DNase Specific for Uracil-Containing Bacteriophage DNA

A DNase from Bacillus subtilis which specifically hydrolyzes native DNA of phage PBS 1 has been purified and characterized. The mode of action of the enzyme is endonucleolytic, yielding deoxyuridine and oliogonucleotides of various sizes. The primary site of enzymatic attack is deoxyuridylic acid in the DNA. A mild nitrous acid treatment of thymine-containing thymus DNA, which deaminates 30% of the cytosine residues, renders the DNA susceptible to the DNase. Nicked DNA from coli phage T5 and hydroxymethyluracil-containing DNA from phage PBS 15 are not sensitive to this DNase.     

Silver staining of DNA restriction fragments for the ultrarapid identification of pseudorabies virus strains.

Restriction endonuclease analysis of pseudorabies virus DNA has been used to study various virus strains. To make use of a rapid technique for the identification of viral strains, studies have been undertaken to facilitate purification of the DNA from viral particles present in cytoplasmic fractions. The ultrasensitive photochemical silver staining of nucleic acid, described by Beidler et al. (Analytic Biochemistry 1982: 126) has been adapted and applied to the detection of pseudorabies virus restriction fragments. In a period of 5 h more than 1 microgram of DNA can be extracted from a 25 cm2 plastic flask containing infected cells and purified without ultra centrifugation. Low molecular weight DNA was separated from high molecular weight DNA by polyacrylamide gel electrophoresis. The restriction fragments were selectively visualized by silver staining which can detect 0.025 micrograms of total pseudorabies virus DNA. The electrophoretic DNA pattern of vaccine and wild strains has been studied using these techniques and the results agree with previously published data.     

DNA repair: insights from urinary lesion analysis

Due to various confounding factors, namely dietary contribution and cell death, measurement of urinary 8-oxo-2'-deoxyguanosine (8-oxodG) has long been considered to be no more than a marker of generalised oxidative stress. Indeed, the action of no single enzyme has been reported to excise 8-oxodG from DNA. However, analysis of recent research has suggested that these confounders may be circumvented, which, combined from work from the authors' laboratory, indicates that urinary 8-oxodG has the potential to become a most important marker of oxidative damage to, and repair of, DNA.     

Isolation and regional localization of DNA segments revealing polymorphic loci from human chromosome 13.

A recombinant DNA library enriched for portions of human chromosome 13 has been constructed from a hamster-human somatic cell hybrid that contained human chromosomes 13, 12, and 6p. A total of 733 phages were identified that contain human DNA inserts, and 46 single-copy subfragments have been derived and used as probes on Southern transfers of genomic DNA isolated from unrelated individuals. From this set, nine fragments revealing polymorphic loci (RFLP) in Msp I- or Taq I-digested DNA have been identified, of which three are polymorphic with both enzymes. Six of these probes have been shown to segregate concordantly with human chromosome 13 in a somatic cell hybrid mapping panel, and the RFLPs at these loci have been shown to behave as codominant Mendelian alleles. Additionally, hybridization to DNA isolated from cells containing various deletions of chromosome 13 has allowed regional localization. This recombinant DNA library will be useful in the study of retinoblastoma as well as in the study of the mechanisms responsible for abnormalities of this autosome.     

DNA markers in plant improvement: an overview

The progress made in DNA marker technology has been tremendous and exciting. DNA markers have provided valuable tools in various analyses ranging from phylogenetic analysis to the positional cloning of genes. The development of high-density molecular maps which has been facilitated by PCR-based markers, have made the mapping and tagging of almost any trait possible. Marker-assisted selection has the potential to deploy favorable gene combinations for disease control. Comparative studies between incompatible species using these markers has resulted in synteny maps which are useful not only in predicting genome organization and evolution but also have practical application in plant breeding. DNA marker technology has found application in fingerprinting genotypes, in determining seed purity, in systematic sampling of germplasm, and in phylogenetic analysis. This review discusses the use of this technology for the genetic improvement of plants.     

Preparation, properties and fractionation of the nuclear deoxyribonucleic acid from guinea pig brain

L ittle work has been done on the chemical and physical properties of brain nuclear DNA. Recently D u B uy , M attern and R iley (1966) described the heat denaturation of mouse brain nuclear DNA, which apparently differs from the related mitochondrial DNA and the various protozoal DNA's tested. For such studies, it is essential to prepare the nuclear DNA from brain tissues in a native and highly polymerized state. In this brief communication preparation procedures of the native DNA from isolated brain nuclei are described, and some physical and chemical properties are given.     

DNA Repair: Insights from Urinary Lesion Analysis

Due to various confounding factors, namely dietary contribution and cell death, measurement of urinary 8-oxo-2'-deoxyguanosine (8-oxodG) has long been considered to be no more than a marker of generalised oxidative stress. Indeed, the action of no single enzyme has been reported to excise 8-oxodG from DNA. However, analysis of recent research has suggested that these confounders may be circumvented, which, combined from work from the authors' laboratory, indicates that urinary 8-oxodG has the potential to become a most important marker of oxidative damage to, and repair of, DNA.     

