Nuclease S1-sensitive sites in multigene families: human U2 small nuclear RNA genes.

We show here that human U2 small nuclear RNA genes contain a 'strong nuclease S1 cleavage site' (SNS1 site), a sequence that is very sensitive to digestion by nuclease S1. This site is located 0.50-0.65 kb downstream of the U2 RNA coding region. It comprises a 0.15-kb region in which (dC-dT)n:(dA-dG)n co-polymeric stretches represent greater than 90% of the sequence. Nuclease S1 is able to excise unit length repeats of the human U2 RNA genes both from cloned fragments and total human genomic DNA. The precise locations of the cleavage sites are dependent on the superhelicity of the substrate DNA. In negatively supercoiled substrates, cleavages are distributed over the entire 0.15-kb region, but in linearized substrates, they occur within a more limited region, mainly at the boundary of the SNS1 site closest to the human U2 RNA coding region. Nuclease S1 cleavage of negatively supercoiled substrates occurs at pHs as high as 7.0; in contrast, cleavage of linearized substrates requires a pH less than 5.0, indicating that supercoiling contributes to the sensitivity of this site. Mung bean nuclease gives results similar to that observed with nuclease S1.     

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.     

Sequence-dependent S1 nuclease hypersensitivity of a heteronomous DNA duplex

Using cloned (dG-dA)n X (dC-dT)n DNA duplexes [GA)n) as models of homopurine-homopyrimidine S1-hypersensitive sites, we show that cleavage of the alternate (non-B, non-Z) DNA structure by S1 nuclease is length-dependent, in both supercoiled and linear forms, which are similar because of the identity of their nicking profiles. However, the length of flanking sequences, the presence of borders, and the DNA topology affect the equilibrium between the alternate structure and B-DNA. The B form of (GA)38 has a 10.4-base pair helical repeat, but the two phosphodiester backbones have different conformations (heteronomous DNA with a dinucleotide repeat unit). Extension experiments reveal that the alternate structure is also heteronomous, in agreement with the nicking patterns generated by S1 and mung bean nucleases and by venom phosphodiesterase. Sensitivity to the latter enzyme at pH 9.0 indicates that the alternate DNA does not appear only in the low pH of the S1 nuclease reaction. Moreover, Hoogsteen G-CH+ base-pairing does not seem to be a prerequisite for the appearance of sensitivity because S1 still recognizes the structure even when all Gs are methylated at N-7. This is consistent with the results of chemical probing of the structure using dimethyl sulfate and diethyl pyrocarbonate at various pH values, which show absence of protection at guanine N-7. However, diethyl pyrocarbonate treatment at low pH results in hyper-reactivity of A residues.     

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.     

Nicking activity on pBR322 DNA of ribosome inactivating proteins from Phytolacca dioica L. leaves

Ribosome-inactivating proteins isolated from Phytolacca dioica L. leaves are rRNA-N-glycosidases, as well as adenine polynucleotide glycosylases. Here we report that some of them cleave supercoiled pBR322 dsDNA, generating relaxed and linear molecules. PD-L1, the glycosylated major form isolated from the winter leaves of adult P . dioica plants, produces both free 3'-OH and 5'-P termini randomly distributed along the DNA molecule, as suggested by labelling experiments with [alpha- 32P]dCTP and [gamma- 32 P]dATP. Moreover, when the reaction is carried out under low-salt conditions, cleavage is observed mainly at a specific site, located downstream of the ampicillin resistance gene (close to position 3200), ending with the deletion of a fragment of approximately 70 nucleotides. This cleavage pattern is similar to that obtained under the same conditions with mung bean nuclease, a single-strand endonuclease. Furthermore, pBR322 DNA treated with PD-L1 shows reduced transforming activity with E . coli HB101 competent cells in comparison to untreated control plasmid DNA.     

Does cruciform DNA provide a recognition signal for DNA-topoisomerase II?

Topoisomerase II displays higher affinity for supercoiled DNA compared to the same relaxed DNA. Moreover, cruciform structures are formed in topologically constrained DNA. Here we report that, using S1 nuclease experiments on supercoiled DNA, hairpin structures are located close to numerous topoisomerase II cleavage sites on the BPV I genome. Therefore, DNA secondary structure may play a role in the recognition mechanism of DNA by topoisomerase II.     

