Characterization of the genome of the Rhodococcus rhodochrous bacteriophage NJL.

Temperate bacteriophage NJL of Rhodococcus rhodochrous has a 49-kb linear double-stranded DNA with cohesive ends (cos). NJL DNA has unique target sites for HindIII and SspI, two target sites each for NheI and ScaI, and no cleavage site for AxyI, DraI, EcoRI, SacI, and SphI. The single-stranded regions of cos ends were ligated to each other with T4 DNA ligase, removed with mung bean nuclease, or blunted with the Klenow large fragment of DNA polymerase I; then the sequences of the cos ends were determined. Comparison of these sequences revealed that the single-stranded regions are complementary and 18 bases long and protrude at the 3' ends; they have the following sequences: 5'-TTGGCACCGTGGGAGGAG-3' and 3'-AACCGTGGCAC CCTCCTC-5'. A physical map of NJL was constructed by a cos mapping method based on information about the structure of the cohesive ends and multiple digestions with restriction endonucleases.     

Specificity of the S1 nuclease from Aspergillus oryzae.

Conditions are described for digesting single-stranded DNA by S1 nuclease without introducing breaks in double-stranded DNA. The enzyme is inhibited by low concentrations of various compounds of phosphate. Under certain conditions S1 nuclease cleaves the strand opposite a nick in bacteriophage T5 DNA; under other conditions, the enzyme cleaves a loop in one strand of heteroduplex lambdaDNA while leaving the opposite strand intact. S1 nuclease makes many single strand breaks in ultraviolet-irradiated duplex lambdaDNA. Superhelical DNA of phiX174 (Form I) is converted first to a relaxed circular molecule (Form II), and then to a linear molecule (Form III) by cleavage at one site per molecule. Since the cleavage occurs at many sites in the population of molecules, the partially single-stranded regions in phiX174 superhelical DNA are not determined by specific nucleotide sequences.     

Hairpin opening by single-strand-specific nucleases.

DNA molecules with covalently sealed (hairpin) ends are probable intermediates in V(D)J recombination. According to current models hairpin ends are opened to produce short single-stranded extensions that are thought to be precursors of a particular type of extra nucleotides, termed P nucleotides, which are frequently present at recombination junctions. Nothing is known about the activities responsible for hairpin opening. We have used two single-strand-specific nucleases to explore the effects of loop sequence on the hairpin opening reaction. Here we show that a variety of hairpin ends are opened by P1 nuclease and mung bean nuclease (MBN) to leave short, 1-2 nt single-stranded extensions. Analysis of 22 different hairpin sequences demonstrates that the terminal 4 nt of the hairpin loop strongly influence the sites of cleavage. Correlation of the nuclease digestion patterns with structural (NMR) data for some of the hairpin loops studied here provides new insights into the structural features recognized by these enzymes.     

Specific cleavage of kinetoplast minicircle DNA from Leishmania tarentolae by mung bean nuclease and identification of several additional minicircle sequence classes

Multiple sequence classes of kinetoplast minicircle DNA from Leishmania tarentolae were cleaved by mung bean nuclease in the presence of formamide, yielding unit length linear molecules which retained the anomalous electrophoretic mobility in acrylamide characteristic of minicircle DNA. No specific cleavage site sequence common to all minicircle sequence classes was apparent, although the main region of nuclease cleavage was localized approximately 350 bp from the unique SmaI restriction site of the conserved region found in all minicircle sequence classes. Covalent closure of the minicircle substrate was not a requirement for cleavage, as linearized network-derived or cloned minicircles were also cleaved by mung bean nuclease at similar locations. The partial sequences of several new minicircle sequence classes released from the network by mung bean nuclease are also reported.     

Activity of single-stranded DNA endonucleases in mung bean is associated with cell division

A single-strand-specific endonuclease from mung bean sprouts is widely usedin molecular biology. However, the biological role of this enzyme is unknown. We studied the spatial and temporal activity of single-stranded DNA endonucleases in mung bean seedling by following enzyme activity that linearizes supercoiled plasmid DNA, a characteristic of this type of enzyme. The formation of a linear molecule from supercoiled DNA was found to occur in two distinguishable steps. The first, which involves introducing a nick into the supercoiled DNA and relaxing it, is very rapid and complete within a few seconds. The second step of cleaving the opposite strand to generate a unit-length linear duplex DNA is a relatively slow process. Analysis of the DNA cleavage sites showed the nuclease preferentially cuts supercoiled DNA at an AT-rich region. Varying levels of nuclease activity could be detected in different tissues of the mung bean seedling. The highest activity was in the root tip and was correlated with histone H1 kinase activity. This implies a link between nuclease activity and cell division. Induction of cell division in mung bean hypocotyls with auxin promoted formation of root primordia and considerably increased the activity of single-stranded DNA endonucleases. The nuclease activity and histone H1 kinase activity were reduced in mung bean cuttings treated with hydroxyurea, but not in cuttings treated with oryzalin. The potential function of single-stranded DNA endonucleases is discussed.     