Formation of ring-opened and rearranged products of guanine: mechanisms and biological significance

DNA damage by endogenous and exogenous agents is a serious concern, as the damaged products can affect genome integrity severely. Damage to DNA may arise from various factors such as DNA base modifications, strand break, inter- and intrastrand crosslinks, and DNA-protein crosslinks. Among these factors, DNA base modification is a common and important form of DNA damage that has been implicated in mutagenesis, carcinogenesis, and many other pathological conditions. Among the four DNA bases, guanine (G) has the smallest oxidation potential, because of which it is frequently modified by reactive species, giving rise to a plethora of lethal lesions. Similarly, 8-oxo-7,8-dihydroguanine (8-oxoG), an oxidatively damaged guanine lesion, also undergoes various degradation reactions giving rise to several mutagenic species. The various products formed from reactions of G or 8-oxoG with different reactive species are mainly 2,6-diamino-4-oxo-5-formamidopyrimidine, 2,5-diamino-4H-imidazolone, 2,2,4-triamino-5-(2H)-oxazolone, 5-guanidino-4-nitroimidazole, guanidinohydantoin, spiroiminodihydantoin, cyanuric acid, parabanic acid, oxaluric acid, and urea, among others. These products are formed from either ring opening or ring opening and subsequent rearrangement. The main aim of this review is to provide a comprehensive overview of various possible reactions and the mechanisms involved, after which these ring-opened and rearranged products of guanine would be formed in DNA. The biological significance of oxidatively damaged products of G is also discussed.     

Thymus-derived inhibitor of lymphocyte proliferation. II. Tissue specificity in vitro and in vivo

A thymus crude factor (TCF) isolated from bovine thymus tissue has been tested for its effects on the proliferation of various murine cells. Specific inhibition in vitro has been found for DNA synthesis in murine T and B lymphocytes which appears not to be based on cytotoxicity. Moreover, TCF, when administered to mice, also interferes with the DNA synthesis in lymphoid tissue in vivo. Our data are suggestive for the presence in TCF of an endogenous 'chalone-like' inhibitor of lymphoid cell proliferation in vitro and in vivo.     

Studies on the interaction of H1 histone with superhelical DNA: characterization of the recognition and binding regions of H1 histones.

The very lysine rich histone, H1, isolated from a variety of sources interacts preferentially with superhelical DNA compared to relaxed DNA duplexes. The nature of this specific interaction has been investigated by studying the ability of various purified fragments of H1 histone from calf thymus to recognize and bind superhelical DNA. The data suggest that the globular region of the H1 histone molecule (amino acid residues 72-106) is involved in the recognition of superhelical DNA. Thus, the H1 histone carboxy-terminal fragment, 72-212, resembles native H1 histone both quantitatively and qualitatively in its ability to discriminate between and bind to superhelical and relaxed DNA while the H1 histone carboxy-terminal fragment, residues 106-212, has lost this specificity, binding superhelical and relaxed DNA equally well. Furthermore, under conditions in which the globular region of the intact H1 histone has been unfolded, the molecule loses its ability to discriminate between superhelical and relaxed DNA, and binds both forms of DNA equally.     

RIF1: A novel regulatory factor for DNA replication and DNA damage response signaling

DNA double strand breaks (DSBs) are highly toxic to the cells and accumulation of DSBs results in several detrimental effects in various cellular processes which can lead to neurological, immunological and developmental disorders. Failure of the repair of DSBs spurs mutagenesis and is a driver of tumorigenesis, thus underscoring the importance of the accurate repair of DSBs. Two major canonical DSB repair pathways are the non-homologous end joining (NHEJ) and homologous recombination (HR) pathways. 53BP1 and BRCA1 are the key mediator proteins which coordinate with other components of the DNA repair machinery in the NHEJ and HR pathways respectively, and their exclusive recruitment to DNA breaks/ends potentially decides the choice of repair by either NHEJ or HR. Recently, Rap1 interacting factor 1 has been identified as an important component of the DNA repair pathway which acts downstream of the ATM/53BP1 to inhibit the 5′–3′ end resection of broken DNA ends, in-turn facilitating NHEJ repair and inhibiting homology directed repair. Rif1 is conserved from yeast to humans but its function has evolved from telomere length regulation in yeast to the maintenance of genome integrity in mammalian cells. Recently its role in the maintenance of genomic integrity has been expanded to include the regulation of chromatin structure, replication timing and intra-S phase checkpoint. We present a summary of these important findings highlighting the various aspects of Rif1 functions and discuss the key implications for genomic integrity.     

Fractionation of a chalone-containing substance from Ehrlich's ascites tumor using high pressure chromatography]

The effect of various fractions of chalone--containing preparation from ascyte Ehrlich's tumour obtained by high performance liquid chromatography (HPLC) on mitotic activity and DNA synthesis in the tumour has been studied. After filtration the division of active chalone component which inhibits entering cells into M-phase and S-phase took place. The component inhibiting DNA synthesis eluated with G1-chalone.     

