One hundred-fold acceleration of DNA renaturation rates in solution

Solvents which accelerate DNA renaturation rates have been investigated. Addition of NaCl or LiCl to DNA in 2.4M Et₄NCl initially increases renaturation rates at 45°C and then leads to a loss of second-order behavior. The greatest accelerations are seen with LiCl and dilute DNA. Volume exclusion by dextran sulfate is the most effective method of accelerating DNA renaturation with concentrated DNA. Addition of dextran sulfate beyond 10–12% in 2.4M Et₄NCl fails to increase the acceleration beyond approximately 10-fold. Accelerations of 100-fold may be achieved with 35–40% dextran sulfate in 1M NaCl at 70°C. No other mixed solvent system was found to be more effective, although acceleration may be achieved in solvents containing formamide or other denaturants. The acceleration in 2M NaCl occurs without loss of the normal concentration and temperature dependence of DNA renaturation and is also independent of dextran sulfate concentration if sufficient dextran sulfate is used. Dextran sulfate may be selectively precipitated by use of 1M CsCl.     

Purification by ammonium sulfate precipitation of bacteriophage lambda gt11 DNA for restriction analysis of cloned cDNA inserts

A rapid and efficient method to purify lambda gt11 DNA is described. This technique involves precipitation of intact bacteriophage particles with ammonium sulfate, followed by phage lysis with sodium dodecyl sulfate, proteinase K, and alkaline treatment. The quality of DNA for subsequent restriction analysis, infectivity, subcloning, and radiolabeling is comparable to that isolated by cesium chloride banding or ion exchange chromatography. The yield of the phage DNA is, however, two to eight times higher than that obtained by other conventional methods of lambda gt11 purification. Furthermore the time required to process the bacteriophage lysate is approximately 2 h and therefore more rapid than other currently used methods.     

Identification of a protein bound to the termini of bacteriophage PRD1 DNA.

Lipid-containing bacteriophage PRD1 has a double-stranded DNA genome of about 14,500 nucleotide base pairs. The phage can infect Escherichia coli and Salmonella typhimurium as well as other gram-negative bacteria harboring an appropriate plasmid. [35S]methionine label is incorporated into the DNA band early in infection. The label remains associated with DNA through phenol extraction and boiling with sodium dodecyl sulfate. Nuclease treatment of the genome released a protein which migrated as an early phage-specific protein (P8). This protein is also necessary for phage DNA replication. By restriction enzyme analysis it was shown that protein was associated with the terminal restriction fragments. Extracts of infected cells catalyzed the labeling of protein P8 with [alpha-32P]dGTP.     

DNA ligase activity in crude extracts of fibroblasts and lymphocytes

DNA ligase activity was determined in crude cell extracts using a new assay which measures the retention of double stranded circular phage λ DNA on nitrocellulose filters, and allows accurate determinations of the enzyme activity with cell concentration corresponding to 0.1 μg of proteins. Using this assay, we show that the DNA ligase activity varies greatly among mammalian cell lines. The higher activity is found in actively growing fibroblasts where it is stimulated by dimethyl sulfate pretreatment of the cells, whereas the low activity measured in resting lymphocytes is not modified by dimethyl sulfate. The DNA ligase activity correlates with the cells sensitivity towards ionizing radiations.     

An efficient method for preparing high quality DNA from plant DNA libraries in lambda phage

An efficient method has been developed to improve preparation of phage particles by ammonium sulfate precipitation and to yield high quality DNA. The method, that has been used to screen plant DNA libraries constructed in vectors, is inexpensive, does not require purification of phage particles, and can be used from either plate stocks or liquid lysates. Up to 1100 g DNA was produced from 5 ml lysate obtained from agar plates.     

