Structure and Biological Activity of Deoxyribonucleic Acid from Bacillus Bacteriophage φ105: Effects of Escherichia coli Exonucleases

The effects of Escherichia coli exonuclease I, exonuclease III, and deoxyribonucleic acid (DNA) polymerase on the biological activity of mature DNA from temperate Bacillus bacteriophage phi105 were investigated. Intact DNA loses infectivity rapidly upon exposure to exonuclease III. Although there is an overall decrease in marker rescue from exonuclease III-digested DNA, digestion preferentially affects markers at the end of the genetic map. This is taken to indicate a nonpermuted gene sequence in mature DNA. Incubation of mature DNA in the presence of exonuclease I or DNA polymerase has no effect on its biological activity. The possible structure of the ends of mature phi105 DNA is discussed. The rate of digestion of mature phi105 DNA by exonuclease III is only about 1/20 the rate of lambda DNA. Results of digestion of various DNA substrates by exonuclease III indicate that the enzyme distinguishes between different DNA terminal structures.     

Sequence specificity of exonuclease III from E. coli.

The influence of the nucleotide sequence on the digestion of deoxyribonuclease from E. coli, has been investigated. It was found that the rate at which mononucleotides are released varies in a sequence dependent fashion. C-residues are cleaved off rapidly and G-residues slowly while A and T are released at an intermediate rate. Quantitative analyses of digestion experiments with synthetic DNA fragments made it possible to determine rate constants for the cleavage of several dinucleotide bonds by exonuclease III. These values were found to differ by up to a factor of 3. Summation of the differences can lead to appreciable variation in the overall rate of digestion of a DNA strand. The nucleotide specificity of exonuclease III leads to a transient appearance of a series of discrete DNA fragments intermediate in digestion and a stable set of fragments in limit digests, i.e. at the point when all DNA has become single-stranded. This property of exonuclease III needs to be taken into account for the application of the enzyme in the analysis of nucleoprotein complexes.     

An exonuclease III and graphene oxide-aided assay for DNA detection

We have developed a novel DNA assay based on exonuclease III (ExoIII)-induced target recycling and the fluorescence quenching ability of graphene oxide (GO). This assay consists of a linear DNA probe labeled with a fluorophore in the middle. Introduction of target sequence induces the exonuclease III catalyzed probe digestion and generation of single nucleotides. After each cycle of digestion, the target is recycled to realize the amplification. Finally, graphene oxide is added to quench the remaining probes and the signal from the resulting fluorophore labeled single nucleotides is detected. With this approach, a sub-picomolar detection limit can be achieved within 40 min at 37°C. The method was successfully applied to multicolor DNA detection and the analysis of telomerase activity in extracts from cancer cells.     

Detection of neocarzinostatin chromophore-deoxyribose adducts as exonuclease-resistant sites in defined-sequence DNA

A 5'-end-labeled DNA restriction fragment was treated with the nonprotein chromophore of neocarzinostatin under anoxia in the presence of dithiothreitol, conditions known to maximize formation of chromophore-deoxyribose adducts. Under conditions where unmodified DNA was digested to completion, chromophore-treated DNA was highly resistant to digestion by exonuclease III plus the 3'----5' exonucleolytic activity of T4 DNA polymerase and partially resistant to digestion by exonuclease III plus snake venom exonuclease. The electrophoretic mobilities of the products of exonucleolytic digestion suggested that (i) digestion by exonuclease III or T4 polymerase terminated one nucleotide before the nucleotide containing the adduct, (ii) the remaining nucleotide directly adjacent to the adduct (3' side) could be removed by snake venom phosphodiesterase, but at a slow rate, (iii) the covalently linked chromophore decreased the electrophoretic mobilities of the digestion products by the equivalent of approximately three nucleotides, and (iv) adducts formed under anaerobic conditions occurred at the same nucleotide positions as the strand breaks formed under aerobic conditions (primarily at T and, to a lesser extent, A residues). The close similarity in sequence specificity of adducts and strand breaks suggests that a common form of nascent DNA damage may be a precursor to both lesions. A chromophore-induced free radical on C-5' of deoxyribose, subject to competitive fixation by addition reactions with either oxygen or chromophore, is the most likely candidate for such a precursor. The base specificity of adduct formation does not reflect the reported base specificity of neocarzinostatin-induced mutagenesis, suggesting that lesions other than adducts may be responsible for at least some neocarzinostatin-induced mutations, particularly those occurring at G X C base pairs.     

