lambda exonuclease on double-stranded DNA. These observations are most consistent with the idea that recA protein protects DNA from recBC DNase by binding to DNA. RecA protein also blocks the endonucleolytic cleavage of gapped circular DNA by recBC DNase. Since both recA protein and recBC DNase have the ability under certain conditions to unwind duplex DNA and to displace strands, we looked for evidence that their combined action would enlarge gaps but found no extensive enlargement. D-loops, a putative intermediate in genetic recombination, are effectively protected against the action of recBC DNase by the E. coli single strand binding protein and by recA protein in the presence of adenosine 5'-O-(3-thiotriphosphate).     

DNA recognition by DNase I

Bovine pancreatic DNase I shows a strong preference for double-stranded substrates and cleaves DNA with strongly varying cutting rates suggesting that the enzyme recognises sequence-dependent structural variations of the DNA double helix. The complicated cleavage pattern indicates that several local as well as global helix parameters influences the cutting frequency of DNase I at a given bond. The high resolution crystal structures of two DNase I-DNA complexes showed that the enzyme binds tightly in the minor groove, and to the sugar-phosphate backbones of both strands, and thereby induces a widening of the minor groove and a bending towards the major grooves. In agreement with biochemical data this suggests that flexibility and minor groove geometry are major parameters determining the cutting rate of DNase I. Experimental observations showing that the sequence environmental of a dinucleotide step strongly affects its cleavage efficiency can be rationalized by that fact that six base pair are in contact with the enzyme. Mutational analysis based on the structural results has identified critical residues for DNA binding and cleavage and has lead to a proposal for the catalytic mechanism.     

The crystal structure of the human DNA repair endonuclease HAP1 suggests the recognition of extra-helical deoxyribose at DNA abasic sites.

The structure of the major human apurinic/ apyrimidinic endonuclease (HAP1) has been solved at 2.2 A resolution. The enzyme consists of two symmetrically related domains of similar topology and has significant structural similarity to both bovine DNase I and its Escherichia coli homologue exonuclease III (EXOIII). A structural comparison of these enzymes reveals three loop regions specific to HAP1 and EXOIII. These loop regions apparently act in DNA abasic site (AP) recognition and cleavage since DNase I, which lacks these loops, correspondingly lacks AP site specificity. The HAP1 structure furthermore suggests a mechanism for AP site binding which involves the recognition of the deoxyribose moiety in an extrahelical conformation, rather than a 'flipped-out' base opposite the AP site.     

An endonucleolytic activity of nuclease TT1 specific for superhelical DNA.

Highly purified nuclease TT1 from T. thermophilus HB8 acts on a linear single- and double-stranded DNA as an exonuclease and produces 5'-mononucleotides either from the 5'- or 3'-terminus. It was found that the enzyme also possesses an endonuclease activity specific for superhelical (form I) and single-stranded circular DNA. Form I of various kinds of DNA (phi X174, PM2, Co1E1 and RF 1010 etc.) is nicked to yield first relaxed circles (form II) and then nicked at the opposite site to yield unit length linear DNA (form III), which is subsequently hydrolyzed from the 5'- or 3'-terminus. A single cleavage of the form I of phi X174 DNA seemed to occur at a limited number of unique sites. Both endonuclease and the known exonuclease activities co-migrate on polyacrylmide gels, show the same pH and temperature optima, are stimulated by Mg2+ and are inactivated by EDTA similarly.     

Cloning,sequence analysis and expression in E. coli of the DNA polymerase I gene from Chloroflexus aurantiacus,a green: nonsulfur eubacterium

We have cloned and sequenced the polA gene from Chloroflexus aurantiacus, a green nonsulfur eubacterium, and expressed the recombinant protein in Escherichia coli. One open reading frame encodes a protein with 942 amino acids showing 38% identity with DNA polymerase I from E. coli. Sequence alignments with other members of DNA polymerase family A and analysis of the separate domains show that the central 3′-5′ exonuclease domain is 30% identical to the corresponding E. coli domain and that three sequence motifs associated with 3′-5′ exonuclease activity are conserved. Also, a protein fraction from E. coli expressing the Chloroflexus polymerase contains a thermostable 3′-5′ exonucleolytic activity, indicating that this activity is present in the enzyme, in agreement with the sequence analysis. The N-terminal 5′-3′ exonuclease domain and the C-terminal polymerase domain show 31 and 46% identity, respectively, with the corresponding E. coli domains and all sequence motifs associated with these two enzymatic activities also are conserved. Since several DNA polymerase I enzymes lack the proofreading activity associated with the central domain it has been suggested that the ancestral polA gene contained only the two more conserved N- and C-terminal domains and that the proofreading 3′-5′ exonuclease domain was introduced later in those eubacterial branches that have this activity. Our data indicate a different scenario where the ancestral polA gene contained both the exonucleolytic activities in addition to the polymerase activity and where several eubacterial branches lost the polymerase-associated proofreading activity during evolution.     