Coiled Rings of DNA Released from Cells Infected with Bacteriophages T7 or T4 or from Uninfected Escherichia coli

The replicating intracellular DNA of phage T7 was labeled at high specific activity with tritiated thymidine. The DNA of uninfected Escherichia coli was similarly labeled. Portions of cells which contained replicating phage T7 or E. coli DNA were lysed by a lysozyme, freeze-thaw, sodium lauryl sulfate procedure, and the DNA was spread on Millipore membranes for visualization by autoradiography. The DNA of phage T7 appeared to be highly concatenated reaching lengths of up to 721 mum. Much of the DNA of phage T7 and E. coli was retained in compact globular structures. In addition, orderly coiled rings of varying diameter up to about 43 mum were regularly observed. Similar coiled ring structures were also observed in autoradiographs of replicating phage T4 DNA which had been prepared in previous experiments. Worcel and Burgi (27) have presented evidence that E. coli chromosomes, when gently extracted from cells, are in a multilooped and superhelically twisted configuration. The coiled rings which we have observed may correspond to the relaxed, multilooped configurations which they find when the superhelical twists have been relieved by one or more nicks in each loop.     

Biochemical quantitation of PM2 phage DNA as a substrate for endonuclease assay

Bacteriophage PM2 has a closed circular form of double stranded DNA as a genome. This DNA from the phage is a useful source for nick-circle endonuclease assay in the fmol range. Due to difficulties in the maintenance of viral infectivity, storage conditions of the phage should be considered for the purification of PM2 DNA. The proper condition for a short-term storage of less than 2 months is to keep the PM2 phage at 4 degrees C; whereas the proper condition for a long-term storage of the PM2 phage for over 2 months is to keep it under liquid nitrogen in 7.5% glycerol. The optimal conditions for a high yield of phage progeny were also considered with the goal to achieve a successful PM2 DNA preparation. A MOI(Multiplicity Of Infection) of 0.03, in which the OD600 of the host bacteria was between 0.3 and 0.5, turned out to be optimal for the mass production of PM2 phage with a burst size of about 214. Considerations of PM2 genome size, and the concentrations and radiospecific activities of purified PM2 DNA, are required to measure the endonuclease activity in the fmol range. This study reports the proper quantitation of radioactivity and the yield of purified DNA based on these conditions.     

Induction of prophage SPO2 in Bacillus subtilis: isolation of excised prophage DNA as a covently closed circle.

Bacillus subtilis tryC2, thyA, thyB, lysogenic for the phage DNA polymerase negative mutant SPO2 susL244, was induced under conditions preventing phage and bacterial DNA synthesis. The biological activity of DNA from induced cells and from uninduced controls was assayed by transformation and transfection, respectively. About 50% of the phage DNA biological activity in DNA extracted from induced cells was resistant to exposure to pH 11.8 TO 11.9. This DNA was operationally defined as alkali-resistant phage DNA. Transforming bacterial DNA from uninduced or induced cells and transfecting DNA from uninduced cells were more than 95% inactivated after exposure to high pH. The alkali-resistant phage DNA was characterized by sucrose gradient centrifugation, by centrifugation in cesium chloride-propidium iodide, and by electron microscopy. It was found to consist of a majority of covalently closed circular DNA molecules. Length measurements of a few relaxed circular molecules indicate a molecular weight of these similar to that previously found for mature SPO2DNA. Attempts to isolate similar covalently closed circular phage DNA from induced bacteria lysogenic for SPO2 phage with a functional DNA polymerase gene were unsuccessful. The gene order in mature and prophage SPO2 was determined by rescue of single and double markers from the respective type of DNA. The data obtained show that prophage DNA is (genetically) permuted relative to mature DNA. The phage attachment site is suggested to be located between genes I and J.     

