Nuclease from Aspergillus oryzae, specific for single-stranded regions of nucleic acids]

A single-stranded specific nuclease has been purified from amyloryzine obtained from the mould fungi Aspergillus cryzae. The nuclease under study resembles the enzymes described in the literature in its ability to hydrolyze single-stranded nucleic acids. However, the enzyme essentially differs from previously known nucleases in some catalytic properties, particularly in its ability for degradation of poly A. It has been shown that the enzyme also hydrolyzes the synthetic dinucleotide pTpT to mononucleoside phosphates.     

Substrate specificity and mode of action of the zinc-metallo nuclease from Physarum polycephalum

The alkaline zinc-metallo nuclease of Physarum polycephalum is an endonuclease with a high specificity for single-stranded nucleic acids. Single-stranded DNA was cleaved at least 6,000 times faster than double-stranded DNA under identical conditions. In the supercoil-induced single-stranded region of Form I PM2 DNA only a single nick was made. The nuclease showed nucleotide specificity. Poly(A), poly(I), and poly(dT) were preferentially hydrolyzed. Product analysis showed that it acted by an endonucleolytic mechanism: long polynucleotides were fragmented via intermediate length products to oligo- and mono-nucleotides with the phosphate group at the 5'-terminal position. Extensive similarities exist with the single-strand-specific nuclease S1 from Aspergillus. The zinc-metallo endonuclease from Physarum could be used as a similar probe for single-stranded nucleic acids at neutral or alkaline pH conditions.     

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.     

Single-strand-specific degradation of DNA during isolation of rat liver nuclei

We have investigated structural change in rat liver DNA produced by different isolation procedures and specifically compared the integrity of DNA derived by phenol extraction from isolated and purified nuclei with preparations extracted immediately from a crude liver homogenate containing intact nuclei. As indicated by stepwise elution from benzoylated DEAE-cellulose, most structural change in DNA was evident following nuclei isolation. Damage principally involved generation of single-stranded regions in otherwise double-stranded DNA fragments; totally single-stranded DNA was not detected by hydroxylapatite chromatography. Caffeine gradient elution suggested formation of single-stranded regions extending for up to several kilobases. In neutral sucrose gradients, differences in sedimentation rates of respective DNA samples consequent upon S1 nuclease digestion could be detected after isolation of nuclei, though not in other circumstances. The observed single-strand-specific nuclease digestion of DNA could apparently be reduced if steps were taken to reduce autodigestion during nuclei isolation by reduction of temperature and covalent cation concentration. The results are discussed in terms of the use of exogenous and endogenous nucleases in chromatin fractionation studies involving isolated nuclei and possible artifactual findings that may be generated by single-strand-specific autodigestion.     

Paraquat and roundup effects on nucleases activities of alfalfa seedlings and alfalfa nucleases activities on paraquat-treated and roundup-treated nucleic acids

The specific activities of acid (pH 5.5) and neutral (pH 7) DNases and RNases were determined in alfalfa (Medicago sativa L.) seedlings grown in the dark in the presence of 3.7 mM paraquat (PQ) or 1 mM roundup (RD). Seedlings were taken at 0, 1, 3, and 5 days. Plant growth parameters (plant height and fresh weight) were dramatically reduced under these conditions of growth comparing to the control (grown in water). The DNase and RNase specific activities of herbicide-treated seedlings were reduced. The reduction of activities ranged by about 50–90 and 15–70% in PQ- and RD-treated seedlings, respectively. In vitro, PQ- and RD-treated nucleic acids [single-stranded DNA (ssDNA), RNA, and plasmid DNA (pl-DNA)] were incubated with acid and neutral nucleases. Both enzymes were isolated and purified from alfalfa seedlings. Electrophoretic analysis on agarose gel of the above incubated mixtures revealed the following: (a) neutral nuclease (pH 7) was capable of hydrolyzing PQ-treated ssDNA while acid nuclease (pH 5.5) was incapable. This could be due to the fact that acid and neutral nucleases displayed different base linkage specificity toward ssDNA; (b) RD formed strong complexes with ssDNA that were unable to be hydrolyzed by both nucleases; (c) in contrast, both enzymes were capable of hydrolyzing PQ- or RD-treated RNA; (d) neutral nuclease was capable of nicking and linearizing both PQ- and RD-treated pl-DNA while acid nuclease had the same activity only toward the PQ-treated pl-DNA; (e) the enzyme activities were not inhibited in the presence of both herbicides. The data suggest that the complexes of PQ or RD with DNA should not be functional substrates of nucleases, and consequently cell processes (e.g., metabolism of nucleic acids, gene expression, replication), in which DNA and nucleases are involved, could be disturbed.     

