Deoxyuridine residues in DNA of thymine-requiring Bacillus subtilis strains with defective N-glycosidase activity for uracil-containing DNA.

DNA extracted from exponentially growing cells of thymine-requiring Bacillus subtilis strains with defective N-glycosidase activity for deoxyuridine residues in DNA was subjected to the action of N-glycosidase in vitro and analyzed by sedimentation in alkaline sucrose gradients. The sites attacked by N-glycosidase occurred once per 6 X 10(6) to 7 X 10(6) daltons of DNA from cells cultured in the presence of growth-supporting concentrations of thymine. The number of N-glycosidase-susceptible sites increased when the thymine concentration in the medium was lowered. Parallel to this observation, the N-glycosidase-defective mutant cells were less apt to show the detrimental effect due to thymine depletion than were the parental cells. Such sites were not detected in DNA from cells with a normal N-glycosidase activity or with a "wild type" capacity for thymidylate synthesis. The results are interpreted to mean that cells defective for thymidylate synthesis incorporate dUTP in place of TTP in DNA and that the deoxyuridine residues, once incorporated, remain in the DNA in the absence of N-glycosidase activity.     

Enzymatic degradation of uracil-containing DNA. II. Evidence for N-glycosidase and nuclease activities in unfractionated extracts of Bacillus subtilis.

Further studies have confirmed our earlier observations that in the presence of EDTA, degradation of phage PBS2 [3H]uracil-labeled DNA is effected by an N-glycosidase activity in extracts of Bacillus subtilis that removes free uracil from DNA. In addition, such extracts contain a nuclease activity that attacks PBS2 DNA in the presence of CaCl2. The nuclease activity is not observed under conditions that inactivate N-glycosidase activity but does attack DNA that has been preincubated to remove uracil by N-glycosidase action. We therefore postulate that the nuclease requires N-glycosidase action to generate substrate for its activity, i.e., the nuclease appears to attack depyrimidinated sites rather than uracil sites in phage PBS2 DNA.     

Degradation of Escherichia coli DNA synthesized after ultraviolet irradiation in the absence of repair

DNA degradation in Escherichia coli uvrA recA bacteria exposed to a low dose (0.07 J/m2) of ultraviolet radiation was studied. A considerable amount of the newly-synthesized DNA, which contains gaps opposite pyrimidine dimers, is broken down. In contrast, parental, dimer-containing DNA is resistant to radiation-induced degradation.     

DNA degradation in an amber mutant of Escherichia coli K12 affecting DNA ligase and viability

Isolation of an amber mutant lig-321 (or dnaL321) if Escherichia coli K12 with a defect in DNA ligase activity was previously reported (Nagata & Horiuchi, 1974). This was the first demonstration that, in E. coli, conditionally lethal nonsense mutants can be isolated selectively. Unlike the hitherto available E. coli K12 DNA ligase-deficient (lig) mutants, the DNA of this mutant is degraded under lethal conditions. This paper describes its further characterization. The DNA degradation was found to be an energy-requiring process, in which endonuclease I did not seem to participate. Kinetic analyses of prelabeled DNA indicated that the parental strands were degraded. The sedimentation profile of prelabeled DNA in an alkaline sucrose gradient showed that the extensive degradation was preceded by a step in which the parental strands were broken into relatively large pieces. At least in the early phase of degradation, which we examined by alkaline sucrose gradient centrifugation of pulse-labeled DNA, synthesis of discontinuous daughter chains (Okazaki fragments, Okazaki et al., 1968) was confirmed. Joining of the nascent chains, however, was completely inhibited. Genetic analyses revealed that the mutant allele is recessive to the wild type. This agrees with in vitro studies in which the mutant crude extract was found not to inhibit DNA ligase activity of the wild type extract. These and other properties of the lig-321 mutant were compared with the other DNA ligase-deficient mutants of E. coli. The role of this enzyme in DNA replication, repair and recombination is discussed.     

Characterization of human enzymes specific for damaged DNA: resolution of endonuclease for irradiated DNA from an apparent N-glycosidase active on alkylated DNA.

