Investigation and improvement of DNA cleavage models of polyamide + Cu(II) nuclease + OOH<Superscript>-</Superscript> ligands bound to DNA

Background  

Copper nucleases as a famous class of artificial metallonucleases have attracted considerable interest in relation to their diverse potentials not only as therapeutic agents but also in genomic researches. Copper nucleases present high efficient oxidative cleavage of DNA, in which DNA strand scission occurs generally after hydrogen atom abstracted from a sugar moiety. In order to achieve the selective cleavage of DNA sequences by copper nucleases, the DNA specific recognition agents of the Dervan-type hairpin and cyclic polyamides can be considered as proper carriers of copper nucleases. Investigation of the DNA cleavage selectivity of copper nucleases assisted by the hairpin and cyclic polyamides at the molecular level has not yet been elucidated.     

Using molecular beacons as a sensitive fluorescence assay for enzymatic cleavage of single-stranded DNA

Traditional methods to assay enzymatic cleavage of DNA are discontinuous and time consuming. In contrast, recently developed fluorescence methods are continuous and convenient. However, no fluorescence method has been developed for single-stranded DNA digestion. Here we introduce a novel method, based on molecular beacons, to assay single-stranded DNA cleavage by single strand-specific nucleases. A molecular beacon, a hairpin-shaped DNA probe labeled with a fluorophore and a quencher, is used as the substrate and enzymatic cleavage leads to fluorescence enhancement in the molecular beacon. This method permits real time detection of DNA cleavage and makes it easy to characterize the activity of DNA nucleases and to study the steady-state cleavage reaction kinetics. The excellent sensitivity, reproducibility and convenience will enable molecular beacons to be widely useful for the study of single-stranded DNA cleaving reactions.     

DNA Segments Sensitive to Single-Strand-Specific Nucleases Are Present in Chromatin of Mitotic Cells

It was observed before that DNAin situin chromatin of mitotic cells is more sensitive to denaturation than DNA in chromatin of interphase cells. DNA sensitivity to denaturation, in these studies, was analyzed by exposing cells to heat or acid and using acridine orange (AO), the metachromatic fluorochrome which can differentially stain double-stranded (ds) vs single-stranded (ss) nucleic acids, as a marker of the degree of DNA denaturation. However, without prior cell treatment with heat or acid no presence of single-stranded DNA in either mitotic or interphase cells was detected by this assay. In the present experiments we demonstrate that DNAin situin mitotic cells, without any prior treatment that can induce DNA denaturation, is sensitive to ss-specific S1 and mung bean nucleases. Incubation of permeabilized human T cell leukemic MOLT-4, promyelocytic HL-60, histiomonocytic lymphoma U937 cells, or normal PHA-stimulated lymphocytes with S1 or mung bean nucleases generated extensive DNA breakage in mitotic cells. DNA strand breaks were detected using fluorochrome-labeled triphosphonucleotides in the reaction catalyzed by exogenous terminal deoxynucleotidyl transferase. Under identical conditions of the cells’ exposure to ss-specific nucleases, DNA breakage in interphase cells was of an order of magnitude less extensive compared to mitotic cells. The data indicate that segments of DNA in mitotic chromosomes, in contrast to interphase cells, may be in a conformation which is sensitive to ss nucleases. This may be a reflection of the differences in the torsional stress of DNA loops between interphase and mitotic chromatin. Namely, greater stress in mitotic loops may lead to formation of the hairpin-loop structures by inverted repeats; such structures are sensitive to ss nucleases. The present method of detection of such segments appears to be more sensitive than the use of AO. The identification of mitotic cells based on sensitivity of their DNA to ss nucleases provides an additional method for their quantification by flow cytometry.     

StpA protein from Escherichia coli condenses supercoiled DNA in preference to linear DNA and protects it from digestion by DNase I and EcoKI

The nucleoid-associated protein, StpA, of Escherichia coli binds non-specifically to double-stranded DNA (dsDNA) and apparently forms bridges between adjacent segments of the DNA. Such a coating of protein on the DNA would be expected to hinder the action of nucleases. We demonstrate that StpA binding hinders dsDNA cleavage by both the non-specific endonuclease, DNase I, and by the site-specific type I restriction endonuclease, EcoKI. It requires approximately one StpA molecule per 250–300 bp of supercoiled DNA and approximately one StpA molecule per 60–100 bp on linear DNA for strong inhibition of the nucleases. These results support the role of StpA as a nucleoid-structuring protein which binds DNA segments together. The inhibition of EcoKI, which cleaves DNA at a site remote from its initial target sequence after extensive DNA translocation driven by ATP hydrolysis, suggests that these enzymes would be unable to function on chromosomal DNA even during times of DNA damage when potentially lethal, unmodified target sites occur on the chromosome. This supports a role for nucleoid-associated proteins in restriction alleviation during times of cell stress.     