Exonuclease III-based and gold nanoparticle-assisted DNA detection with dual signal amplification

Herein we report a sensitive electrochemical biosensor for DNA detection by making use of exonuclease III and probe DNA functionalized gold nanoparticles. While probe DNA P1 modified on a gold electrode surface can self-hybridize into a stem-loop structure with an exonuclease III-resistant 3' overhang end, in the presence of target DNA, P1 may also hybridize with the target DNA to form a duplex region. Therefore, exonuclease III may selectively digest P1 from its 3'-hydroxyl termini until the duplex is fully consumed. Since a single target DNA can trigger exonuclease III digestion of numerous P1 strands, the first signal amplification is achieved. On the other hand, since the digested P1, exposing its complementary sequence to probe DNA P2, can further hybridize with P2 that has been previously modified on the surface of gold nanoparticles, many nanoparticles loaded with numerous DNA strands are immobilized onto the electrode surface. Consequently, large amount of electroactive molecules [Ru(NH(3))(6)](3+) can bind with the DNA strands to produce an intense electrochemical response as the second signal amplification. Based on the studies with cyclic voltammetry (CV) and chronocoulometry (CC) techniques, the proposed biosensor can sensitively detect specific target DNA at a picomolar level with high specificity.     

Real-time direct observation of single-molecule DNA hydrolysis by exonuclease III

Single-molecule DNA digestion by exonuclease III, which has 3' to 5' exonuclease activity, was analyzed using a micro-channel with two-layer laminar flow. First, a DNA-bead complex was optically trapped in one layer in the absence of exonuclease III permitted the DNA to be stretched by the laminar flow. The exonuclease III reaction was initiated by moving the trapped DNA-bead complex to another layer of flow, which contained exonuclease III. As the reaction proceeded, the fluorescently-stained DNA was observed to shorten. The process was photographed; examination of the photographs showed that the DNA molecule shortened in a linear fashion with respect to the reaction time. The digestion rate obtained from the single-molecule experiment was compared to that measured from a bulk experiment and was found to be ca. 28 times higher than the bulk digestion rate.     

Synthesis by DNA polymerase I on bleomycin-treated deoxyribonucleic acid: a requirement for exonuclease III

phi X174 RFI DNA treated with bleomycin (BLM) under conditions permitting nicking does not serve as a template-primer for Escherichia coli DNA polymerase I. Purified exonuclease III from E. coli and extracts from wild-type E. coli strains are able to convert the BLM-treated DNA to suitable template-primer, but extracts from exonuclease III deficient strains are not. Brief digestion by exonuclease III is enough to create the template-primer, suggesting that the exonuclease III is converting the BLM-treated DNA by a modification of 3' termini. The exonucleolytic rather than the phosphatase activity of exonuclease III appears to be involved in the conversion. Comparative studies with micrococcal nuclease indicate that BLM-created nicks do not have a simple 3'-P structure. Bacterial alkaline phosphatase does not convert BLM-treated DNA to template-primer. The endonuclease VI activity associated with exonuclease III does not incise DNA treated with BLM under conditions not allowing nicking, in contrast to DNA with apurinic sites made by acid treatment, arguing that conversion does not require the endonuclease VI action on uncleaved sites.     

Real-time Direct Observation of Single-molecule DNA Hydrolysis by Exonuclease III

Abstract

Single-molecule DNA digestion by exonuclease III, which has 3′ to 5′ exonuclease activity, was analyzed using a micro-channel with two-layer laminar flow. First, a DNA-bead complex was optically trapped in one layer in the absence of exonuclease III permitted the DNA to be stretched by the laminar flow. The exonuclease III reaction was initiated by moving the trapped DNA-bead complex to another layer of flow, which contained exonuclease III. As the reaction proceeded, the fluorescently-stained DNA was observed to shorten. The process was photographed; examination of the photographs showed that the DNA molecule shortened in a linear fashion with respect to the reaction time. The digestion rate obtained from the single-molecule experiment was compared to that measured from a bulk experiment and was found to be ca. 28 times higher than the bulk digestion rate.     

Identification of a telomeric fragment from the right arm of chromosome III of Aspergillus nidulans

A minimum of 11 bands hybridising to an oligonucleotide complementary to the putative telomeric repeat sequence (TTAGGG)n was visible in a Southern blot of EcoRI-digested Aspergillus nidulans genomic DNA. All 11 were sensitive to BAL 31 exonuclease digestion, consistent with telomeric locations. Blots of DNA from aneuploid strains deleted for a dispensable, extreme distal region on the right arm of chromosome III lack a 1.3-kb EcoRI band, indicating that this fragment is located at or near the chromosome III right arm telomere.     