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.     

Use of aurintricarboxylic acid as an inhibitor of nucleases during nucleic acid isolation.

Aurintricarboxylic acid (ATA) is a general inhibitor of nucleases. ATA has been shown to inhibit the following enzymes in vitro: DNAse I, RNAse A, S1 nuclease, exonuclease III, and restriction endonucleases Sal I, Bam HI, Pst I and Sma I. The observed inhibition is consistent with the proposal by Blumenthal and Landers (BBRC 55, 680, 1973) that most nucleic acid binding proteins will be sensitive to ATA. The action of ATA as a nuclease inhibitor can be used to advantage in the isolation of cellular nucleic acids.     

Influence of nucleic acid base aromaticity on substrate reactivity with enzymes acting on single-stranded DNA.

Stacking between aromatic amino acids and nucleic acid bases may play an important role in the interaction of enzymes with nucleic acid substrates. In such circumstances, disruption of base aromaticity would be expected to decrease enzyme activity on the modified substrates. We have examined the requirement for DNA base aromaticity of five enzymes that act on single-stranded DNA, T4 polynucleotide kinase, nucleases P1 and S1, and snake venom and calf spleen phosphodiesterases, by comparing their kinetics of reaction with a series of dinucleoside monophosphates containing thymidine or a ring-saturated derivative. The modified substrates contained either cis-5R,6S-di-hydro-5,6-dihydroxythymidine (thymidine glycol) or a mixture of the 5R and 5S isomers of 5,6-dihydrothymidine. It was observed that for all the enzymes, except snake venom phosphodiesterase, the parent molecules were better substrates than the dihydrothymidine derivatives, while the thymidine glycol compounds were significantly poorer substrates. Snake venom phosphodiesterase acted on the unmodified and dihydrothymidine molecules at almost the same rate. These results imply that for all the remaining enzymes base aromaticity is a factor in enzyme-substrate interaction, but that additional factors must contribute to the poorer substrate capacity of the thymidine glycol compounds. The influence of the stereochemistry of the dihydrothymidine derivatives was also investigated. We observed that nuclease P1 and S1 hydrolysed the molecules containing 5R-dihydrothymidine approximately 50-times faster than those containing the S-isomer. The other enzymes displayed no measurable stereospecificity.     

Isolation and characterization of naturally occurring hairpin structures in single-stranded DNA of coliphage M13

With precise conditions of digestion with single-strand-specific nucleases, namely, endonuclease S1 of $\text{Aspergillus oryzae}$ and exonuclease I of $\text{Escherichia coli}$, nuclease-resistant DNA cores can be obtained reproducibly from single-stranded M13 DNA. The DNA cores are composed almost exclusively of two sizes (60 and 44 nucleotides long). These have high (G + C)-contents relative to that of intact M13 DNA, and arise from restricted regions of the M13 genome. The resistance of these fragments to single-strand-specific nucleases and their nondenaturability strongly suggest the presence of double-stranded segments in these core pieces. That the core pieces are only partially double-stranded is shown by their lack of complete base complementarity and their pattern of elution from hydroxyapatite.     

P1 nuclease cleavage is dependent on length of the mismatches in DNA

P1 nuclease is one of the most extensively used single-strand DNA specific nucleases in molecular biology. In modern biology, it is used as an enzymatic probe to detect altered DNA conformations. It is well documented that P1 cleaves single-stranded nucleic acids and single-stranded DNA regions. The fact that P1 can act under a wide range of conditions, including physiological pH and temperature make it the most commonly used enzymatic probe in DNA structural studies. Surprisingly, to this date, there is no study to characterize the influence of length of mismatches on P1 sensitivity. Using a series of radioactively labeled oligomeric DNA substrates-containing mismatches, we find that P1 nuclease cleavage is dependent on the length of mismatches. P1 does not cleave DNA when there is a single-base mismatch. P1 cleavage efficiency is optimum when mismatch length is 3 nt or more. Changing the position of the mismatches also does not make any difference in cleavage efficacy. These novel findings on P1 properties have implications for its use in DNA structure and DNA repair studies.     