Specificity of staphylococcal phage and SaPI DNA packaging as revealed by integrase and terminase mutations

SaPI1 and SaPIbov1 are chromosomal pathogenicity islands in Staphylococcus aureus that carry tst and other superantigen genes. They are induced to excise and replicate by certain phages, are efficiently encapsidated in SaPI-specific small particles composed of phage virion proteins and are transferred at very high frequencies. In this study, we have analysed three SaPI genes that are important for the phage–SaPI interaction, int (integrase) terS (phage terminase small subunit homologue) and pif (phage interference function). SaPI1 int is required for SaPI excision, replication and packaging in a donor strain, and is required for integration in a recipient. A SaPI1 int mutant, following phage induction, produces small SaPI-specific capsids which are filled with partial phage genomes. SaPIbov1 DNA is efficiently packaged into full-sized phage heads as well as into SaPI-specific small ones, whereas SaPI1 DNA is found almost exclusively in the small capsids. TerS, however, determines DNA packaging specificity but not the choice of large versus small capsids. This choice is influenced by SaPIbov1 gene 12, which prevents phage DNA packaging into small capsids, and which is also primarily responsible for interference by SaPIbov1 with phage reproduction.     

Transfection of Escherichia coli Spheroplasts I. General Facilitation of Double-Stranded Deoxyribonucleic Acid Infectivity by Protamine Sulfate

The addition of 25 mug of protamine sulfate per ml to lysozyme-ethylenediamine-tetraacetic acid spheroplasts of Escherichia coli stimulates transfection not only for T1 phage deoxyribonucleic acid (DNA; Hotz and Mauser, 1969) but also for the following phage DNA species: lambda, 10,000-fold to an efficiency of 10(-3) infective centers per DNA molecule; phiX174 replicative form, 300-fold to an efficiency of 5 x 10(-2); fd replicative form, 300-fold to 10(-6); T7, 300-fold to 3 x 10(-7). Three native phage DNA species were not infective at all in the absence of protamine sulfate but were infective in the presence of protamine sulfate with the following efficiencies: T4, 10(-5); T5, 3 x 10(-6); and P22, 3 x 10(-9). The effect of protamine sulfate is specific for double-stranded DNA. The application of infectivity assays to the study of phage DNA replication, recombination, prophage integration, prophage excision, and interspecies transfection are discussed.     

Influence of antibodies against DNA on the renaturation of DNA.

The treatment of denatured T4 phage DNA with antiserum for the DNA of this phage, containing antibodies against glucosylated 5-hydroxymethylcytosine, decreases the ability of DNA for renaturation. The greatest inhibiting activity is possessed by antiserum for T4 phage DNA irradiated with UV light, which contains antibodies not only against glucosylated 5-hydroxymethylcytosine, but also against the usual nitrogen bases. Antiserum against E. coli DNA, containing antibodies to the usual nitrogen bases, in equal dilutions with the antisera indicated above, shows less inhibitory activity on the renaturation of T4 phage DNA.     

Interaction of DNA with DNA binding proteins. III. Infectivity of protein-complexed phage fd DNA in Escherichia coli spheroplasts.

Complex formation of circular, single-stranded phage fd DNA with Escherichia coli DNA binding protein HD or phage fd gene 5 protein keeps infection of E. coli spheroplasts at the level of free phage DNA, whereas complexes of this DNA with E. coli DNA unwinding protein show a strongly reduced efficiency of transfection. Displacement of the unwinding protein by HD protein or gene 5 protein also maintains the poor adsorption of the complexes to spheroplasts. Free E. coli DNA unwinding protein and residual amounts of this protein bound to the DNA may interfere with the adsorption and the uptake of the phage genome.     

Dextran sulfate sodium-induced ulcerative colitis leads to increased hematopoiesis and induces both local as well as systemic genotoxicity in mice