Mung bean nuclease cleavage of a dA + dT-rich sequence or an inverted repeat sequence in supercoiled PM2 DNA depends on ionic environment

We have determined the nucleotide sequences around two alternative sites cleaved in supercoiled PM2 DNA by single-strand-specific mung bean nuclease in different ionic environments. In 10 mM Tris-HC1 (pH 7.0, 37 degrees C), the major site is a dA+dT-rich sequence which maps with a known early denaturation region at 0.75 map units. About 30 cleavages occurred in a 135 bp region. Cleavages were largely excluded at (dA)n . (dT)n (n = 3-7) sequences. Cleavage patterns of this type have not been previously observed in dA+dT-rich sequences. With the addition of 0.1 M NaC1 the major alternative site occurred in a hyphenated inverted repeat sequence 500 bp away (0.70 map units) and did not map to an early denaturation region. One major and 4 minor cleavages occurred in the region between the repeats, suggesting that a hairpin containing at most a 12 bp stem and 10 base loop is recognized. The basis for nuclease recognition of the dA+dT-rich sequence is not clear. The differences in the sequences and cleavage patterns at the alternative sites indicate that their secondary structures differ.     

Subunit assembly and mode of DNA cleavage of the type III restriction endonucleases EcoP1I and EcoP15I

DNA cleavage by type III restriction endonucleases requires two inversely oriented asymmetric recognition sequences and results from ATP-dependent DNA translocation and collision of two enzyme molecules. Here, we characterized the structure and mode of action of the related EcoP1I and EcoP15I enzymes. Analytical ultracentrifugation and gel quantification revealed a common Res(2)Mod(2) subunit stoichiometry. Single alanine substitutions in the putative nuclease active site of ResP1 and ResP15 abolished DNA but not ATP hydrolysis, whilst a substitution in helicase motif VI abolished both activities. Positively supercoiled DNA substrates containing a pair of inversely oriented recognition sites were cleaved inefficiently, whereas the corresponding relaxed and negatively supercoiled substrates were cleaved efficiently, suggesting that DNA overtwisting impedes the convergence of the translocating enzymes. EcoP1I and EcoP15I could co-operate in DNA cleavage on circular substrate containing several EcoP1I sites inversely oriented to a single EcoP15I site; cleavage occurred predominantly at the EcoP15I site. EcoP15I alone showed nicking activity on these molecules, cutting exclusively the top DNA strand at its recognition site. This activity was dependent on enzyme concentration and local DNA sequence. The EcoP1I nuclease mutant greatly stimulated the EcoP15I nicking activity, while the EcoP1I motif VI mutant did not. Moreover, combining an EcoP15I nuclease mutant with wild-type EcoP1I resulted in cutting the bottom DNA strand at the EcoP15I site. These data suggest that double-strand breaks result from top strand cleavage by a Res subunit proximal to the site of cleavage, whilst bottom strand cleavage is catalysed by a Res subunit supplied in trans by the distal endonuclease in the collision complex.     

A vaccinia virus DNase preparation which cross-links superhelical DNA.

Multiple DNA-dependent enzyme activities have been detected in highly purified preparations of a single-strand-specific nuclease from vaccinia virus. These enzyme preparations were extensively purified and characterized by using superhelical DNAs as substrates. In particular, the nuclease activity was monitored by the extent of conversion of supercoiled closed duplex DNA (DNA I) to nicked circular DNA (DNA II), which could subsequently be converted to duplex linear DNA (DNA III) by prolonged incubation with the enzyme. DNA species which were not substrates for the enzyme included relaxed closed duplex DNA, DNA II which had been prepared by nuclease S1 treatment or by photochemical nicking of DNA I, and DNA III. With plasmid pSM1 DNA as substrate, the extent of cleavage of DNA I to DNA II was found to increase with superhelix density above a threshold value of about -0.06. The linear reaction products were examined by gel electrophoresis after restriction enzyme digestion of the DNAs from plasmids pSM1 and pBR322 and of the viral DNAs from bacteriophage phi X174 (replicative form) and simian virus 40, and the map coordinate locations of the scissions were determined. These products were further examined by electron microscopy and by gel electrophoresis under denaturing conditions. Electron micrographs taken under partially denaturing conditions revealed molecules with terminal loops or hairpins such as would result from the introduction of cross-links at the cutting sites. These species exhibited snapback renaturation. The denaturing gel electrophoresis experiments revealed the appearance of new bands at locations consistent with terminal cross-linking. With pSM1 and pBR322 DNAs, this band was shown to contain DNA that was approximately twice the length of a linear single strand. The terminal regions of the cross-linked linear duplex reaction products were sensitive to nuclease S1 but insensitive to proteinase K, suggesting that the structure is a hairpin loop not maintained by a protein linker. A similar structure is found in mature vaccinia virus DNA.     