An endonuclease partially purified from human lymphoblasts, and active against ultraviolet-irradiated DNA, was found to act additionally on DNA damaged by either x-radiation or methylmethanesulfonate. To determine if these activities were truly endonucleolytic, the reaction products were analyzed under conditions that prevented conversion of apurinic or apyrimidinic sites to single-strand breaks. With either ultraviolet- or x-irradiated DNA, strand breakage remained maximal, hence confirming the endonucleolytic character of the enzyme. By contrast, with DNA alkylated with methylmethanesulfonate, strand breakage was sharply reduced. Additional experiments indicated that the activity for alkylated DNA induces strand breaks only in concert with a purified endonuclease specific for apurinic sites, suggesting that it is an N-glycosidase that depurinates alkylated bases. This enzyme was separated from the endonuclease specific for irradiated DNA, by chromatography on DNA-agarose.     

Recombinational-type transfer of viral DNA during bacteriophage 2C replication in Bacillus subtilis.

The Bacillus subtilis phage 2C contains one molecule of double-stranded DNA of about 100 x 10(6) daltons in which thymine is replaced by hydroxymethyluracil; the two strands have different buoyant densities. Parental DNA, labeled with either [3H]uracil of [32P]phosphate, was quite effectively transferred to offspring phage, and the efficiency of transfer was the same for the two strands. Labeled nucleotide compositions of the H and L strands from parental and progeny virions were very close. These data exclude a degradation of the infecting DNA and reutilization of nucleotides. Upon infection of light unlabeled cells with heavy radioactive viruses, no DNA with either heavy or hybrid density was extracted from offspring phage. Instead, an heterogeneous population of DNA molecules of densities ranging from that of almost hybrid to that of fully light species was obtained. Shear degradation of such progeny DNA to fragments of decreasing molecular weight produced a progressive shift to the density of hybrid molecules. Denaturation of sheared DNA segments caused the appearance of labeled and heavy single-stranded segments. These findings indicate that 2C DNA replicates semiconservatively and then undergoes extensive genetic recombination with newly formed viral DNA molecules within the vegatative pool, thus mimicking a dispersive transfer of the infecting viral genome. The pieces of transferred parental DNA have an average size of 10 x 10(6) daltons.     

N-Glycosidase activity in extracts of Bacillus subtilis and its inhibition after infection with bacteriophage PBS2.

We have detected in crude extracts of Bacillus subtilis an N-glycosidase activity which catalyzes the release of free uracil from DNA of the subtilis phage PBS2 labeled with [3H]uridine. This DNA contains deoxyuridine instead of thymidine. The enzyme is active in the presence of 1.0 mM EDTA and under these conditions Escherichia coli or T7 DNA labeled with [3H]thymidine is not degraded to labeled acid-soluble products. The activity resembles an N-glycosidase from E. coli which releases free uracil from DNA containing deaminated cytosine residues. Both enzymes in crude extracts are active in the presence of EDTA, do not require dialyzable co-factors, and have the same pH optimum. They differ in that the enzyme from E. coli is more sensitive to heat, sulfhydryl reagents, and salt. The enzyme from B. subtilis is inactive on DNA containing 5-bromouracil or hydroxymethyluracil. Extracts of PBS2-infected B. subtilis lose the N-glycosidase activity within 4 min after infection and contain a factor that inhibits the N-glycosidase activity within 4 min after infection and contain a factor that inhibits the N-glycosidase activity in extracts of uninfected cells in vitro.     

A DNA binding protein from human placenta specific for ultraviolet damaged DNA.

A DNA-binding protein specific for ultraviolet irradiated DNA has been purified extensively from human placenta. The binding preparation is free of exonuclease, polymerase, endonuclease, and N-glycosidase activity. The binding activity is salt dependent and is specific for double-stranded irradiated DNA. DNA from which the pyrimidine dimers have been monomerized by the action of photolyase (photoreactivating enzyme) remains an effective substrate for the binding protein, suggesting that the protein recognizes photoproducts other than pyrimidine dimers. This is supported by the finding that DNA irradiated under conditions which introduce only pyrimidine dimers is not a substrate for the binding protein. Examination of three of the xeroderma pigmentosum complementation groups has revealed no deficiency in this binding activity.     