The major apoptotic endonuclease DFF40/CAD is a deoxyribose-specific and double-strand-specific enzyme

DFF40/CAD endonuclease is primarily responsible for internucleosomal DNA cleavage during the terminal stages of apoptosis. The nuclease specifically introduces DNA double strand breaks into chromatin substrates. Here we performed a detailed study on the specificity of the nuclease using synthetic single-stranded and double-stranded ribo- and deoxyribo-oligonucleotides as substrates. We have found that neither single-stranded DNA, single-stranded RNA, double-stranded RNA nor RNA–DNA heteroduplexes are cleaved by the DFF40/CAD nuclease. Noteworthy, all types of oligonucleotides that are not cleaved by the nuclease inhibit cleavage of double-stranded DNA. We have also observed that in cells undergoing apoptosis in vivo neither the activation of DFF40/CAD nor oligonucleosomal chromatin fragmentation was temporally correlated with either total cellular or nuclear RNA degradation. We conclude that DFF40/CAD is exclusively specific for double-stranded DNA. Jakub Hanus and Magdalena Kalinowska-Herok contributed equally to the work.     

DNA sequence analysis. Terminal sequences of bacteriophage phi80.

Sequences of the cohesive ends and the 3'-terminal regions of phi80 DNA have been determined. Sequences of the cohesive ends were obtained through the use of two standard methods. The first method involved the incorporation of all four labeled deoxyribonucleotides into the phi80 cohesive ends using DNA polymerase I. The DNA was then partially digested with micrococcal nuclease or pancreatic DNase. The products were separated by two-dimensional electrophoresis and characterized by composition, 3'-terminal, and nearest neighbor analyses. The second method involved partial incorporation using one, two, or three labeled deoxyribonucleotides followed by similar analyses. Sequences of the double-stranded regions adjacent to the cohesive ends were determined by three new methods. These methods were: (a) the DNA was specifically labeled at the 3' terminus and then partially degraded. Labeled oligonucleotide products were sequenced by their mobilities on various separation systems. (b) The cohesive ends were enlarged by limited degradation with exonuclease III. After this treatment, the DNA was partially repaired with labeled nucleotides, digested, and the products were analyzed. (c) A synthetic ologonucleotide primer was bound to phi80 DNA which had been repaired with DNA polymerase I, and then partially digested with lambda-exonuclease. The primer was extended into the region of interest by partial repair with labeled nucleotides. The extended primer was isolated and analyzed.     

Fragmentation of Bacillus bacteriophage phi105 DNA by complementary single-stranded DNA in the cohesive ends of the molecule.

The structure of DNA from the temperate Bacillus subtilis phage phi105 was examined by using the restriction endonuclease EcoRI and by sedimentation analysis. The DNA contains six EcoRI cleavage sites. Although eight DNA fragments were identified in the EcoRI digests, the largest of these was shown to consist of the two fragments that carry the cohesive ends of the phage DNA. In neutral gradients, the majority of whole phi105 DNA sedimented as nicked circles and the remainder as oligomers. No unit-length linear structures were detected. The associated cohesive ends could be sealed by DNA ligase from Escherichia coli and could be cleaved by S1 nuclease. On the basis of these results and previously reported studies, it appears that, as isolated from phage particles, phi105 DNA is a circular molecule that is formed from the linear structure by the association of complementary single-stranded DNA.     

The conformation of single-stranded nucleic acids tDNA versus tRNA

Conformational analyses using the single-strand-specific nuclease from mung bean and restriction endonucleases have been performed on a series of DNA fragments related to the sequence of the yeast initiator tRNA(Met). Mung bean nuclease cleaves DNA fragments exclusively in some, but not all, single-stranded regions as predicted by RNA secondary structural rules. Comparison of cleavage patterns of yeast initiator tRNA(Met), tDNA(Met) (a DNA oligomer having the sequence of tRNA(Met] and the anti-tDNA(Met) (the complement of tDNA(Met] suggests that the conformation of the three molecules is very similar. Furthermore, both tDNA and anti-tDNA are cleaved by HhaI and CfoI restriction endonucleases at two GCG/C sites which would be in double-stranded regions (the acceptor and dihydrouridine stem), if the two molecules adopt the tRNA cloverleaf structure. On the other hand, minor cleavage products show that the core region, i.e. the extra loop area, is slightly more exposed in tDNA and in anti-tDNA than in tRNA. Therefore, we submit that the global conformation of nucleic acids is primarily dictated by the interaction of purine and pyrimidine bases with atoms and functional groups common to both RNA and DNA. In this view the 2'-hydroxyl group, in tRNA at least, is an auxiliary structural feature whose role is limited to fostering local interactions, which increase the stability of a given conformation.     

