A Streptomyces glaucescens endodeoxyribonuclease which shows a strong preference for CC dinucleotide.

We have characterized a deoxyribonuclease from Streptomyces glaucescens that cleaves double-stranded DNA preferably between the dinucleotide 5'-CC-3'. The cleavage specificity was demonstrated by both analysis of the terminal nucleotides of the generated fragments and DNA sequencing of partially digested DNA. Digestion of lambda DNA with this enzyme resulted in the production of double-stranded fragments with 5' and/or 3'-protruding single-stranded tails. DNase I footprinting experiments indicated that the nuclease specifically binds to its cleavage sites on the DNA under non-catalytic conditions. The enzyme is not affected by cytosine methylation in hemimethylated DNA.     

Mutational analysis of primosome assembly sites. Evidence for alternative DNA structures

Primosome assembly sites are complex DNA structures that share common functions (they elicit the DNA-dependent ATPase of replication factor Y from Escherichia coli and serve as origins of complementary strand DNA synthesis), but display little sequence homology. In order to ascertain a common basis for factor Y-DNA recognition, a primosome assembly site and its mutated derivatives have been functionally and structurally analyzed. Under conditions in which they lose the capacity to function as ATPase effectors these DNA templates have been (i) assayed for their ability to bind factor Y, and (ii) probed, with pancreatic DNase, for structural alterations. In this ATPase-inactivating environment (suboptimal concentrations of MgCl2 and NaCl, and high levels of the E. coli single-stranded DNA binding protein), factor Y does not bind to its cognate DNA and the DNase cleavage pattern characteristic of this site is perceptibly changed: compared to the DNase digest obtained under activating conditions, cleavage is notably decreased in the 5' half of the site and enhanced at the 3' end. The results of this study strongly indicate that the structure of the primosome assembly site under analysis consists of two hairpins which interact with each other. When the sites of pancreatic DNase attack are plotted on the proposed double hairpin structure, the 5' cleavage sites all map to one duplex while the 3' sites map to the other. The observation that, under factor Y ATPase-activating conditions, the 3' hairpin is largely refractory to the action of pancreatic DNase indicates that tertiary interactions between the two duplexes render a portion of the DNA structure inaccessible to the nuclease.     

Development of nonradioactive microtiter plate assays for nuclease activity

We have developed two microtiter plate assays for the detection of DNA cleavage by nucleases, using 3'-biotinylated oligonucleotide substrates. In the covalently linked oligonucleotide nuclease assay (CLONA), the biotinylated substrates are phosphorylated at the 5' end to facilitate their covalent immobilization on CovaLink NH plates. The cleavage of the covalently immobilized substrate by nucleases results in biotin release. The uncleaved substrate molecules are detected with an enzyme-avidin conjugate. The affinity-linked oligonucleotide nuclease assay (ALONA) makes use of substrates with a digoxigenin on the 5' end of the 3'-biotinylated DNA strand. The substrate binds specifically to the wells of streptavidin-coated microtiter plates, in which the nuclease reaction takes place. Uncleaved substrate retains the digoxigenin label, which is detected with an enzyme-labeled anti-digoxigenin antibody. We assessed the efficiency of these two assays by measuring S1 nuclease and DNase I activities, and the inhibitory effect of EDTA and aurintricarboxylic acid on the reaction. Both methods are more convenient than the standard radioactive nuclease assay and are suitable for high-throughput screening of potential nuclease inhibitors, nucleases, and catalytic antibodies. The ALONA assay was found to be more sensitive than the CLONA assay, with a performance similar to that of the standard nuclease assay.     

Cleavage of phi X174 single-stranded DNA by gene A protein and formation of a tight protein-DNA complex.

