Identification and purification of a nuclease from Zinnia elegans L.: a potential molecular marker for xylogenesis

A single-strand specific nuclease was identified during a particular stage of a defined cellular differentiation pathway characteristic of xylem development. Using a hormone-inducible system in which cultured mesophyll cells of Zinnia elegans differentiated to xylem cells in synchrony, the enzymatic activity on single-stranded (ss) DNA was highest during the maturation phase of differentiation. Nondifferentiating cells contained little of this activity throughout a similar course of culture. After electrophoresis of extracts from differentiating cells, a 43-kilodalton (kDa) polypeptide was detected by its activity in the gels containing either ssDNA or RNA. Lectins specific for mannose residues on glycoproteins bound to the 43-kDa nuclease and were used to distinguish it from several ribonucleases. The nuclease was purified by a two-step chromatographic procedure: a lectin-affinity column followed by a phosphocellulose column. The purified protein was determined to be a single polypeptide with a relative molecular mass of 43000 by the analysis of its mobility during sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by gel filtration of the native enzyme. A sensitive detection system using biotinylated-concanavalin A and avidin was demonstrated to be specific as a probe for the nuclease protein. An N-terminal amino-acid sequence was derived from 5 pmol of the enzyme. The nuclease was most active on ssDNA at pH 5.5 in the presence of Zn²⁺ and dithiothreitol. The purified preparation hydrolyzed RNA and to a lesser extent, native DNA. It digested closed circular duplex DNA by introducing a single endonucleolytic cleavage followed by random hydrolysis. During the induced pathway of synchronous differentiation in Zinnia the 43-kDa nuclease rapidly increased just prior to the onset of visibly differentiated features, and developed to a maximum level during xylem cell maturation. At this time a similar but slightly smaller nuclease appeared and became dominant as differentiation continued, and subsequently both enzymes decayed. After autolysis, a nuclease of about 37 kDa was found together with the 43-kDa enzyme in the culture medium. Complementing these analyses was the examination of the tissue distribution of the 43-kDa enzyme in Zinnia and other dicotyledonous plants, which also indicated an invivo role of the nuclease in autolysis, the terminal stage of vascular differentiation in plants. The Zinnia nuclease is therefore a potential marker for xylogenesis.Abbreviations Con A Canavalia ensiformis (concanavalin) agglutinin - DNase deoxyribonuclease - DTT dithiothreitol - EDTA ethylenediaminetetraacetic acid - kDa kilodalton - M_r relative molecular mass - RNase ribonuclease - ss single-stranded - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

The use of S1 nuclease treatment of hybrid PCR products for the differentiation between PVY isolates

A new strategy based on treating PCR hybrids with S1 nuclease was used to differentiate between two PVY isolates. Mixed denatured and annealed hybrid PCR products of two PVY isolates including a tested strain and a reference N strain were treated with S1 nuclease. Single-stranded mismatched regions were revealed by the S1 nuclease cleavage, yielding a characteristic pattern of bands in polyacrylamide gel by which virus isolates could be matched. Sequence analysis of the relevant PCR products revealed that only part of the mismatched regions were cleaved by the S1 nuclease. Still, the distinct pattern of degradation products enabled the differentiation between the PVY isolates. The general application of this procedure for strain differentiation is discussed.     

Nuclease-coated bacteriophage: a sensitive tool for studying antigenic reactivity of synthetic sequence fragments

Staphylococcal nuclease was conjugated to bacteriophage T₄ using glutaraldehyde as a cross-linking agent. The conjugated phage is inactivated by antinuclease antibodies and this inactivation is specifically inhibited by nuclease in concentrations as low as 10^?9m. Two fragments of the enzyme, namely P₂ (residues 6–48) and P₃ (residues 49–149) inhibit to a much lower extent the inactivation of the conjugated bacteriophage by the antibodies, than the native enzyme, but when mixed together (forming the noncovalent complex, nuclease-T), the inhibition curve obtained is similar to that obtained by native nuclease. This sensitive system was applied for testing different synthetic sequence fragments and for studying the complementarity of synthetic sequences in the P₂ region with native P₃.     

Subunits of oncornavirus high-molecular-weight RNA. II. Detection of double-stranded-regions in 60S AMV (avian myeloblastosis virus) RNA

Nuclease S₁, specifically splitting only single-stranded polynucleotides has been used to detect the double-stranded regions of high-molecular-weight AMV-RNA. Nuclease S₁-resistant material comprising approx. 8% of 60S AMV-RNA molecule was isolated, purified and found to be completely nuclease S₁-resistant when native and completely nuclease S₁-sensitive upon heat denaturation. The symmetric nucleotide composition with equal G-C and equal A-U contents is also consistent with double-stranded nature of this material. Poly A does not participate significantly, if at all, in nuclease S₁-resistant structures. It is suggested that those base paired regions might participate in linking the RNA subunits together to form an aggregate 60S RNA molecule of oncornaviruses.     