Physical and biological characterization of linear DNA plasmids of the yeast Pichia inositovora

Three cryptic DNA plasmids have been identified in a strain of the yeast Pichia inositovora that are 18, 13, and 10 kbp in size. All are sensitive to digestion by DNase I, restriction endonucleases, and exonuclease III, but are resistant to the activities of RNase A and lambda exonuclease. These results indicate that each plasmid is a linear DNA molecule whose 5' ends are protected. A restriction map has been developed for each of the plasmids, demonstrating that each is unique and confirming their linear nature. The plasmids are a major constituent of DNA prepared from whole cells, but are absent from DNA preparations of purified mitochondria and nuclei, indicating that the plasmids are located in the cytoplasm. These plasmids share many of the physical characteristics described for the linear plasmids of the yeasts Kluyveromyces lactis and Saccharomycopsis crataegensis. Unlike the linear plasmids of K. lactis, however, they appear not to be capable of killer toxin production.     

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.     

Expression and characterization of a DNase I-Fc fusion enzyme

Recombinant human deoxyribonuclease I (DNase I) is an important clinical agent that is inhaled into the airways where it degrades DNA to lower molecular weight fragments, thus reducing the viscoelasticity of sputum and improving the lung function of cystic fibrosis patients. To investigate DNases with potentially improved properties, we constructed a molecular fusion of human DNase I with the hinge and Fc region of human IgG1 heavy chain, creating a DNase I-Fc fusion protein. Infection of Sf9 insect cells with recombinant baculovirus resulted in the expression and secretion of the DNase I-Fc fusion protein. The fusion protein was purified from the culture medium using protein A affinity chromatography followed by desalting by gel filtration and was characterized by amino-terminal sequence, amino acid composition, and a variety of enzyme-linked immunosorbent assays (ELISA) and activity assays. The purified fusion contains DNase I, as determined by a DNase I ELISA and an actin-binding ELISA, and an intact antibody Fc region, which was quantified by an Fc ELISA, in a 2:1 stoichiometric ratio, respectively. The dimeric DNase I-Fc fusion was functionally active in enzymatic DNA digestion assays, albeit about 10-fold less than monomeric DNase I. Cleavage of the DNase I-Fc fusion by papain resulted in a specific activity comparable to the monomeric enzyme. Salt was inhibitory for wild type monomeric DNase I but actually enhanced the activity of the dimeric DNase I-Fc fusion. The DNase I-Fc fusion protein was also less Ca2+-dependent than DNase I itself. These results are consistent with a higher affinity of the dimeric fusion protein to DNA than monomeric DNase I. The engineered DNase I-Fc fusion protein described herein has properties that may have clinical benefits.     

A mouse DNA repair enzyme (APEX nuclease) having exonuclease and apurinic/apyrimidinic endonuclease activities: purification and characterization.

A mouse repair enzyme having priming activity on bleomycin-damaged DNA for DNA polymerase was purified to apparent homogeneity and characterized. The enzyme extracted from permeabilized mouse ascites sarcoma (SR-C3H/He) cells with 0.2 M potassium phosphate buffer (pH 7.5) was purified by successive chromatographies on phosphocellulose, DEAE-cellulose, phosphocellulose (a second time), Sephadex G-100, single-stranded DNA cellulose and hydroxyapatite. The purified enzyme has an Mr of 34,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Enzymatical studies indicated that it is a multifunctional enzyme having exonuclease, apurinic/apyrimidinic endonuclease and phosphatase activities, similar to Escherichia coli exonuclease III. This enzyme is tentatively designated as APEX nuclease for apurinic/apyrimidinic endonuclease and exonuclease activities. The amino acid composition, amino-terminal amino acid sequence and an internal amino acid sequence of APEX nuclease are determined.