The gene A protein cleaves phi X174 single-stranded DNA (ssDNA). The cleavage appears to be stoichiometric, whereby a gene A protein molecule breaks a phosphodiester bond and binds to the 5' end. The enzyme introduces mostly a single break in a circular ssDNA molecule. However, at high enzyme-to-DNA ratios, more than one break in the DNA could be observed. The cleavage of the ssDNA by gene A protein renders the DNA sensitive to the action of terminal transferase to incorporate [alpha -32P]ATP. Thus, the 3'OH end is free. All attempts to label the 5' end by T4-induced polynucleotide kinase and [gamma-32P]ATP failed. The formation of a gene A-ssDNA complex was demonstrated directly by using 3H-labeled gene A protein and 32P-labeled ssDNA in the reaction. Such a complex is resistant to treatments with 0.2 M NaOH, banding in CsCl, and boiling in 2.5% sodium dodecyl sulfate. Only treatment with a nuclease released the bound protein. Also, after cleaving [32P]ssDNA by gene A protein, followed by either DNase I or micrococcal nuclease digestion, a fraction of the 32P label remained resistant to nuclease treatment and comigrated with gene A protein on polyacrylamide gels.     

Location of the primary sites of micrococcal nuclease cleavage on the nucleosome core

The positions and relative frequencies of the primary cleavages made by micrococcal nuclease on the DNA of nucleosome core particles have been found by fractionating the double-stranded products of digestion and examining their single-stranded compositions. This approach overcomes the problems caused by secondary events such as the exonucleolytic and pseudo-double-stranded actions of the nuclease and, combined with the use of high resolution gel electrophoresis, enables the cutting site positions to be determined with a higher precision than has been achieved hitherto. The micrococcal nuclease primary cleavage sites lie close (on average, within 0.5 nucleotide) to those previously determined by Lutter (1981) for the nucleases DNase I and DNase II. These similarities show that the accessible regions are the same for all three nucleases, the cleavage sites being dictated by the structure of the nucleosome core. The differences in the final products of the digestion are explained in terms of secondary cleavage events of micrococcal nuclease. While the strongly protected regions of the nucleosome core DNA are common to all three nucleases, there are differences in the relative degrees of cutting at the more exposed sites characteristic of the particular enzyme. In particular, micrococcal nuclease shows a marked polarity in the 3'-5' direction in the cutting rates as plotted along a single strand of the nucleosomal DNA. This is explained in terms of the three-dimensional structure of the nucleosome where, in any accessible region of the double helix, the innermost strand is shielded by the outermost strand on the one side and the histone core on the other. The final part of the paper is concerned with the preference of micrococcal nuclease to cleave at (A,T) sequences in chromatin.     

Contacts between the 5' nuclease of DNA polymerase I and its DNA substrate

The 5' nuclease of DNA polymerase I (Pol I) of Escherichia coli is a member of an important class of prokaryotic and eukaryotic nucleases, involved in DNA replication and repair, with specificity for the junction between single-stranded and duplex DNA. We have investigated the interaction of the 5' nuclease domain with DNA substrates from the standpoint of both the protein and the DNA. Phosphate ethylation interference showed that the nuclease binds to the nucleotides immediately surrounding the cleavage site and also contacts the complementary strand one-half turn away, indicating that contacts are made to one face only of the duplex portion of the DNA substrate. Phosphodiester contacts were investigated further using DNA substrates carrying unique methylphosphonate substitutions, together with mutations in the 5' nuclease. These experiments suggested that two highly conserved basic residues, Lys(78) and Arg(81), are close to the phosphodiester immediately 5' to the cleavage site, while a third highly conserved residue, Arg(20), may interact with the phosphodiester 3' to the cleavage site. Our results provide strong support for a DNA binding model proposed for the related exonuclease from bacteriophage T5, in which the conserved basic residues mentioned above define the two ends of a helical arch that forms part of the single-stranded DNA-binding region. The nine highly conserved carboxylates in the active site region appear to play a relatively minor role in substrate binding, although they are crucial for catalysis. In addition to binding the DNA backbone around the cleavage point, the 5' nuclease also has a binding site for one or two frayed bases at the 3' end of an upstream primer strand. In agreement with work in related systems, 5' nuclease cleavage is blocked by duplex DNA in the 5' tail, but the enzyme is quite tolerant of abasic DNA or polarity reversal within the 5' tail.     