Methods for microbial DNA extraction from soil for PCR amplification

Amplification of DNA from soil is often inhibited by co-purified contaminants. A rapid, inexpensive, large-scale DNA extraction method involving minimal purification has been developed that is applicable to various soil types (1). DNA is also suitable for PCR amplification using various DNA targets. DNA was extracted from 100g of soil using direct lysis with glass beads and SDS followed by potassium acetate precipitation, polyethylene glycol precipitation, phenol extraction and isopropanol precipitation. This method was compared to other DNA extraction methods with regard to DNA purity and size.     

The assay and isolation of DNA rings using an ATP-dependent endonuclease.

The ATP-dependent endonuclease from Hemophilus influenzae is relatively inactive on closed or open DNA rings, yet rapidly hydrolyzes single- or double-chained linear DNA. This enzyme in combination with an exonuclease (exo VII) has been shown to spare various circular DNA molecules including those having single-chain regions of significant length. However, rings containing single-chained regions are broken at a rate depending on the length of these regions. By admixing a linear DNA of alternate radiolabel, a simple assay for DNA rings has been developed. The application of this procedure to the assay of folded rings from Drosophila DNA is demonstrated.     

Classification analysis of a latent dinucleotide periodicity of plant genomes

The information decomposition (ID) method has been used for searching dinucleotide periodicities, including latent ones, in plant genomes. In nucleotide sequences of genomes of various plants from the GenBank database, 14766 sequences with a periodicity of two nucleotides have been found. Classification of the periodicity matrices of the detected DNA sequences has yielded 141 classes of dinucleotide periodicity. Since ID does not detect periodicities with nucleotide deletions or insertions, modified profile analysis (MPA) has been applied to the obtained classes to reveal DNA sequences with dinucleotide periodicities containing nucleotide deletions and insertions. Combined use of ID and MPA has permitted the detection of 80 396 DNA sequences with dinucleotide periodicities in the genomes of various plants. The biological role of dinucleotide periodicity in the detected sequences is discussed.     

105 Activity of DNA ligase on substrates containing non-canonical structures

The expansion of trinucleotide repeat tracts (e.g. (CAG)_n tracts) has been shown to contribute to genomic instability and has been implicated in the pathogenesis of several neurodegenerative diseases, including Huntington’s Disease and Fragile X syndrome (Kovtun et al., 2008). While the molecular mechanism of this expansion is unknown, the ability of trinucleotide repeat sequences to form non-canonical secondary structures, such as hairpins, has been implicated as a multifaceted source of error (Gacy et al., 1995). Non-canonical DNA secondary structures have been shown to impact the action of enzymes in the base excision repair (BER) pathway, by which oxidatively damaged bases are removed. More specifically, there is evidence that trinucleotide repeat-containing DNA mistakenly enters long-patch BER, which can potentially lead to the incorporation of extra nucleobases by DNA polymerase (Jarem et al., 2011). The final enzyme in the BER pathway is DNA Ligase, which catalyses the formation of a phosphodiester bond to seal a nick site (Taylor et al., 2011). When extra nucleotides have been added during an erroneous long-patch BER process, the action of DNA ligase may expand the repeat tract by incorporating these additional bases into duplex DNA. In this study, DNA constructs containing (CAG)_n hairpins at various distances from a nick site are used to investigate the ability of DNA Ligase to ligate substrates containing non-canonical secondary structure back into duplex DNA.     

Effect of different fractions obtained by gel filtration of a chalone-containing preparation from Ehrlich ascites tumor on mitotic activity and DNA synthesis in this tumor

The effect of various fractions of chalone-containing preparation from ascite Ehrlich's tumour obtained by gel filtration on ultragel Ac-A-44 on mitotic activity and DNA synthesis in the tumour has been studied. The chalone-containing preparation (alcohol precipitate) was shown to suppress entering of tumour cells into M- and S-phase and DNA synthesis. After gel filtration, the partial division of active chalone component which inhibits entering of cells into M- and S-phase took place. The component inhibiting DNA synthesis eluted with G1-chalone.     

Genomic fingerprinting: new possibilities in determining the species identity of Brucella

The genomes of various Brucella species were shown to contain hypervariable sequences which can be detected by the M13 DNA. It has been demonstrated that the method of DNA fingerprinting opens up new possibilities in differentiation and identification of Brucellosis agents.     

Sequence-specific covalent labelling of DNA

Sequence-specific DNA modification is of significance for applications in bio- and nano-technology, medical diagnostics and fundamental life sciences research. Preferentially, labelling should be performed covalently, which avoids doubts about label dissociation from the DNA under various conditions. Several methods to label native DNA have been developed in the last two decades. Triple-helix-forming oligodeoxynucleotides and hairpin polyamides that bind DNA sequences specifically in the major and minor groove respectively were used as targeting devices for subsequent covalent labelling. In addition, enzyme-directed labelling approaches utilizing nicking endonucleases in combination with DNA polymerases or DNA methyltransferases have been employed. This review summarizes various techniques useful for functionalization of long native DNA.