Degradation of the viral strand of phiX174 parental replicative-form DNA in a rep- host.

A progressive degradation of the parental viral strand label is observed upon infection of a Rep- mutant of Escherichia coli by 32P-labeled phiX174. Very little parental label remains in the RF (replicative form) by 47 min after infection. Concomitant with this degradation, replicative intermediates are formed which sediment at 21s, the rate of RF I (supercoiled-closed circular DNA), in a neutral sucrose gradient but which denature and sediment in alkaline gradients as single strands of unit size and larger. These denaturable 21s replicative intermediates have been shown previously to be RF molecules containing an elongated viral strand. Addition of chloramphenicol at 7 min after infection at 30 mug/ml, a concentration sufficient to block RF leads to SS (single strand) synthesis but not RF leads to RF synthesis in a wild-type host cell, reduced the amount of viral strand elongation but did not prevent viral strand degradation. The addition of chloramphenicol at 150 mug/ml at 7 min after infection totally prevents both the degradation of the parental label and the formation of the replicative intermediates with elongated tails. We infer that degradation of the viral strand requires the gene A-mediated nicking of the viral strand but not the concomitant elongation of the viral strand.     

Host specificity of DNA produced byEscherichia coli

Summary Phage , whose DNA was physically labelled with density markers²H and¹⁵N and biologically labelled with K-host specificity, was submitted to one growth cycle on a restriction deficient (r ^–) strain ofE. coli B exerting normally its modification function (m _B ⁺ ). All progeny phages, including those with nonreplicated, fully conserved parental DNA molecules, acquired the B-specificity in this passage, independently of DNA replication and of the presence of the K-specificity on the DNA. Phages with parental DNA had preserved the parental K-specificity. However, about half of the phages carrying a halfheavy DNA molecule (corresponding presumably to a semiconserved double helix) did only plate on B and onr ^– mutants, but not on K12. Experimental evidence is presented, that DNA degradation is the cause of this lack of growth in K12, while in infections initiated by the other half of the hybrids both strands (that with K and B specificity and that with only B specificity) are preserved and are recovered in the progeny with equal chance.     

Mechanism of replication of phichi174 single-stranded DNA. V. Dispersive and conservative transfer of parental DNA into progeny DNA

We have studied parent-to-progeny transfer of bacteriophage φX174 DNA during infection of Escherichia coli with isotopically-labeled, lysis-defective phage. After 60 minutes of infection at low multiplicities, 25 to 30% of the input viral DNA is transferred from the double-stranded replicative form into progeny phage; another 10 to 20% is transferred into the progeny single-stranded DNA pool. Thus, at times beyond the normal time of lysis, about 35 to 50% of the parental deoxyribonucleotides are found in progeny single-stranded DNA. Three quarters of the parental label found in the progeny phage is transferred by a dispersive process and one-quarter is transferred by a conservative, or non-dispersive, process such that the parental strand remains intact. At high multiplicities of infection the fraction of parental label transferred decreases.     

Delayed degradation of parental macronuclear DNA in programmed nuclear death of Paramecium caudatum

In the ciliated protozoan Paramecium caudatum, a parental macronucleus that is fragmented into some 40-50 pieces during conjugation does not degenerate immediately, but persists until the eighth cell cycle after conjugation. Here we demonstrate that the initiation of the parental macronuclear degeneration occurs at about the fifth cell cycle. The size of parental macronuclear fragments continued to increase between the first and fourth cell cycle, but gradually decreased thereafter. By contrast, a new macronucleus grew and reached a maximum size by the fourth cell cycle, suggesting that the new macronucleus matured by that stage. Southern blot analysis revealed that parental macronuclear DNA was degraded at about the fifth cell cycle. The degradation was supported by acridine orange staining, indicating degeneration of the macronuclear fragments. Prior to the degradation, the fragments once attached to the new macronucleus were subsequently liberated from it. These observations lead us to conclude that once a new macronucleus has been fully formed by the fourth cell cycle, the parental macronuclear fragments are destined to degenerate, probably through direction by new macronucleus. Considering the long persistence of the parental macronucleus during the early cell cycles after conjugation, the macronuclear fragments might function in the maturation of the imperfect new macronucleus. Two possible functions, a gene dosage compensation and adjustment of ploidy level, are discussed.     