Characterization of distinct segments in mouse satellite DNA by restriction nucleases.

The long-range periodicity of mouse satellite DNA has been analyzed by digestion with five restriction nucleases. With all nucleases tested, a major repeat unit approximately 245 nucleotide pairs became apparent. Minor registers of shorter length were also detected. The total number of cleavage sites per haploid genome for each restriction enzyme as well as their positions relative to each other were determined. While endo R-EcoRII was known to cleave all of the satellite DNA, the other four restriction enzymes were found to generate only weak degradation patterns. The results taken together with quantitative analyses of codigestion experiments indicate that the recognition sequences for each of these four nucleases are clustered on separate parts of the satellite DNA. It is concluded that the satellite DNA, which appears homogeneous by digestion with endo R-EcRII, contains distinct segments each susceptible to degradation with one of the other nucleases. These results have certain implications for theories on the evolution of mouse satellite DNA. A simple mechanism of multiplication and divergence by mutation is not sufficient to explain the data. Additional and alternative processes which are relevant to the evolutionary considerations are discussed.     

The Methanothermobacter thermautotrophicus ExoIII homologue Mth212 is a DNA uridine endonuclease

The genome of Methanothermobacter thermautotrophicus, as a hitherto unique case, is apparently devoid of genes coding for general uracil DNA glycosylases, the universal mediators of base excision repair following hydrolytic deamination of DNA cytosine residues. We have now identified protein Mth212, a member of the ExoIII family of nucleases, as a possible initiator of DNA uracil repair in this organism. This enzyme, in addition to bearing all the enzymological hallmarks of an ExoIII homologue, is a DNA uridine endonuclease (U-endo) that nicks double-stranded DNA at the 5′-side of a 2′-d-uridine residue, irrespective of the nature of the opposing nucleotide. This type of activity has not been described before; it is absent from the ExoIII homologues of Escherichia coli, Homo sapiens and Methanosarcina mazei, all of which are equipped with uracil DNA repair glycosylases. The U-endo activity of Mth212 is served by the same catalytic center as its AP-endo activity.     

DNA folding in the nucleosome

Digestion of chromatin with a number of nucleases shows that the DNA is regularly folded in the nucleosome. Particularly cleavage by pancreatic DNase (DNase I) in the 140 base-pair nucleosome has been examined. This nuclease nicks the DNA every ten bases on each strand as demonstrated by labeling the 5′-ends of the 140 base-pair nucleosome. Cleavage sites on opposite strands are staggered by two bases. This proves that the DNA is arranged on the outside of the histone core in a regular way. The probability distribution of nicking might indicate a 2-fold symmetry of the 140 base-pair nucleosome. In particular it is shown that the predominant band of 80 bases is derived from several regions within the 140 base-pairs and suggested to reflect the pitch of the DNA superhelix surrounding the histone core of the nucleosome. Its possible significance with respect to chromatin structure is discussed.     

Restriction Enzyme Digests of Rapidly Renaturing Fragments of Vaccinia Virus DNA

Vaccinia virus DNA fragments that have been denatured by alkali and then neutralized contain a fraction that rapidly reforms duplex structures. The fraction is enriched by fractionating on hydroxyapatite columns and serves as a substrate for digestion by two restriction endonucleases isolated from Hemophilus parainfluenzae, Hpa I and HPa II. The patterns obtained by gel electrophoresis of the digested fragments show the presence of three major bands after Hpa I digestion and four major bands after Hpa II digestion. The DNA that is isolated from some of these bands quickly reforms duplex regions after alkaline denaturation. The size of the DNA segments in the major bands has been estimated to be in the range of 0.44 × 10⁶ to 3.2 × 10⁶ daltons. The fragments which rapidly reform duplex chains after denaturation are sensitive to single-strand-specific nucleases. These results are consistent with a model of vaccinia virus DNA which has a covalent link connecting complementary chains.     