The interactions of enzyme and chemical probes with inverted repeats in supercoiled DNA

In negatively supercoiled DNA molecules some inverted repeat sequences adopt a perturbed conformation which is characterised by the following properties. They are centrally hypersensitive to single-strand-specific nucleases such as S1, and to a much lower extent the flanking regions may also be sensitive. They are also hypersensitive to modification by bromoacetaldehyde, particularly in their flanking region. They may be resistant to endonucleolysis by restriction enzymes and are cleaved (resolved) by a T4 resolving enzyme. All these properties can only be consistently explained by a model in which the inverted repeat adopts a cruciform structure. This property has been shown to depend sharply on a superhelix density, and the transition to nuclease sensitivity is accompanied by a marked alteration in the overall molecular geometry as judged by frictional properties. The probable dynamics of these structures are discussed.     

Dissection of the functional domains of the Leishmania surface membrane 3'-nucleotidase/nuclease, a unique member of the class I nuclease family

Class I nucleases are a family of enzymes that specifically hydrolyze single-stranded nucleic acids. Recently, we characterized the gene encoding a new member of this family, the 3'-nucleotidase/nuclease (Ld3'NT/NU) of the parasitic protozoan Leishmania donovani. The Ld3'NT/NU is unique as it is the only class I nuclease that is a cell surface membrane-anchored protein. Currently, we used a homologous episomal expression system to dissect the functional domains of the Ld3'NT/NU. Our results showed that its N-terminal signal peptide targeted this protein into the endoplasmic reticulum. Using Ld3'NT/NU-green fluorescent protein chimeras, we showed that the C-terminal domain of the Ld3'NT/NU functioned to anchor this protein into the parasite cell surface membrane. Further, removal of the Ld3'NT/NU C-terminal domain resulted in its release/secretion as a fully active enzyme. Moreover, deletion of its single N-linked glycosylation site showed that such glycosylation was not required for the enzymatic functions of the Ld3'NT/NU. Thus, using the fidelity of a homologous expression system, we have defined some of the functional domains of this unique member of the class I nuclease family.     

Isolation and characterization of nucleases from a clinical isolate of Serratia marcescens kums 3958

Two new extracellular nucleases, nucleases SM1 and SM2, were purified from the culture fluid of S. marcescens kums 3958, a fresh clinical isolate. The purification was carried out by the following steps; ammonium sulfate precipitation, and DEAE-cellulose and Sephadex G-100 column chromatography. At the final step, nucleases SM1 and SM2 were purified about 3,700- and 1,000-fold, respectively. They were free from phosphomonoesterase and phosphodiesterase activities. The pIs were 8.1 and 7.5 for nucleases SM1 and SM2, respectively. The molecular weight was estimated to be 35,000 for both enzymes by SDS-polyacrylamide disc gel electrophoresis. The results of amino acid analyses showed that both the threonine and serine contents were higher in nuclease SM2 than in SM1. Furthermore, nuclease SM1 was more stable than nuclease SM2 at 4 degrees C. The other properties of the two enzymes were similar; pH optimum (8.0), Mg2+ or Mn2+ for activation, and inhibition by chemical reagents such as EDTA and pyrophosphate. No significant difference was found in base specificity between nucleases SM1 and SM2. Both enzymes specifically degraded double-stranded homopolymers, especially poly(I). poly(C), as well as yeast RNA and calf thymus DNA. They hardly degraded, however, single-stranded homopolymers such as poly(dA), poly(G), and poly(U).     

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.     

The removal of nucleic acids from microbial extracts by precipitation with lysozyme

It is usually necessary to remove nucleic acids from microbial extracts in order to avoid their interference with the isolation of enzymes from the extract. This may be particularly important where the purification procedure includes chromatography on an anion-exchange column such as DEAE-Sephadex (1). Methods that have been used have included precipitation with Mn, destruction of the nucleic acids with nucleases, and precipitation with basic substances, usually protamine sulfate or streptomycin sulfate. It is likely that there may be advantages, in some cases at least, in using other basic proteins for this purpose, since the results obtained with the previous methods have not always been satisfactory. The procedure described in this paper utilizes high concentrations of lysozyme to precipitate nucleic acids from a bacterial extract. The separation obtained with lysozyme was efficient, reproducible, and superior to the separation obtained with protamine sulfate.     

Cellular site in Bacillus subtilis of a nuclease which preferentially degrades single-stranded nucleic acids

Birnboim, H. C. (Albert Einstein College of Medicine, New York, N.Y.). Cellular site in Bacillus subtilis of a nuclease which preferentially degrades single-stranded nucleic acids. J. Bacteriol. 91:1004-1011. 1966.-A nuclease, identified by a marked preference for single-stranded nucleic acids, has been demonstrated in extracts of Bacillus subtilis. The enzyme was associated with the cell wall-membrane fraction of mechanically disrupted cells and was released from cells which had been converted to protoplasts by lysozyme. The nuclease activity prepared by the latter procedure was found to be activated and solubilized by treatment with trypsin. The enzyme had about 2% activity on native deoxyribonucleic acid (DNA) as compared with denatured DNA. By use of CsCl analytical density gradient ultracentrifugation, this preparation was shown to degrade denatured DNA selectively in mixtures of native and denatured DNA.     