Dependence of DNA dark repair on protein synthesis in Escherichia coli.

Summary We investigated the influence of aminoacidless treatments applied prior and after UV irradiation on survival, dimer excision, postirradiation DNA degradation, DNA synthesis and sedimentation profiles of parental DNA ofE. coli B/r Hcr⁺ cells. In dependence on the treatment applied, the fluence 50 J/m² yielded distinctly different fractions of survivors within 0,03–85%. In all cases dimers were completely excised. The rate of DNA degradation was similar during a 30–40 min period after UV during which the bulk of dimers was excised. Degradation ceased, however, earlier in the prestarved cells than in exponentially growing ones; it was prolonged by aminoacidless postincubation. Sedimentation profiles of parental DNA did not differ during the whole period of dimer excision. In cells DNA synthesis was not restored for several hours after addition of amino acids. In cells addition of amino acids resulted in a fast resumption of DNA synthesis. We conclude that removal of dimers and repair of gaps were similar in all cases. We believe that aminoacidless treatments influence production and repair of damage to the sites of DNA replication. The treatment appears to prevent this damage when applied before UV irradiation, but interferes with its restoration when applied after UV irradiation. Consequently, the former treatment increases survival of cells while the latter produces an opposite effects.     

Degradation of intracellular DNA in KB cells infected with cyt mutants of human adenovirus type 12.

A group of mutants (cyt mutants) with much reduced oncogenicity was isolated from the highly oncogenic human adenovirus type 12 (Takemori et al., Virology 36: 575-586, 1968). These mutants induce extensive cellular destruction during lytic infection of human cells and produce low yields of virions. We report here that human KB cells infected with cyt mutants synthesized a reduced amount of viral DNA as compared with cells infected with the parental virus. Furthermore, the newly synthesized viral and cellular DNAs were extensively degraded in mutant-infected cells. Viral DNA was first synthesized as complete genome size, and most of it was degraded to subgenomic size within 6 h after synthesis. This virus-induced DNA degradation function, as well as the low yield of virions, was prevented by co-infection with the parental virus.     

Competence-Independent Activity of Pneumococcal Enda Mediates Degradation of Extracellular DNA and Nets and Is Important for Virulence

Membrane surface localized endonuclease EndA of the pulmonary pathogen Streptococcus pneumoniae (pneumococcus) is required for both genetic transformation and virulence. Pneumococcus expresses EndA during growth. However, it has been reported that EndA has no access to external DNA when pneumococcal cells are not competent for genetic transformation, and thus, unable to degrade extracellular DNA. Here, by using both biochemical and genetic methods, we demonstrate the existence of EndA-mediated nucleolytic activity independent of the competence state of pneumococcal cells. Pneumococcal mutants that are genetically deficient in competence development and genetic transformation have extracellular nuclease activity comparable to their parental wild type, including their ability to degrade neutrophil extracellular traps (NETs). The autolysis deficient ΔlytA mutant and its isogenic choline-treated parental wild-type strain D39 degrade extracellular DNA readily, suggesting that partial cell autolysis is not required for DNA degradation. We show that EndA molecules are secreted into the culture medium during the growth of pneumococcal cells, and contribute substantially to competence-independent nucleolytic activity. The competence-independent activity of EndA is responsible for the rapid degradation of DNA and NETs, and is required for the full virulence of Streptococcus pneumoniae during lung infection.     

Apoptotic nuclear morphological change without DNA fragmentation.