Fractionation of chick oviduct chromatin. Nuclease-resistant deoxyribonucleic acid.

Chromatin isolated from several chick tissues was treated with micrococcal nuclease. A limited degree of tissue specificity of chromatin DNA resistance to nuclease digestion was observed. No difference in the extent of nuclease resistance of chromatin DNA was detected during oestrogen-induced oviduct differentiation. This suggested that the amount of non-histone chromosomal protein does not play an important role in the sensitivity of chromatin DNA to nuclease digestion. Studies of nuclease resistance of chromatin DNA after dissociation and reconstitution of chromatin proteins and ethanol extraction of chromatin indicate that the histones protect the DNA from nuclease attack. Slow thermal denaturation of nuclease-resistant DNA suggests that the protected DNA sequences may be (A+T)-rich, and the (G+C)-rich satellites present in total chick DNA are sensitive to nuclease.     

An immunological approach to the conformational equilibrium of staphylococcal nuclease.

The conformational equilibrium constant, K_conf, of staphylococcal nuclease, describing the equilibrium between the native conformation and non-native or disordered conformations, has been estimated using an immunologic method and an interpretive model. Using goat antisera prepared toward a conformationally disordered nuclease fragment (99–149), antibodies specific for the disordered form of the helix-rich sequence 99 to 126, anti-(99–126)_R, were isolated by sequential immunoabsorption. Anti-(99–126)_R forms soluble 7 S complexes with fragment (99–149), but this interaction may be inhibited by a large excess of nuclease. By using fragment (99–149) preferentially carbamylated at the α-amino terminus with KN¹⁴CO and rabbit anti-goat immunoglobulin to distinguish between antibody-bound and free fragment (99–149), an assay for the quantitation of the degree of inhibition of anti-(99–126)_R. (99–149) complex formation by nuclease was developed.Using a formal analysis based on the hypothesis that nuclease is in a conformational equilibrium between a folded and unfolded form and that anti-(99–126)_R binds effectively only to the unfolded form, the K_conf of nuclease was estimated to be 2900. In the presence of the ligands Ca(II), or Ca(II) and thymidine-3′,5′-diphosphate, K_conf values of 6500 and 30,000 to 50,000 were estimated, respectively. The K_conf of nuclease at 4 °C and 39 °C was 3900 and 400, respectively.     

Occurrence of Nuclease P1-Malonogalactan Complex

Nuclease P₁ from Penicillium citrinum was found to be produced in a form of complex with malonogalactan (a galactan, 1, 5-β-galactofuranoside polymer esterfied with malonic acid at position 3) in the culture on wheat bran. Neither nuclease P₁-malonogalactan complex nor malonogalactan was produced in a liquid medium. Nuclease P₁-malonogalactan complexes, P₁-MG I, II, and III were purified from an aqueous extract of the culture on wheat bran. The most anionic complex, P₁-MG III, was composed of the protein, carbohydrate and malonic acid in the ratio of 1: 2.6: 0.5 (w/w). The complex was not dissociated by purification procedures including fractionations with acetone and ammonium sulfate, gel filtration and DEAE-cellulose chromatography. A malonogalactan-specific carboxylesterase was found in culture of the same mold on wheat bran. Nuclease P₁-malonogalactan was demalonylated by the esterase to yield nuclease P₁-galactan. The binding of nuclease P₁ to galactan was rather loose so that nuclease P₁-galactan complex was partially dissociated by DEAE-cellulose chromatography. Attempt to reconstitute the complex from nuclease P₁ and malonogalactan upon mixing was unsuccessful. Exogenously supplemented nuclease P₁ did not associate with malonogalactan in the growing culture on wheat bran, either.

Several extracellular enzymes such as RNase, β-galactosidase and protease were also found in a form of complex with malonogalactan in the culture on wheat bran.     

Comparison of Nuclease P1-Malonogalactan Complex with Nuclease P1

Properties of nuclease P₁-malonogalactan complex (P₁-MG) were compared with those of the polysaccharide-free nuclease P₁. Significant difference was not observed between them in phosphomonoester splitting activity, but marked differences were observed in nucleolytic activity as follows: (1) The pH optima of P₁-MG for RNA and heat-denatured DNA were lower than those of nuclease P₁. (2) At lower than 0.001 of ionic strength, RNA and heat- denatured DNA were attacked hardly by P₁-MG, but attacked well by nuclease P₁. (3) The increase in hydrolysis rate of RNA or heat-denatured DNA with an elevation of temperature from 37°C to 70°C was not so marked in P₁-MG as compared with nuclease P₁. (4) P₁-MG hydrolyzed polynucleotides, especially native DNA, much slower than nuclease P₁.