衣壳蛋白靶向灭活 一种新型抗病毒策略

衣壳蛋白靶向灭活（CTVI）是一种新型抗病毒策略,它是通过将病毒衣壳蛋白与核酸酶（金黄色葡萄球菌和酸梅、核糖核酸酶Barnase、大肠杆菌RNase HI等）的融合蛋白装配到病毒粒子中,使核酸酶接触并降解病毒核酸,从而达到抑制病毒复制的目的。该策略已经在人免疫缺陷病毒、鼠白血病病毒、乙肝病毒、登革病毒等病毒的抗病毒研究中取得良好效果,展示了广阔的应用前景。     

The Interactions of Enzyme and Chemical Probes with Inverted Repeats in Supercoiled DNA

Abstract

In negatively supercoiled DNA molecules some inverted repeat sequences adopt a perturbed conformation which is characterised by the following properties. They are centrally hypersensitive to single-strand-specific nucleases such as SI, and to a much lower extent the flanking regions may also be sensitive. They are also hypersensitive to modification by bromoacetaldehyde, particularly in their flanking region. They may be resistant to endo- nucleolysis by restriction enzymes and are cleaved (resolved) by a T4 resolving enzyme. All these properties can only be consistently explained by a model in which the inverted repeat adopts a cruciform structure. This property has been shown to depend sharply on a superhelix density, and the transition to nuclease sensitivity is accompanied by a marked alteration in the overall molecular geometry as judged by frictional properties. The probable dynamics of these structures are discussed.     

137 DNA nanostructure serum stability: greater than the sum of their parts

DNA cages hold tremendous potential to encapsulate and selectively release therapeutic drugs, and can provide useful tools to probe the size and shape dependence of nucleic acid delivery (McLaughlin & Sleiman, H. F., 2011). These structures have been shown to site-specifically present ligands, small molecule drugs, or antisense/siRNA motifs, in order to increase their therapeutic efficiency (Li & Fan, C. 2012). One of the major barriers towards their in vivo applications is the susceptibility of their strands towards nuclease degradation. A number of chemical strategies have been used to block nuclease digestion of oligonucleotides and improve potency, such as the use of a phosphorothioate backbone, 2´-O-methyl, locked nucleic acids, and short hybrid gapmers. However, the synthesis of these oligonucleotides is often complicated and expensive, driving the need for simple modifications to enhance serum stability and address in vivo biodistribution. We show here a simple method to significantly enhance the nuclease stability of DNA strands, through introduction of commercially available, single-endmodifications (Conway & Sleiman 2013). We use these oligonucleotides to construct DNA cages in a single step and in quantitative yields. Even in single-stranded form, these cages stabilize their component strands towards nucleases, with mean lifetimes as long as 62?h in 10 % (v/v) fetal bovine serum (FBS). We examine the effect of other DNA-end modifications on nuclease susceptibility. Finally, we show the ligation of these single-stranded cages into topologically interesting catenane ‘necklaces,’ with mean lifetimes in serum of ～200?h.     

Cloning and Characterization of a Novel Drosophila Stress Induced DNase

Drosophila melanogaster flies mount an impressive immune response to a variety of pathogens with an efficient system comprised of both humoral and cellular responses. The fat body is the main producer of the anti-microbial peptides (AMPs) with anti-pathogen activity. During bacterial infection, an array of secreted peptidases, proteases and other enzymes are involved in the dissolution of debris generated by pathogen clearance. Although pathogen destruction should result in the release a large amount of nucleic acids, the mechanisms for its removal are still not known. In this report, we present the characterization of a nuclease gene that is induced not only by bacterial infection but also by oxidative stress. Expression of the identified protein has revealed that it encodes a potent nuclease that has been named Stress Induced DNase (SID). SID belongs to a family of evolutionarily conserved cation-dependent nucleases that degrade both single and double-stranded nucleic acids. Down-regulation of sid expression via RNA interference leads to significant reduction of fly viability after bacterial infection and oxidative stress. Our results indicate that SID protects flies from the toxic effects of excess DNA/RNA released by pathogen destruction and from oxidative damage.