Ulcerative colitis is a chronic gastrointestinal disorder eliciting the risk of colorectal cancer, the third most common malignancy in humans. The present study was aimed to characterize dextran sulfate sodium-induced ulcerative colitis and to elucidate its influence on the bone marrow cell proliferation and the subsequent stimulation of the systemic genotoxicity in mice. Experimental colitis was induced in Swiss mice using 3% (w/v) dextran sulfate sodium in drinking water. The severity of colitis was assessed on the basis of clinical signs, colon length, oxidative stress parameters, various pro-inflammatory markers, histopathological evaluation and immunohistochemical staining of 8-oxo-7,8-dihydro-2'-deoxyguanosine in the colon of dextran sulfate sodium treated mice. Further, assessment of genotoxicity was carried out using alkaline and modified comet assays in the colon and lymphocytes and micronucleus assay in the peripheral blood of mice. For the evaluation of inflammation-induced cell proliferation in the bone marrow, proliferating cell nuclear antigen immunostaining was carried out in the bone marrow of mice. Dextran sulfate sodium induced severe colitis as evident from the elevated disease activity index, reduced colon length, increased oxidative stress, histological abnormalities and oxidative DNA damage in the colon of mice. Moreover, colitis-induced elevated prostaglandin-E2 level in the plasma of dextran sulfate sodium treated mice stimulated the cell proliferation in the bone marrow, which further triggered colitis-induced DNA damage in the peripheral blood of mice.     

Frozen and thawed bacteria as recipients of isolated phages and plasmid DNA]

Bacteria subjected to freezing and thawing are effective recipients of phage 1 phi 7 DNA, lambda DNA, and plasmid pMB9 DNA. The effectiveness of transfection and plasmid transformation of frozen and thawed bacteria is determined by the joint action of 3 factors: 1) the conditions of freezing and thawing of a recipient and DNA mixture with freezing carried out at a rate of 400 degrees C/min to--76 degrees C or--196 degrees C and with subsequent thawing at 42 degrees C; 2) a transitory character of recipient competence preservation in respect of phage and plasmid DNA; 3) the degree of recipient cryolability depending, in particular, on the genotype of the recipient. The maximum indices of transfection effectiveness and plasmid transformation have been obtained with bacterial concentration equal to 1--5 X 10(9) cells/ml, phage and plasmid DNA concentration equal to 0.05--0.5 mcg/ml in the reaction mixture containing 0.5--1% of Spofa bactopeptone, PH 7.4--7.6.     

A bacteriophage lambda DNA purification procedure suitable for the analysis of DNA from either large or multiple small lysates

A method for the efficient preparation of high quality bacteriophage lambda DNA from cleared lysates is described. Advantages of the method include high DNA yields (typically around 0.8 micrograms of DNA/1 ml of cleared lysate), speed of processing (approximately 2 h from lysate to DNA), economy, and the absence of any requirement for phenol or chloroform extractions. The technique involves the concentration of phage particles by standard polyethylene glycol precipitation followed by enzymatic treatment to remove contaminating RNA and DNA. Phage particles are then lysed with sodium dodecyl sulfate (SDS) at elevated pH and temperature. Contaminating protein/SDS complexes are rendered insoluble by the addition of potassium acetate and removed by centrifugation. The quality of the resultant DNA is comparable to that prepared by cesium chloride banding for all standard molecular biological purposes providing that spermidine is included in all restriction endonucleases digestions.     

Internal motion of DNA in bacteriophages

We have investigated internal motion of DNA in bacteriophages by measuring fluorescence anisotropy decays of intercalated ethidium. The results showed large suppression of the internal motion of the inner DNA; the interhelix interaction of the DNA in the phage head is considered to enhance the effective viscosity of the DNA rod and to restrict the angle of the internal motion. Considering that the observed internal motion arises mainly from torsional motion of the DNA, we have calculated the movable angles of the torsional motion (the standard deviation of the torsional motion) of the DNA in the phage heads. The magnitude of the calculated movable angles indicates the extent of suppression of the DNA movement in the phage head; in lambda wild type phage, the DNA is packed most rigidly in the head and the motion is found to be restricted most severely. In a deletion mutant of lambda phage, whose inner DNA content is deficient by 17.6%, steric hindrance from the interhelix DNA interaction is decreased, and the DNA can move more easily. In T4 wild type phage, although the extent of condensation of the inner DNA is the same as that in lambda wild type phage, the DNA was fairly mobile. The presence of glucosylated hydroxymethylcytosine is suggested to influence the rigidity of the inner DNA or packaging mode of the DNA in the T4 head.     