Processivity of DNA exonucleases.

A homopolymer system has been developed to examine the digestion strategies of DNA exonucleases. Escherichia coli exonuclease I and lambda-exonuclease, are processive enzymes. However, T7 exonuclease, spleen exonuclease, E. coli exonuclease III, the 3' leads to 5'-exonuclease of T4 DNA polymerase, and both the 3' leads to 5' and the 5' leads to 3' activity of E. coli DNA polymerase I dissociate frequently from the substrate during the course of digestion. Regions of duplex DNA are a dissociation signal for exonuclease I.     

Sequencing along DNA fragments cloned in bacteriophage M13 by using internal primers. The sequence analysis of a yeast DNA fragment containing a replication origin

In the `shotgun' procedure for sequencing DNA, DNA fragments are cloned into a phage M13 vector and sequenced by using a flanking primer. In a variation of this procedure a longer DNA sequence is cloned into M13, the two single-stranded recombinants identified and sequenced by using a set of internal primers prepared by exonuclease III digestion of restriction fragments.     

Preparation of plasmid DNA by sequential enzymatic digestion.

A new method for the preparation of plasmid DNA from Escherichia coli, sequential enzymatic digestion, is described. The method is based on sequential and selective enzymatic digestion of all components of E. coli except for the supercoiled plasmid DNA. The key enzymes are exonuclease I and exonuclease III that specifically hydrolyze linear chromosomal DNA and are unable to attack supercoiled plasmid DNA under controlled conditions. Isolated plasmid DNA can be sequenced and digested with restriction enzymes.     

Differential binding of a CCAAT DNA binding factor to the promoters of the mouse alpha 2(I) and alpha 1(III) collagen genes

An exonuclease III assay (Wu, C. (1985) Nature 317, 84-87) was used to identify in nuclear extracts of NIH 3T3 cells a factor which binds to the CCAAT segment of the alpha 2(I) collagen promoter between -80 and -84. This sequence is located on the coding strand in the alpha 2(I) collagen promoter. Binding is specific since only promoter fragments which contain the CCAAT box sequences on one or the other DNA strand inhibit binding to the alpha 2(I) collagen CCAAT box. The CCAAT binding factor protects approximately 26 base pairs of the alpha 2(I) collagen promoter from exonuclease III digestion. Binding to the alpha 2(I) collagen promoter CCAAT box is not inhibited by a fragment of the alpha 1(III) collagen promoter (from -396 to +16), which does not contain a CCAAT sequence on either one or the other strand. Our data suggest that two genes such as the alpha 2(I) and alpha 1(III) collagen genes, which are coordinately expressed in many tissues, are not necessarily regulated by the same trans-acting DNA binding proteins.     

Exoquence DNA sequencing.

We have developed a strategy for DNA sequencing based on exonuclease III digestion followed by double strand specific endonuclease digestion and direct dideoxynucleotide sequencing reaction. This strategy eliminates the need for subcloning, oligonucleotide primers, and prior knowledge of the DNA to be sequenced. All template and primer duplexes needed for sequencing a complete insert can be prepared in one day from uncharacterized starting DNA. Sequence information can be obtained from different regions of the DNA simultaneously. The method uses double-stranded DNA to generate single-stranded template and primer, and thus produces high quality sequence results. Commercially available dideoxy-sequencing kits are well suited for this method. The strategy should be applicable for both automatic and routine laboratory DNA sequencing.     

Bromodeoxyuridine (BrdU) immunocytochemistry by exonuclease III (Exo III) digestion.