Evaluation of Biological and Physical Protection against Nuclease Degradation of Clay-Bound Plasmid DNA

In order to determine the mechanisms involved in the persistence of extracellular DNA in soils and to monitor whether bacterial transformation could occur in such an environment, we developed artificial models composed of plasmid DNA adsorbed on clay particles. We determined that clay-bound DNA submitted to an increasing range of nuclease concentrations was physically protected. The protection mechanism was mainly related to the adsorption of the nuclease on the clay mineral. The biological potential of the resulting DNA was monitored by transforming the naturally competent proteobacterium Acinetobacter sp. strain BD413, allowing us to demonstrate that adsorbed DNA was only partially available for transformation. This part of the clay-bound DNA which was available for bacteria, was also accessible to nucleases, while the remaining fraction escaped both transformation and degradation. Finally, transformation efficiency was related to the perpetuation mechanism, with homologous recombination being less sensitive to nucleases than autonomous replication, which requires intact molecules.     

Structure-specific DNA nucleases: structural basis for 3D-scissors

Structure-specific DNA nucleases play important roles in various DNA transactions such as DNA replication, repair and recombination. These enzymes recognize loops and branched DNA structures. Recent structural studies have provided detailed insights into the functions of these enzymes. Structures of Holliday junction resolvase revealed that nucleases are broadly diverged in the way in which they fold, however, are required to form homodimers with large basic patches of protein surfaces, which are complementary to DNA tertiary structures. Many nucleases maintain structure-specific recognition modes, which involve particular domain arrangements through conformal changes of flexible loops or have a separate DNA binding domain. Nucleases, such as FEN-1 and archaeal XPF, are bound to proliferating cell nuclear antigen through a common motif, and thereby actualize their inherent activities.     

Gold Nanoparticle Based FRET for DNA Detection

The nanoscience revolution that sprouted throughout the 1990s is having great impact in current and future DNA detection technology around the world. In this review, we report our recent progress on gold nanoparticle based fluorescence resonance energy transfer assay to monitor DNA hybridization as well as the cleavage of DNA by nucleases. We tried to discuss a reasonable account of the science and the important fundamental work carried out in this area. We also report the development of a compact, highly specific, inexpensive and user-friendly optical fiber laser-induced fluorescence sensor based on fluorescence quenching by nanoparticles to detect single-strand DNA hybridization at femtomolar level.     

The Mre11-Rad50-Xrs2 Complex Is Required for Yeast DNA Postreplication Repair

Yeast DNA postreplication repair (PRR) bypasses replication-blocking lesions to prevent damage-induced cell death. PRR employs two different mechanisms to bypass damaged DNA, namely translesion synthesis (TLS) and error-free PRR, which are regulated via sequential ubiquitination of proliferating cell nuclear antigen (PCNA). We previously demonstrated that error-free PRR utilizes homologous recombination to facilitate template switching. To our surprise, genes encoding the Mre11-Rad50-Xrs2 (MRX) complex, which are also required for homologous recombination, are epistatic to TLS mutations. Further genetic analyses indicated that two other nucleases involved in double-strand end resection, Sae2 and Exo1, are also variably required for efficient lesion bypass. The involvement of the above genes in TLS and/or error-free PRR could be distinguished by the mutagenesis assay and their differential effects on PCNA ubiquitination. Consistent with the observation that the MRX complex is required for both branches of PRR, the MRX complex was found to physically interact with Rad18 in vivo. In light of the distinct and overlapping activities of the above nucleases in the resection of double-strand breaks, we propose that the interplay between distinct single-strand nucleases dictate the preference between TLS and error-free PRR for lesion bypass.     

Resolving branched DNA intermediates with structure-specific nucleases during replication in eukaryotes

Genome duplication requires that replication forks track the entire length of every chromosome. When complications occur, homologous recombination-mediated repair supports replication fork movement and recovery. This leads to physical connections between the nascent sister chromatids in the form of Holliday junctions and other branched DNA intermediates. A key role in the removal of these recombination intermediates falls to structure-specific nucleases such as the Holliday junction resolvase RuvC in Escherichia coli. RuvC is also known to cut branched DNA intermediates that originate directly from blocked replication forks, targeting them for origin-independent replication restart. In eukaryotes, multiple structure-specific nucleases, including Mus81–Mms4/MUS81–EME1, Yen1/GEN1, and Slx1–Slx4/SLX1–SLX4 (FANCP) have been implicated in the resolution of branched DNA intermediates. It is becoming increasingly clear that, as a group, they reflect the dual function of RuvC in cleaving recombination intermediates and failing replication forks to assist the DNA replication process.     