Influence of ionic strength, pH and temperature on the nucleolytic activity of nuclease P₁-galactan (P₁-G), which was prepared by demalonylating P₁-MG enzymatically, was similar to that of nuclease P₁, except that the activity of P₁-G for native DNA was much lower than nuclease P₁.     

Structural organization of ribonucleoproteins containing small nuclear RNAs from HeLa cells. Proteins interact closely with a similar structural domain of U1, U2, U4 and U5 small nuclear RNAs

U₁ snRNP² isolated from HeLa cells and purified by centrifugation in cesium chloride contains a set of proteins that may be resolved into four/five polypeptides by gel electrophoresis. When this particle was submitted to extensive digestion with micrococcal nuclease, RNA fragments of about 25 nucleotides in length were obtained. Sequence analyses showed that these highly protected fragments were derived from the same region of the U₁ molecule, spanning positions 119 to 143. At low concentrations of nuclease, a longer fragment, from nucleotide 119 to the 3′ OH end, was also detected. U₁ core-resistant snRNP, isolated by high performance liquid chromatography, still contains all the protein components of the intact particle.When a less drastically purified U₁ snRNP containing, beside the four/five polypeptides remaining after centrifugation in cesium chloride, a set of at least three polypeptides of larger size, was digested with the nuclease, no other protected RNA fragment was detected.When a mixture of U₁, U₂, U₄, U₅ and U₆ snRNPs, which contains the same four/five polypeptides as U₁ snRNP, was treated with micrococcal nuclease, protected fragments of snRNAs U₂, U₄ and U₅ were found in addition to those derived from U₁. No fragment derived from U₆ was found.In all cases, the region of snRNA shielded from nuclease attack corresponds to a distinctive feature of the molecule. It is a single-stranded region, comprising the sequence A(U)_nG with n ≥ 3, bordered by two double-stranded stems. One of these stems includes the 3′ terminus of the RNA, except in the case of U₂, where there are two stems instead of one on the 3′ side of the single-stranded stretch. Although a comparable structural domain exists also in U₆ snRNA, it does not contain the sequence A(U)_nG which correlates well with the fact that no U₆ snRNA fragment seems to resist micrococcal nuclease digestion.     

Production of 5′ Nucleotide by Using Halophilic Nuclease H Preferentially Adsorbed on Flocculated Cells of the Halophile Micrococcus varians subsp. halophilus

A bioreactor with a column of flocculated cells of the moderate halophile Micrococcus varians subsp. halophilus which adsorbed the halophilic nuclease H was designed to be used in the production of 5′ nucleotides from RNA. A remarkable characteristic of the flocculated cells was that they preferentially adsorbed much exogenous nuclease, excluding adsorbed 5′ nucleotidase. Furthermore, desalting treatment of the flocculated cells in the presence of 2% MgSO₄ · 7H₂O gave rise to selective inactivation of 5′ nucleotidase without the loss of nuclease H activity, and 5′-guanylic acid was produced with the bioreactor.     

Action of hexaamminecobalt on the activity of Serratia marcescens nuclease

Using CD spectroscopic and kinetic analysis, a refined mechanism of Co(NH₃) ₆ ³⁺ action on activity of Serratia marcescens nuclease was elucidated. The mechanism was identical with previously found mechanisms of Mg²⁺ and C₇H₅O₂Hg⁺. Similarly to Mg²⁺ and C₇H₅O₂Hg⁺, Co(NH₃) ₆ ³⁺ binding to the DNA substrate induced changes in the secondary structure which resulted in changes of the enzymatic activity of the S. marcescens nuclease. Upon binding of 0.03 Co(NH₃) ₆ ³⁺ per DNA phosphate, highly polymerized DNA displayed A-form characteristics. The DNA transition from B-form to A-form intermediate was followed by a decrease of the nuclease activity. The diminishing nuclease activity was consistent with diminishing values of Km and Kcat. Co(NH₃)₆ ³⁺ binding to the highly polymerized DNA caused a 1.7–2.8-fold decrease in Km, and 13.3–19.9 decrease in Vmax compared with Mg-DNA complex. A vast excess of Co(NH₃)₆ ³⁺ did not affect the activity of S. marcescens nuclease if the DNA in the assay mixture remained in its B-form conformation. Preincubation of S. marcescens nuclease with Co(NH₃)₆ ³⁺ did not influence the tertiary structure of the enzyme.     