A new procedure is described to generate single-stranded DNA by exonuclease III (Exo III) digestion for bromodeoxyuridine (BrdU) immunocytochemistry on tissue sections. We compared this procedure with the most widely used procedure of DNA denaturation with 2 N HCl. In vivo and in vitro pulse and continuous labelling of tissues and cells were used. The specimens were fixed in formalin, ethanol, glutaraldehyde, Carnoy's, Bouin's or Zamboni's fixative and embedded in paraffin or used unfixed as cryostat sections or cytospin preparations. After Exo III digestion, BrdU substituted DNA was detected irrespective of the fixation procedure applied. The optimal protocol for nuclease digestion appeared to be simultaneous incubation, of 10 Units Exo III per ml EcoRI buffer and anti-BrdU monoclonal antibody at 37 degrees C. The advantages of Exo III digestion for BrdU immunocytochemistry compared to acid denaturation were: less non-specific nuclear background reactivity, no DNA renaturation, less DNA loss, optimal nuclear morphology, increase in antibody efficiency and the possibility for simultaneous detection of acid-sensitive tissue constituents. Disadvantages of the Exo III digestion are decreased sensitivity and the need for more rigorous pepsin pretreatment. We conclude that Exo III digestion of DNA is an appropriate alternative for acid denaturation for BrdU immunocytochemistry on sections of pulse-labelled specimens.     

Deletion analysis of a DNA sequence that positions itself precisely on the nucleosome core

Exonuclease III digests DNA sequentially from the 3' end. This enzyme is used to analyse the location of nucleosomes on DNA fragments containing a particular 145 base-pair (bp) sequence. When one of these fragments is assembled into chromatin and digested with exonuclease, a strong and persistent pause in digestion is detected at a single location. That this pause is due to the enzyme encountering a nucleosome is suggested, firstly, by its absence from digests of free DNA and, secondly, by the detection of a corresponding pause on the other strand. The two pauses, 146 bp apart, specify the location of a single precisely positioned nucleosome on the DNA fragment. This position corresponds exactly to one of two possible positions of the 145 bp sequence identified previously. A fragment containing only about 80 bp of the original 145 bp continues to position itself in the nucleosome like the parent sequence. Therefore, some of the sequence can be replaced with different DNA without affecting nucleosome positioning. Further exonuclease III analysis of an extensive set of deletions demonstrates that a central region of about 40 bp is essential for positioning the 145 bp sequence. When deletions advance into this region from either side, only a very small proportion of the DNA remains in the original position on the nucleosome. Therefore, the two short lengths of DNA at the edges of the region must each contain all or part of an essential nucleosome-positioning signal. These two critical sequences are symmetrically located across the nucleosome dyad and interact with the same region of histone H3. The sequence TGC occurs at the same place in both sequences; otherwise they are dissimilar.     

Evidence for palindromic sequences near the termini of adenovirus 2 DNA

When the kinetics of $\text{Escherichia coli}$ exonuclease III digestion of adenovirus 2 DNA were studied by DNA polymerase I-catalyzed repair synthesis at 5°C, there was an indication of the formation of hairpin structure in the single-stranded template, exposed by exonuclease III. The hairpin structure results from a sequence with an inverted repetition of the type, a b c d···d′ c′ b′ a′. The location of these sequences was determined to be about 180 nucleotides from each terminus of adenovirus 2 DNA with the use of specific restriction endonucleases. The possible role of this region in the replication of the adenovirus 2 genome is discussed.     

Adaptor Ligation-Based Polymerase Chain Reaction-Mediated Walking

An improved method of adaptor ligation PCR was developed for isolation of unknown sequences flanking a known DNA sequence. It was determined that the specificity of the adaptor ligation-based walking technique could be significantly enhanced by using uniquely blocked adaptors along with removal of unligated genomic DNA by exonuclease III digestion. This technique was utilized to isolate three novel promoter regions from three differentZea mays(maize) peroxidase genes. Sequences encoding a putative maize 6-phosphogluconate dehydrogenase gene were also isolated and confirmed by sequence analysis. The described improvements could be applied to other existing adaptor ligation-based PCR walking techniques.     

Progress towards single-molecule DNA sequencing: a one color demonstration

Single molecules of fluorescently labeled nucleotides were detected during the cleavage of individual DNA fragments by a processive exonuclease. In these experiments, multiple (10-100) strands of DNA with tetramethyl rhodamine labeled dUMP (TMR-dUMP) incorporated into the sequence were anchored in flow upstream of the detection region of an ultra sensitive flow cytometer. A dilute solution of Exonuclease I passed over the microspheres. When an exonuclease attached to a strand, processive digestion of that strand began. The liberated, labeled bases flowed through the detection region and were detected at high efficiency at the single-molecule level by laser-induced fluorescence. The digestion of a single strand of DNA by a single exonuclease was discernable in these experiments. This result demonstrates the feasibility of single-molecule DNA sequencing. In addition, these experiments point to a new and practical means of arriving at a consensus sequence by individually reading out identical sequences on multiple fragments.