Recognition of the DNA helix stabilizing anthramycin-N2 guanine adduct by UVRABC nuclease

The binding of the anti-tumor antibiotic anthramycin to a defined linear DNA fragment was investigated using both exonuclease III and lambda exonuclease. We show that most of the guanine residues are reactive toward anthramycin; however, several guanine residues showed preferential reactivity for the drug. Using purified UVRA, UVRB and UVRC proteins we present evidence that these three proteins in concert are able to recognize and produce specific strand cleavage flanking anthramycin-DNA adducts. The cleavage of anthramycin adducts by UVRABC nuclease is specific and results in strand breaks at five or six bases 5' and three or four bases 3'-flanking an adduct. At some guanine residues single incisions were observed only on one side of the adduct. The 5' strand breaks observed often occurred as doublet bands on sequencing gels, indicating plasticity in the site of 5' cleavage whereas the 3' cleavage did not show this effect. When DNA fragments modified with elevated levels of anthramycin were used as substrates the activity of the UVRABC nuclease toward the anthramycin adducts decreased. Possible mechanisms for the recognition and specific cleavage of the helix-stabilizing anthramycin DNA adduct and other helix destabilizing lesions by the UVRABC nuclease are discussed.     

Probing the structure of multi-stranded guanine-rich DNA complexes by Raman spectroscopy and enzymatic degradation.

The multi-stranded DNA complexes formed by the oligonucleotides d(T15G4T2G4), Tel, and d(T15G15), TG, were examined by nuclease digestion and Raman spectroscopy. Both Tel and TG can aggregate to form structures consisting of multiple, parallel-oriented DNA strands with two independent structural domains. Overall, the structures of the TG and Tel aggregates appear similar. According to the Raman data, the majority of bases are in C2'-endo/anti conformation. The interaction of guanines at the 3'-ends in both complexes stabilizes the complexes and protects them from degradation by exonuclease III. The 5'-extensions remain single-stranded and the thymines are accessible to single-strand-specific nuclease digestion. The extent of enzymatic cleavage at the junction at the 5' end of the 15 thymines implies a conformational change between this part of the molecule and the guanine-rich region. The differential enzymatic sensitivity of the complexes suggests there are variations in backbone conformations between TG and Tel aggregates. TG aggregates were more resistant to digestion by DNase I, Mung Bean nuclease, and S1 nuclease than Tel complexes. It is proposed that the lower DNase I sensitivity may be partly due to the more stable backbone exhibited by TG than Tel complexes. Structural uniformity along the guanine core of TG is suggested, as there is no indication of structural discontinuities or protected sites in the guanine-rich regions of TG aggregates. The lower extent of digestion by Mung Bean nuclease at the 3' end implies that these bases are inaccessible to the enzyme. This suggests that there is minimal fraying at the ends, which is consistent with the extreme thermal stability of the TG aggregates.     

Chromatin structure of the chicken beta-globin gene region. Sensitivity to DNase I, micrococcal nuclease, and DNase II