Structure of p22 headful packaging nuclease

Packaging of viral genomes into preformed procapsids requires the controlled and synchronized activity of an ATPase and a genome-processing nuclease, both located in the large terminase (L-terminase) subunit. In this paper, we have characterized the structure and regulation of bacteriophage P22 L-terminase (gp2). Limited proteolysis reveals a bipartite organization consisting of an N-terminal ATPase core flexibly connected to a C-terminal nuclease domain. The 2.02 Å crystal structure of P22 headful nuclease obtained by in-drop proteolysis of full-length L-terminase (FL-L-terminase) reveals a central seven-stranded β-sheet core that harbors two magnesium ions. Modeling studies with DNA suggest that the two ions are poised for two-metal ion-dependent catalysis, but the nuclease DNA binding surface is sterically hindered by a loop-helix (L₁-α₂) motif, which is incompatible with catalysis. Accordingly, the isolated nuclease is completely inactive in vitro, whereas it exhibits endonucleolytic activity in the context of FL-L-terminase. Deleting the autoinhibitory L₁-α₂ motif (or just the loop L₁) restores nuclease activity to a level comparable with FL-L-terminase. Together, these results suggest that the activity of P22 headful nuclease is regulated by intramolecular cross-talk with the N-terminal ATPase domain. This cross-talk allows for precise and controlled cleavage of DNA that is essential for genome packaging.     

A rapid method for the screening of plasmids from Clostridium acetobutylicum and other Clostridium sp.

Summary A rapid method was developed for plasmid DNA screening from micro volume cultures of Clostridium acetobutylicum. It involves protoplastization by lysozyme, nuclease inhibition by incorporating EDTA or DEP, followed by lysis with high concentration of SDS. The whole lysate is applied directly to electrophoretic analysis.     

Organization of the BcgI restriction-modification protein for the cleavage of eight phosphodiester bonds in DNA

Type IIB restriction-modification systems, such as BcgI, feature a single protein with both endonuclease and methyltransferase activities. Type IIB nucleases require two recognition sites and cut both strands on both sides of their unmodified sites. BcgI cuts all eight target phosphodiester bonds before dissociation. The BcgI protein contains A and B polypeptides in a 2:1 ratio: A has one catalytic centre for each activity; B recognizes the DNA. We show here that BcgI is organized as A₂B protomers, with B at its centre, but that these protomers self-associate to assemblies containing several A₂B units. Moreover, like the well known FokI nuclease, BcgI bound to its site has to recruit additional protomers before it can cut DNA. DNA-bound BcgI can alternatively be activated by excess A subunits, much like the activation of FokI by its catalytic domain. Eight A subunits, each with one centre for nuclease activity, are presumably needed to cut the eight bonds cleaved by BcgI. Its nuclease reaction may thus involve two A₂B units, each bound to a recognition site, with two more A₂B units bridging the complexes by protein–protein interactions between the nuclease domains.     

An alkaline phosphatase-linked assay for ribonucleases

A convenient and rapid assay for ribonucleases has been developed using commerical unlabeled materials. This assay detected less than 1 ng of RNase A. The assay was also applied to RNase T₁ and micrococcal nuclease. The phosphate end groups generated at the cleavage sites of the RNA substrate were measured by incubating with excess alkaline phosphatase and determining the phosphate released. Initial reaction rates were measured and accurate units of activity established, which is not possible with most RNase assays. Commercial preparations of alkaline phosphatase from E. coli are contaminated with RNase. A procedure was described for removal of RNase from the alkaline phosphatase preparations.     

Effect of alkylation with streptozotocin on the secondary structure of DNA

S₁ nuclease hydrolysis and hydroxyapatite chromatography were used to study the effect of the alkylating antibiotic, streptozotocin, on the secondary structure of DNA. Native calf thymus DNA was alkylatedin vitro with increasing concentrations of streptozotocin and subjected to S 1 nuclease hydrolysis. An increasing degree of DNA degradation was seen, suggesting a destabilization of the secondary structure. Indirect evidence, deduced from alkaline hydrolysis, effect of NaCl on S₁ nuclease hydrolysis, and hydroxyapatite chromatographic analysis of alkylated DNA, suggested a significant alkylation of DNA phosphates in addition to DNA bases. Nictotinamide has been reported to alter the cytotoxic and carcinogenic effects of streptozotocin. Our experiments indicate that in the presence of nicotinamide, streptozotocin causes the formation of a greater proportion of alkylated bases in relation to alkyl phosphotriesters. This may have significance in relation to the differential cytotoxicity of streptozotocin in the absence and presence of nicotinamide.