Single-strand-specific nucleases

Single-strand-specific nucleases are multifunctional enzymes and widespread in distribution. Their ability to act selectively on single-stranded nucleic acids and single-stranded regions in double-stranded nucleic acids has led to their extensive application as probes for the structural determination of nucleic acids. Intracellularly, they have been implicated in recombination, repair and replication, whereas extracellular enzymes have a role in nutrition. Although more than 30 single-strand-specific nucleases from various sources have been isolated till now, only a few enzymes (S1 nuclease from Aspergillus oryzae, P1 nuclease from Penicillium citrinum and nucleases from Alteromonas espejiana, Neurospora crassa, Ustilago maydis and mung bean) have been characterized to a significant extent. Recently, some of these enzymes have been cloned, their crystal structures solved and their interactions with different substrates have been established. The detection, purification, characteristics, structure-function correlations, biological role and applications of single-strand-specific nucleases are reviewed.     

Incision at nucleotide insertions/deletions and base pair mismatches by the SP nuclease of spinach

Spinach leaves contain a highly active nuclease called SP. The purified enzyme incises single-stranded DNA, RNA, and double-stranded DNA that has been destabilized by A-T-rich regions and DNA lesions [Strickland et al. (1991) Biochemistry 30, 9749-9756]. This broad range of activity has suggested that SP may be similar to a family of nucleases represented by S1, P1, and the mung bean nuclease. However, unlike these single-stranded nucleases that require acidic pH and low ionic strength conditions, SP has a neutral pH optimum and is active over a wide range of salt concentrations. We have extended these findings and showed that an outstanding substrate for SP is a mismatched DNA duplex. For base-substitution mismatches, SP incises at all mismatches except those containing a guanine residue. SP also cuts at insertion/deletions of one or more nucleotides. Where the extrahelical DNA loop contains one nucleotide, the preference of extrahelical nucleotide is A > T approximately C but undetectable at G. The inability of SP to cut at guanine residues and the favoring of A-T-rich regions distinguish SP from the CEL I family of neutral pH mismatch endonucleases recently discovered in celery and other plants [Oleykowski et al. (1998) Nucleic Acids Res. 26, 4597-4602]. SP, like CEL I, does not turn over after incision at a mismatched site in vitro. Similar to CEL I, the presence of a DNA polymerase or a DNA ligase allows SP to turn over and stimulate its activity in vitro by about 20-fold. The possibility that the SP nuclease may be a natural variant of the CEL I family of mismatch endonucleases is discussed.     

Polynucleotide kinase and aprataxin-like forkhead-associated protein (PALF) acts as both a single-stranded DNA endonuclease and a single-stranded DNA 3' exonuclease and can participate in DNA end joining in a biochemical system

Polynucleotide kinase and aprataxin-like forkhead-associated protein (PALF, also called aprataxin- and PNK-like factor (APLF)) has been shown to have nuclease activity and to use its forkhead-associated domain to bind to x-ray repair complementing defective repair in Chinese hamster cells 4 (XRCC4). Because XRCC4 is a key component of the ligase IV complex that is central to the nonhomologous DNA end joining (NHEJ) pathway, this raises the possibility that PALF might play a role in NHEJ. For this reason, we further studied the nucleolytic properties of PALF, and we searched for any modulation of PALF by NHEJ components. We verified that PALF has 3' exonuclease activity. However, PALF also possesses single-stranded DNA endonuclease activity. This single-stranded DNA endonuclease activity can act at all single-stranded sites except those within four nucleotides 3' of a double-stranded DNA junction, suggesting that PALF minimally requires approximately four nucleotides of single-strandedness. Ku, DNA-dependent protein kinase catalytic subunit, and XRCC4-DNA ligase IV do not modulate PALF nuclease activity on single-stranded DNA or overhangs of duplex substrates. PALF does not open DNA hairpins. However, in a reconstituted end joining assay that includes Ku, XRCC4-DNA ligase IV, and PALF, PALF is able to resect 3' overhanging nucleotides and permit XRCC4-DNA ligase IV to complete the joining process in a manner that is as efficient as Artemis. Reduction of PALF in vivo reduces the joining of incompatible DNA ends. Hence, PALF can function in concert with other NHEJ proteins.     

Characterization of bacteriophage N3 DNA.