噬菌体DNA的快速抽提

介绍一种噬菌体DNA的快速抽提方法.用聚乙二醇沉淀噬菌体颗粒,然后经DEAE纤维素纯化处理和酚抽提.与传统的噬菌体DNA纯化方法相比,改进后的方法方便、快速、经济,可获得高纯度的噬菌体DNA.     

Folded, concatenated genomes as replication intermediates of bacteriophage T7 DNA.

A complex form of bacteriophage T7 DNA, containing up to several hundred phage equivalents of DNA, arises during replication of T7. The complex was stable to treatment with ionic detergent, Pronase, and phenol. The complex form normally exists for only a short time, corresponding to the phase of rapid T7 DNA synthesis. It is then converted to shorter molecules, both concatemers and unit-size DNA. The complex was stable up to the temperature of denaturation of the bihelix. It consisted of a series of loops amanating from a dense central core, as shownby electron microscopy. The complex form is similar to the relaxed Escherichia coli folded chromosome ('nucleoid'). The loops contained an average of 0.7 to 0.8 phage equivalent of DNA. During infection by phage with an amber mutation in gene 3 (endonuclease), formation of the complex occurred normally, but its maturation to unit-size DNA blocked. Before treatment with phenol, the complex contained short fragments of newly replicated DNA. These were released as single-stranded pieces during phenol treatment. A pathway for T7 DNA replication is indicated in which the flow of material is from unit-size DNA to linear concatemers to the complex form, and then back to unit-size DNA by way of linear concatemers.     

Circular and branched circular concatenates as possible intermediates in bacteriophage T4 DNA replication

Escherichia coli cultures were infected with bacteriophage T4. [³H]thymidine was added at the time of infection to label newly-synthesized phage DNA. The infected cells were lysed and the phage chromosomes spread out on Millipore membranes for autoradiographic visualization. Circular forms varying in circumference from one to 21 times the length of a single mature phage chromosome were observed. Linear branches were often appended to these circles, and circles with one, two and four branches were observed. In some cases these branches were much longer than the circumference of the circle to which they were connected. Linear stretches of DNA several-fold longer than the mature phage chromosome were also common and these frequently had one or more branches. The various forms observed are discussed with respect to the rolling circle mechanism of DNA replication.     

Purification of a DNA polymerase-DNA primase complex from calf thymus glands

An immunoabsorbent column, prepared by covalently linking mouse monoclonal anti-calf thymus DNA polymerase-alpha to Protein A-Sepharose, was used as the primary purification step for rapid isolation of DNA polymerase-alpha from calf thymus-gland extracts. In a 4-step procedure consisting of the removal of nucleic acids by protamine sulfate precipitation, chromatography on the immunoabsorbent column, desalting on Sephadex G-50, and removal of bovine immunoglobulins on Protein A-Sepharose, DNA polymerase-alpha activity was purified about 5000-fold from the crude extract with greater than 40% recovery of total enzyme activity. The antibody column-purified DNA polymerase-alpha fraction contains a DNA primase activity that is efficient in replication of single-stranded DNA and poly(dT) when rNTPs are included in the replication reactions. Synthesis by calf thymus DNA polymerase-primase is totally dependent on added template. Complete replication of circular single-stranded phage DNA is achieved with polymerase-primase producing a nicked circular DNA containing oligoribonucleotide primer in the final product. Primers synthesized with single-stranded phage DNA as template were up to 10 nucleotides long when dNTPs were omitted from the reaction and 8 or less nucleotides long when dNTPs were present. Primers synthesized using poly(dT) consisted of three populations when dATP was absent from the reaction, averaging 20 nucleotides, 10 nucleotides, and 3-4 nucleotides. The 20-nucleotide population was not found when dATP was included in the reaction.