Apoptosis is characterized morphologically by condensation and fragmentation of nuclei and cells and biochemically by fragmentation of chromosomal DNA into nucleosomal units [1]. CAD, also known as CPAN or DFF-40, is a DNase that can be activated by caspases [2] [3] [4] [5] [6]. CAD is complexed with its inhibitor, ICAD, in growing, non-apoptotic cells [2] [7]. Caspases that are activated by apoptotic stimuli [8] cleave ICAD. CAD, thus released from ICAD, digests chromosomal DNA into nucleosomal units [2] [3]. Here, we examine whether nuclear morphological changes induced by apoptotic stimuli are caused by the degradation of chromosomal DNA. Human T-cell lymphoma Jurkat cells, as well as their transformants expressing caspase-resistant ICAD, were treated with staurosporine. The chromosomal DNA in Jurkat cells underwent fragmentation into nucleosomal units, which was preceded by large-scale chromatin fragmentation (50-200 kb). The chromosomal DNA in cells expressing caspase-resistant ICAD remained intact after treatment with staurosporine but their chromatin condensed as found in parental Jurkat cells. These results indicate that large-scale chromatin fragmentation and nucleosomal DNA fragmentation are caused by an ICAD-inhibitable DNase, most probably CAD, whereas chromatin condensation during apoptosis is controlled, at least in part, independently from the degradation of chromosomal DNA.     

Adenoviral protein VII packages intracellular viral DNA throughout the early phase of infection.

The proteins associated with parental, adenoviral DNA in productively-infected HeLa cells have been examined both directly and indirectly. HeLa cells infected with 32P-labelled Ad2 were irradiated with u.v. light at various points in the infectious cycle. Following degradation of the DNA, nuclear proteins carrying cross-linked nucleotides, or oligonucleotides, were distinguished from virion phosphoproteins by the resistance of their 32P radioactivity to 1 M NaOH. The major core protein of the virion, protein VII, was found to be associated with viral DNA throughout infection, even when cells were infected at a multiplicity of 0.14. Micrococcal nuclease digestion of intranuclear viral DNA 4 h after infection liberated two nucleoprotein particles containing viral DNA, neither of which co-migrated with HeLa cell mononucleosomes. These results indicate that core protein VII remains associated with parental adenoviral DNA during productive infections. The observation that protein VII can be cross-linked to DNA in cells infected at very low multiplicity, together with the results of a comparison of proteins cross-linkable to viral DNA in cells infected by wild-type virus and a non-infectious mutant containing the precursor to protein VII, suggest that nucleoproteins comprising viral DNA and protein VII must be the templates for expression of pre-early and early viral genes.     

Role of Gene 52 in Bacteriophage T4 DNA Synthesis

In an attempt to elucidate the mechanism of delayed DNA synthesis in phage T4, Escherichia coli B cells were infected with H17 (an amber mutant defective in gene 52 possessing a "DNA-delay" phenotype). The fate of (14)C-labeled H17 parental DNA after infection was followed: we could show that this DNA sediments more slowly in neutral sucrose than wild-type DNA 3 min postinfection. In pulse-chase experiments progeny DNA was found to undergo detachment from the membrane at 12 min postinfection. Reattachment to the membrane was found to be related to an increase in rate of DNA synthesis. A nucleolytic activity that is absent from cells infected by wild-type phage and from uninfected cells could be detected in extracts prepared from mutant-infected cells. In contrast, degradation of host DNA was found to be less extensive in am H17 compared with wild-type infected cells. Addition of chloramphenicol to mutant-infected cells 10 min postinfection inhibited the appearance of a nuclease activity on one hand and suppressed the "DNA-delay" phenotype on the other hand. We conclude that the gene 52 product controls the activity of a nuclease in infected cells whose main function may be specific strand nicking in association with DNA replication. This gene product might directly attack both E. coli and phage T4 DNA, or indirectly determine their sensitivity to degradation by another nuclease.     

Partial purification and characterization of a uracil DNA N-glycosidase from Bacillus subtilis.

A uracil specific DNA N-glycosidase activity has been partially purified from crude extracts of Bacillus subtilis. The enzyme has a molecular weight of approximately 24 000 with no subunit structure. It has no requirement for any known cofactors but is inhibited in the presence of Co2+, Fe2+, or Zn2+. The enzyme is specific for uracil in single- and double-stranded deoxyribonucleopolymers and does not release free uracil from RNA or from poly(rU):poly(dA). In addition, neither Udr, dUMP, nor dUTP is recognized as substrate. The enzyme will attack small poly(dU) oligomers but the minimum size recognized as substrate is (pU)4. This enzyme may have a role in the repair (by base excision) or uracil in DNA arising either by incorporation during DNA synthesis or by deamination of cytosine in DNA.