The DNA from Haemophilus influenzae temperate phage N3 was characterized by centrifugation and by electrophoresis after nuclease digestion. The double-stranded DNA, with a mass of 25.8 X 10(6) daltons, had single-strand cohesive ends. Strand association through cohesion was reduced by heat and removed by S1 nuclease digestion. N3 DNA contained five EcoRI, one KpnI, two SacI, six XbaI, and four XhoI cleavage sites. The cohesive end segments were identified by heating the digests before electrophoresis. This was the first step in the construction of the physical maps of this DNA.     

A novel multistep method for generating precise unidirectional deletions using BspMI, a class-IIS restriction enzyme

A novel approach is described that permits the introduction of unidirectional deletions into a cloned DNA fragment, in a precisely controlled manner. The method is based on the use of a special vector and a class-IIS restriction endonuclease, BspMI, which produces staggered cuts 4 and 8 nucleotides (nt) to the 3' from its recognition site 5'-ACCTGC-3'. The DNA fragment is inserted into the pUC19-based plasmid, which contains a unique BspMI recognition site, and the appropriate number of cleavage-and-deletion cycles is performed, each cycle removing 4 bp. Since the recognition site is not affected by the BspMI cleavage, no recloning of the DNA fragment is necessary. Each cycle consists of BspMI cleavage, removal of the 4-nt single-stranded cohesive ends with mung bean nuclease (MB), and blunt-end ligation to recircularize the plasmid. The shortened plasmid is reintroduced into the host, after one or after several such 4-bp deletion cycles. When DNA is inserted into the multiple cloning site in the lacZ alpha gene, the progress of 4-bp removal can be followed by determining the Lac phenotype, since removal of multiples of 3 bp retains the reading frame while other kinds of deletions distort (or restore) the reading frame. Loss of pre-existing restriction sites or creation of new ones also permits monitoring the progress of the deletion process.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in site specificity of single-strand-specific endonucleases on supercoiled PM2 DNA with temperature and ionic environment.

Mung bean nuclease sites in supercoiled PM2 DNA at neutral pH were located by linearizing the singly-nicked circular DNA product with venom phosphodiesterase followed by restriction endonuclease mapping. The locations of the sites varied with small changes in temperature and in concentration of NaC1 or magnesium ion. Different environmental changes which affect duplex stability in the same direction showed similar effects on the number of sites and in some cases resulted in identical cleavage patterns. Venom phosphodiesterase and P1 nuclease showed cleavage patterns similar to mung bean nuclease under the same environmental conditions and showed similar variations in cleavage patterns when environmental conditions were changed. Relaxed, closed-circular DNA was slowly cleaved at numerous sites whose locations did not vary with environment. Changes in site specificity are likely the result of environmental effects on the conformation of supercoiled DNA as opposed to effects on the single-strand-specific endonucleases themselves.     

Cloning of nascent monkey DNA synthesized early in the cell cycle.

To study the structure and complexity of animal cell replication origins, we have isolated and cloned nascent DNA from the onset of S phase as follows: African green monkey kidney cells arrested in G1 phase were serum stimulated in the presence of the DNA replication inhibitor aphidicolin. After 18 h, the drug was removed, and DNA synthesis was allowed to proceed in vivo for 1 min. Nuclei were then prepared, and DNA synthesis was briefly continued in the presence of Hg-dCTP. The mercury-labeled nascent DNA was purified in double-stranded form by extrusion (M. Zannis-Hadjopoulos, M. Perisco, and R. G. Martin, Cell 27:155-163, 1981) followed by sulfhydryl-agarose affinity chromatography. Purified nascent DNA (ca. 500 to 2,000 base pairs) was treated with mung bean nuclease to remove single-stranded ends and inserted into the NruI site of plasmid pBR322. The cloned fragments were examined for their time of replication by hybridization to cellular DNA fractions synthesized at various intervals of the S phase. Among five clones examined, four hybridized preferentially with early replicating fractions.     

Mung bean nuclease exhibits a generalized gene-excision activity upon purified Plasmodium falciparum genomic DNA.

A novel set of reaction conditions for mung bean nuclease has been described in which Plasmodium genes were specifically excised as intact fragments from purified DNA. We have now determined that under the new conditions mung bean nuclease cleaves precisely at sites outside of the coding region of every P. falciparum gene for which the extent of the protein coding region in genomic DNA is known. We conclude that this enzyme activity is probably a general one for P. falciparum genes. Introns are not specifically cleaved, although one gene contained a cleavage site within an intron. There is no direct relationship between dA.dT-richness and sites of cleavage under these conditions. Also contrary to the expectations of a model based on cleavage at denaturation bubbles, there was no general relationship between the concentration of the DNA denaturant, formamide, and the size of the resulting gene-containing fragments. Thus, the data strongly suggest the involvement of an altered DNA structure near gene boundaries in determining the recognition sites for this enzyme activity.