We have examined in some detail the chromatin structure of a 6.2 kilobase pair (kbp) chromosomal region containing the chicken beta-globin gene. The chromatin structure was probed with three nucleases, DNase I, micrococcal nuclease, and DNase II, and the rate of digestion of specific subfragments of the region was compared with the rate of bulk DNA digestion. We have characterized the rate of digestion of each fragment in terms of a sensitivity factor which measures the sensitivity of a fragment to a particular nuclease relative to bulk DNA. The sensitivity factors were determined by a least squares curve fitting method based on target analysis. In nuclei isolated from 14-day-old chicken embryo red blood cells, the entire 6.2-kbp region shows approximately a 10- to 20-fold increase in sensitivity to DNase I, a 3-fold increased sensitivity to micrococcal nuclease, and a 6-fold increased sensitivity to DNase II. In addition to the adult beta-globin gene, this region contains 5' and 3' flanking sequences, the 5' half of the inactive, embryonic globin gene, epsilon, and some repeated sequences. There is no obvious correlation between these genetic elements and the overall chromatin structure as measured by the nuclease sensitivity. This same region shows little or no special sensitivity in nuclei isolated from 14-day-old chicken embryo brain. Furthermore, fragments of the inactive ovalbumin gene show little or no sensitivity in either red blood cells or brain. These results support the conclusion that the entire 6.2-kbp region is largely packaged as active chromatin in 14-day-old chicken embryo red blood cells.     

Site-specific interaction of vaccinia virus topoisomerase I with duplex DNA. Minimal DNA substrate for strand cleavage in vitro.

Purified vaccinia virus DNA topoisomerase I forms a cleavable complex with duplex DNA at a conserved sequence element 5'(C/T)CCTTdecreases in the incised DNA strand. DNase I footprint studies show that vaccinia topoisomerase protects the region around the site of covalent adduct formation from nuclease digestion. On the cleaved DNA strand, the protected region extends from +13 to -13 (+1 being the site of cleavage). On the noncleaved strand, the protected region extends from +13 to -9. Similar nuclease protection is observed for a mutant topoisomerase (containing a Tyr ---- Phe substitution at the active site amino acid 274) that is catalytically inert and does not form the covalent intermediate. Thus, vaccinia topoisomerase is a specific DNA binding protein independent of its competence in transesterification. By studying the cleavage of a series of 12-mer DNA duplexes in which the position of the CCCTTdecreases motif within the substrate is systematically phased, the "minimal" substrate for cleavage has been defined; cleavage requires six nucleotides upstream of the cleavage site and two nucleotides downstream of the site. An analysis of the cleavage of oligomer substrates mutated singly in the CCCTT sequence reveals a hierarchy of mutational effects based on position within the pentamer motif and the nature of the sequence alteration.     

DNase,RNase, and phosphatase activities of antibodies formed upon immunization by DNA,DNase I,and DNase II

Relative DNase, RNase (efficiency of hydrolysis of ribo- and deoxyribooligonucleotides (ON)), and phosphatase (removal of the ON 5′ terminal phosphate) catalytic activities of antibodies (AB) obtained after rabbit immunization by DNA, DNase I, and DNase II were compared. It is shown that electrophoretically homogeneous preparations of polyclonal AB from non-immunized rabbits did not exhibit such activities. Immunization of rabbits by DNA, DNase I, and DNase II results in generation of IgG abzymes that exhibit high activity in the ON hydrolysis reaction and even higher activity in cleavage of 5′ terminal phosphate of ON. In this case K _m values for supercoiled plasmid DNA and ON found in reactions of their AB-dependent nuclease hydrolysis and phosphatase cleavage of 5′ terminal phosphate differ by 2–4 orders of magnitude. This shows that nuclease and phosphatase activities belong to different abzyme fractions within polyclonal AB. Thus, in this work data indicative of the possibility of a formation of antibodies exhibiting phosphatase activity after immunization of animals with DNA, DNase I, and DNase II, were obtained for the first time. Possible reasons for production of AB with phosphatase activity after immunization of rabbits with these immunogens are discussed.     

DNase I hypersensitive regions correlate with a site-specific endogenous nuclease activity on the r-chromatin of Tetrahymena

A novel nuclease activity have been detected at three specific sites in the chromatin of the spacer region flanking the 5'-end of the ribosomal RNA gene from Tetrahymena. The endogenous nuclease does not function catalytically in vitro, but is in analogy with the DNA topoisomerases activated by strong denaturants to cleave DNA at specific sites. The endogenous cleavages have been mapped at positions +50, -650 and -1100 relative to the 5'-end of the pre-35S rRNA. The endogenous cleavage sites are associated with micrococcal nuclease hypersensitive sites and DNase I hypersensitive regions. Thus, a single well-defined micrococcal nuclease hypersensitive site is found approximately 130 bp upstream from each of the endogenous cleavages. Clusters of defined sites, the majority of which fall within the 130 bp regions defined by vicinal micrococcal nuclease and endogenous cleavages, constitute the DNase I hypersensitive regions.     