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.     

Purification and properties of nuclease SP.

Single-strand-specific nucleases are a diverse and important group of enzymes that are able to cleave a variety of DNA structures present in duplex molecules. Nuclease SP, an enzyme from spinach, has been purified to apparent homogeneity, allowing for the unambiguous characterization of a number of its physical properties as well as its DNA strand cleavage specificities. The effects of ionic strength, pH, divalent metal cations, and temperature on nuclease SP activity have been examined in detail. Nuclease SP was found to be quite thermostable and could be stimulated by Co2+. In addition, the cleavage of UV-damaged and undamaged supercoiled plasmid substrates under a variety of conditions suggests that at least two types of structures are recognized and processed by nuclease SP: UV photoproduct-induced distortions and unwound "nuclease hypersensitive sites". These studies indicate that nuclease SP is functionally related to other single-strand-specific nucleases and is a potential enzymatic tool for probing and manipulating various types of DNA structures.     

Variation in the gene encoding a major merozoite surface antigen of the human malaria parasite Plasmodium falciparum.

Plasmodium falciparum merozoites have a variable surface protein of about 195,000 molecular weight which may be involved in strain-specific immunity. We have cloned and sequenced a major portion of the gene encoding this antigen from the CAMP strain and have located sites of preferred mung bean nuclease cleavage around the gene. These sites depend on reaction conditions, but at 40% formamide and 2 units of mung bean nuclease per microgram DNA, the intact gene was excised from the chromosome. Comparison of the CAMP strain gene with the same gene from other strains of P. falciparum by matching available DNA sequences and by DNA hybridization revealed five regions of homology separated by divergent segments. Two of the variable regions encoded three amino acid repeats, predominantly Ser-Gly-Thr and Thr-Glu-Glu. Implications of these findings on the function of the antigen, and possible mechanisms for generation of variants are discussed.     

Non-specific DNAases from the rumen bacterium Prevotella bryantii

Extracellular non-specific nucleases were observed in some strains belonging to the ruminal species of the genus Prevotella, mostly P. brevis and P. bryantii. The nuclease from P. bryantii appeared to be extracellular; it mediates the degradation of the supercoiled plasmid DNA via an open circle intermediate. The cleavage is not site specific although a preference for certain cleavage sites does seem to exist. Our attempts to clone the wild-type P. bryantii B(1)4 nuclease in E. coli strain ER1992 that reports on the DNA damage sustained, were unsuccessful probably due to excessive intracellular nuclease activity that killed the cells bearing the gene for the nuclease. On the other hand, the nuclease from a related strain TCl-1, which has a less active enzyme of the same type, was successfully cloned.     

Specific hydrolysis of the cohesive ends of bacteriophage lambda DNA by three single strand-specific nucleases.

Procedures have been worked out for Aspergillus nuclease S1 and mung been nuclease to quantitatively cleave off both of the 12-nucleotide long, single-stranded cohesive ends of lambdaDNA. This cleavage is indicated by the almost complete elimination of the repair incorporation of radioactive nucleotides by DNA polymerase into the digested DNA. With S1 nuclease, cleavage was complete at 10 degrees as well as at 30 degrees. Under the conditions for quantitative cleavage of the single-stranded regions there was no digestion of the double-stranded lambdaDNA. The mung bean nuclease cleaved off the cohesive ends completely at 30 degrees but at 5 degrees, the cleavage was not complete even at high enzyme concentration. The nearest neighbor analysis of the repaired DNA indicates that at 5 degrees about four nucleotides remained undigested. The mung bean nuclease also introduced, under the conditions used, some nicks into double-stranded DNA as determined by the repair incorporation. The Escherichia coli exonuclease VII cleaved off part of the cohesive ends of lambdaDNA, leaving two nucleotides on each end as single-stranded tails.     