DNA condensation by the nucleocapsid protein of HIV-1: a mechanism ensuring DNA protection

The nucleocapsid (NC) protein NCp7 of the immunodeficiency virus type 1 is a small basic protein with two zinc finger motifs. NCp7 has key roles in virus replication and structure, which rely on its interactions with nucleic acids. Although most interactions involve RNAs, binding to the viral DNA is thought to be of importance to achieve protection of the DNA against cellular nucleases and its integration into the host genome. We investigated the interaction of NCp7 with plasmid DNA as a model system. The fluorescence probe YOYO-1 was used as the reporter. Binding of NCp7 to DNA caused DNA condensation, as inferred from the dramatic decrease in YOYO-1 fluorescence. Efficient condensation of DNA required the full length NCp7 with the zinc fingers. The fingerless peptide was less efficient in condensing DNA. Binding of both these NC peptides led to freezing of the segmental dynamics of DNA as revealed by anisotropy decay kinetics of YOYO-1. The truncated peptide NC(12–55) which retains the zinc fingers did not lead to DNA condensation despite its ability to bind and partially freeze the segmental motion of DNA. We propose that the histone-like property of NCp7 leading to DNA condensation contributes to viral DNA stability, in vivo.     

Excision of amplified viral DNA at palindromic sequences from the adenovirus type 12-transformed hamster cell line T637.

In the DNA of the adenovirus type 12 (Ad12)-transformed hamster cell line T637 approximately 20-22 viral DNA molecules per cell are covalently linked to cellular DNA. Spontaneously arising morphological revertants of T637 cells have lost the bulk of the viral DNA. We have been able to mimic the excision event of viral DNA, as it occurs during reversion, by autoincubation of isolated nuclei from T637 cells. The same Ad12 DNA sequences, which had been deleted in morphological revertants, proved highly sensitive to endogenous nucleases in isolated nuclei of T637 cells. Viral DNA sequences, which persisted in the revertants, are resistant to endogenous nucleases in isolated T637 nuclei. All attempts to clone the nuclease-sensitive sites of Ad12 DNA in cell line T637 have so far failed. After denaturation and renaturation of T637 DNA followed by treatment with S1 nuclease, large fold-back structures of DNA have been found. These snap-back structures were derived from precisely those viral DNA restriction fragments which were uncloneable. The fragments containing palindromic sequences were both highly sensitive to endogenous nucleases in isolated T637 nuclei and were absent from the DNA of all revertant cell lines. Moreover, the palindromic sequences are susceptible to the phage T4-specific endonuclease VII which specifically attacks cruciform structures in DNA. The peculiar structures at the termini of integrated Ad12 DNA molecules are highly sensitive to endogenous nucleases in isolated nuclei. These nucleases may be related to the reversion event.     

Rapid clearance of fetal DNA from maternal plasma.

Fetal DNA has been detected in maternal plasma during pregnancy. We investigated the clearance of circulating fetal DNA after delivery, using quantitative PCR analysis of the sex-determining region Y gene as a marker for male fetuses. We analyzed plasma samples from 12 women 1-42 d after delivery of male babies and found that circulating fetal DNA was undetectable by day 1 after delivery. To obtain a higher time-resolution picture of fetal DNA clearance, we performed serial sampling of eight women, which indicated that most women (seven) had undetectable levels of circulating fetal DNA by 2 h postpartum. The mean half-life for circulating fetal DNA was 16.3 min (range 4-30 min). Plasma nucleases were found to account for only part of the clearance of plasma fetal DNA. The rapid turnover of circulating DNA suggests that plasma DNA analysis may be less susceptible to false-positive results, which result from carryover from previous pregnancies, than is the detection of fetal cells in maternal blood; also, rapid turnover may be useful for the monitoring of feto-maternal events with rapid dynamics. These results also may have implications for the study of other types of nonhost DNA in plasma, such as circulating tumor-derived and graft-derived DNA in oncology and transplant patients, respectively.