DNase I cleavage of branched DNA molecules

We report here a potentially useful signature of branched DNA structures. The base 5' to the branch and the five bases flanking the 3' side of the branch site are protected from cleavage by DNase I in both three- and four-arm branched DNA molecules. Our procedure is to measure the cleavage profile for each 5' -labeled strand in a control duplex and compare this with that of the same strand in a branched structure under conditions yielding less than one cut per strand. The resulting cleavage pattern in an immobile four-arm junction is roughly 2-fold symmetric, consistent with the pattern of Fe(II).EDTA-induced cleavage that has been observed previously. In the three-arm junction, the DNase I cleavage pattern is asymmetric, indicating lack of 3-fold symmetry. A variable pattern of protection occurs to the 5' side of the branch in some strands only for both three- and four-arm junctions, extending 2-4 residues 5' to the branch.     

Functional characterization of DNase X, a novel endonuclease expressed in muscle cells

The activation of endonucleases resulting in the degradation of genomic DNA is one of the most characteristic changes in apoptosis. Here, we report the characterization of a novel endonuclease, termed DNase X due to its X-chromosomal localization. The active nuclease is a 35 kDa protein with 39% identity to DNase I. When incubated with isolated nuclei, recombinant DNase X was capable of triggering DNA degradation at internucleosomal sites. Similarly to DNase I, the nuclease activity of DNase X was dependent on Ca(2+) and Mg(2+) and inhibited by Zn(2+) ions or chelators of bivalent cations. Overexpression of DNase X caused internucleosomal DNA degradation and induction of cell death associated with increased caspase activation. Despite the presence of two potential caspase cleavage sites, DNase X was processed neither in vitro nor in vivo by different caspases. Interestingly, after initiation of apoptosis DNase X was translocated from the cytoplasm to the nuclear compartment and aggregated as a detergent-insoluble complex. Abundant expression of DNase X mRNA was detected in heart and skeletal muscle cells, suggesting that DNase X may be involved in apoptotic or other biological events in muscle tissues.     

Evidence that the nuclease activities associated with the herpes simplex type 1 DNA polymerase are due to the 3'-5' exonuclease.

We investigated nuclease activities associated with the catalytic subunit of herpes simplex virus type 1 DNA polymerase. We confirm that a 3'-5' exonuclease copurifies with this enzyme. Previous reports suggested that a 5' DNase was intrinsic to the polymerase. Our preparation lacks such activity.     

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.     

A human telomerase-associated nuclease

Ciliate and yeast telomerase possess a nucleolytic activity capable of removing DNA from the 3' end of a single-stranded oligonucleotide substrate. The nuclease activity is thought to assist in enzyme proofreading and/or processivity. Herein, we report a previously uncharacterized human telomerase-associated nuclease activity that shares several properties with ciliate and yeast telomerases. Partially purified human telomerase, either from cell extracts or recombinantly produced, demonstrated an ability to remove 3' nontelomeric nucleotides from a substrate containing 5' telomeric DNA, followed by extension of the newly exposed telomeric sequence. This cleavage/extension activity was apparent at more than one position within the telomeric DNA and was influenced by sequences 5' to the telomeric/nontelomeric boundary and by substitution with a methylphosphonate moiety at the telomeric/nontelomeric DNA boundary. Our data suggest that human telomerase is associated with an evolutionarily conserved nucleolytic activity and support a model in which telomerase-substrate interactions can occur distal from the 3' primer end.