High sequence specificity of micrococcal nuclease.

The substrate specificity of micrococcal nuclease (EC 3.1.4.7.) has been studied. The enzyme recognises features of nucleotide composition, nucleotide sequence and tertiary structure of DNA. Kinetic analysis indicates that the rate of cleavage is 30 times greater at the 5' side of A or T than at G or C. Digestion of end-labelled linear DNA molecules of known sequence revealed that only a limited number of sites are cut, generating a highly specific pattern of fragments. The frequency of cleavage at each site has been determined and it may reflect the poor base overlap in the 5' T-A 3' stack as well as the length of contiguous A and T residues. The same sequence preferences are found when DNA is assembled into nucleosomes. Deoxyribonuclease 1 (EC 3.1.4.5.) recognises many of the same sequence features. Micrococcal nuclease also mimics nuclease S1 selectively cleaving an inverted repeat in supercoiled pBR322. The value of micrococcal nuclease as a "non-specific" enzymatic probe for studying nucleosome phasing is questioned.     

Superhelicity induces hypersensitivity of a human polypyrimidine . polypurine DNA sequence in the human alpha 2-alpha 1 globin intergenic region to S1 nuclease digestion--high resolution mapping of the clustered cleavage sites.

Supercoiled recombinant DNAs containing the human adult alpha-globin gene region have been probed with nuclease S1 in vitro. While agarose gel electrophoresis showed only one predominant, double-stranded cleavage generated by S1 within 6 kb of human DNA and 4 kb of pBR322 sequence, a high resolution gel analysis reveals that the unique S1-hypersensitive locus in the human adult alpha-globin gene region actually contains more than 15 authentic S1 cleavage sites closely spaced together. The mapping approach used here locates the specific S1 cleavage sites on both DNA strands at the nucleotide sequence level. Interestingly, most of these sites are mapped within a 90 bp stretch of GC-rich (66%) polypyrimidine . polypurine DNA that is located 1060 to 1150 bp upstream from alpha 1-globin gene. These results provide the first high resolution map of double-stranded S1-cleavage sites induced within a specific DNA sequence under supercoil strain. The distribution and relative cutting frequencies of these sites mapped are consistent with a slippage mechanism in which the simple repeating sequences are organized into base-mismatched duplex on supercoiled DNA.     

Accessibility of some regions of DNA in chromatin (chicken erythrocytes) to single strand-specific nucleases.

The susceptibility of the DNA in chromatin to single strand-specific nucleases was examined using nuclease P1, mung bean nuclease, and venom phosphodiesterase. A stage in the reaction exists where the size range of the solubilized products is similar for each of the three nucleases and is nearly independent of incubation time. During this stage, the chromatin fragments sediment in the range of 30 to 100 S and contain duplex DNA ranging from 1 to 10 million daltons. Starting with chromatin depleted of histones H1 and H5 similar fragments are generated. In both cases these nucleoprotein fragments are reduced to nucleosomes and their multimers by micrococcal nuclease. Thus, chromatin contains a limited number of DNA sites which are susceptible to single strand-specific nucleases. These sites occur at intervals of 8 to 80 nucleosomes and are distributed throughout the chromatin. Nucleosome monomers, dimers, or trimers were not observed at any stage of single strand-specific nuclease digestion of nuclei, H1- and H5-depleted chromatin, or micrococcal nuclease-generated oligonucleosomes. Each of the three nucleases converted mononucleosomes (approximately 160 base pairs) to nucleosome cores (approximately 140 base pairs) probably by exonucleolytic action that was facilitated by the prior removal of H1 and H5. The minichromosome of SV40 is highly resistant to digestion by nuclease P1.