Cleavage of stem-and-loop structure DNA by bleomycin. Reaction on the bacteriophage G4 origin of complementary strand synthesis

The cleavage by bleomycin-Fe(II) complex in the presence of dithiothreitol of 3'-or 5'-end-labeled DNA from the region of the bacteriophage G4 origin of complementary strand synthesis was investigated by using the DNA-sequencing technique. Bleomycin cleaved a single-stranded DNA substrate preferentially at inverted repeat sequences, which potentially form stem-and-loop structures, while it cleaved double-stranded DNA substrates with different specificity. The results support the formation of three adjoining stem-and-loop structures in the region of the phage G4 origin of complementary strand synthesis under the low-salt conditions used and suggest a difference in the form of the double helix between the stem and the double-stranded DNA fragment. Bleomycin appears to be a useful reagent for searching stem-and-loop structures. The results may also contribute to the understanding of the mode of action of bleomycin as an antitumor antibiotic.     

In vitro initiation of bacteriophage phi 29 and M2 DNA replication: genes required for formation of a complex between the terminal protein and 5'dAMP

Cell-free extracts prepared from phi 29 and M2-infected Bacillus subtilis cells catalyse the formation of complexes between terminal protein and [alpha-32P]-dAMP in the presence of [alpha-32P]-dATP, MgCl2, ATP, and phage DNA with terminal protein covalently linked at both the 5'ends. The complex formation does not take place when proteinase K-treated DNA is added or when uninfected extract is used. The phi 29 complex thus formed is smaller than the M2 complex, primarily due to the different molecular weights of the respective terminal proteins. Extracts prepared from cells infected with suppressor-sensitive mutants of genes 2 or 3 of phi 29 or genes G or E of M2 do not support complex formation. When the pair of extracts of phi 29 or M2-infected cells are mixed, however, formation of the complex takes place as a result of in vitro complementation. These results indicate that the complex formation observed in vitro reflects in vivo initiation of phage DNA replication. The product of gene 2 of phi 29 may be the enzyme that catalyses formation of the complex.     

Interactions of the DNA polymerase and gene 4 protein of bacteriophage T7. Protein-protein and protein-DNA interactions involved in RNA-primed DNA synthesis

Three proteins catalyze RNA-primed DNA synthesis on the lagging strand side of the replication fork of bacteriophage T7. Oligoribonucleotides are synthesized by T7 gene 4 protein, which also provides helicase activity. DNA synthesis is catalyzed by gene 5 protein of the phage, and processivity of DNA synthesis is conferred by Escherichia coli thioredoxin, a protein that is tightly associated with gene 5 protein. T7 DNA polymerase and gene 4 protein associate to form a complex that can be isolated by filtration through a molecular sieve. The complex is stable in 50 mM NaCl but is dissociated by 100 mM NaCl, a salt concentration that does not inhibit RNA-primed DNA synthesis. T7 DNA polymerase forms a stable complex with single-stranded M13 DNA at 50 mM NaCl as measured by gel filtration, and this complex requires 200 mM NaCl for dissociation, a salt concentration that inhibits RNA-primed DNA synthesis. Gene 4 protein alone does not bind to single-stranded DNA. In the presence of MgCl2 and dTTP or beta, gamma-methylene dTTP, a gene 4 protein-M13 DNA complex that is stable at 200 mM NaCl is formed. The affinity of DNA polymerase for both gene 4 protein and single-stranded DNA leads to the formation of a gene 4 protein-DNA polymerase-M13 DNA complex even in the absence of nucleoside triphosphates. However, the binding of each protein to DNA plays an important role in mediating the interaction of the proteins with each other. High concentrations of single-stranded DNA inhibit RNA-primed DNA synthesis by diluting the amount of proteins bound to each template and reducing the frequency of protein-protein interactions. Preincubation of gene 4 protein, DNA polymerase, and M13 DNA in the presence of dTTP forms protein-DNA complexes that most efficiently catalyze RNA-primed DNA synthesis in the presence of excess single-stranded competitor DNA.     

Maturation of bacteriophage 9NA DNA is influenced by the fatty acid composition of the host cell membrane

The fatty acid composition of the membrane of the conditional auxotroph fabB2 can be altered by allowing the cells to grow at non-permissive temperature (37°C) in the presence of a cis-unsaturated fatty acid. The phage 9NA, a virulent phage ofSalmonella typhimurium, can not multiply in fabB2. Synthesis and maturation of the phage DNA are differentially affected by variation in the fatty acid composition of the cell membrane. The replicating DNA associates with the membrane complex, the site of DNA synthesis. The association is comparatively weak in oleic, claidic, palmitoleic, palmitelaidic and linolelaidic acid enriched cells. When the cells are grown in the presence of palmitoleic acid, a large pool of concatemeric phage DNA accumulates in the cytoplasm within 10 min of infection. The conversion of concatemeric DNA to monomeric one i.e., mature phage length DNA, is inhibited in such cells. The presence of concatemeric DNA can be visualized by electron microscope. Such a situation is not observed when the cells are grown in media supplemented with other types of unsaturated fatty acids. The mechanism by which the host cell membrane lipid controls phage development is yet to be worked out.     

Specific recognition of parental terminal protein by DNA polymerase for initiation of protein-primed DNA replication

The linear genome of Bacillus subtilis phage phi29 has a protein covalently linked to the 5' ends, called parental terminal protein (TP), and is replicated using a free TP as primer. The initiation of phage phi29 DNA replication requires the formation of a DNA polymerase/TP complex that recognizes the replication origins located at the genome ends. The DNA polymerase catalyzes the formation of the initiation complex TP-dAMP, and elongation proceeds coupled to strand displacement. The same mechanism is used by the related phage Nf. However, DNA polymerase and TP from phi29 do not initiate the replication of Nf TP-DNA. To address the question of the specificity of origin recognition, we took advantage of the initiation reaction enhancement in the presence of Mn(2+), allowing us to detect initiation activity in heterologous systems in which DNA polymerase, TP, and template TP-DNA are not from the same phage. Initiation was selectively stimulated when DNA polymerase and TP-DNA were from the same phage, strongly suggesting that specific recognition of origins is brought through an interaction between DNA polymerase and parental TP.     

Overexpression, purification, and characterization of Escherichia coli bacteriophage PRD1 DNA polymerase. In vitro synthesis of full-length PRD1 DNA with purified proteins.

The bacteriophage PRD1 DNA polymerase gene (gene I) has been cloned into the expression vector pPLH101 under the control of the lambda pL promoter. Tailoring of an efficient ribosome binding site in front of the gene by polymerase chain reaction led to a high level heat-inducible expression of the corresponding gene product (P1) in Escherichia coli cells. Expression was confirmed in vivo by complementation of phage PRD1 DNA polymerase gene mutants and in vitro by formation of the genome terminal protein P8-dGMP replication initiation complex. Expressed PRD1 DNA polymerase was purified to apparent homogeneity in an active form. DNA polymerase, 3'-5'-exonuclease, and P8-dGMP replication initiation complex formation activities cosedimented in glycerol gradient with a protein of 65 kDa, the size expected for PRD1 DNA polymerase. The DNA polymerase was active on DNase I-activated calf thymus DNA, poly(dA).oligo(dT) and poly(dA-dT) primer/templates as well as on native phage PRD1 genome. The 3'-5'-exonuclease activity was specific for single-stranded DNA and released mononucleotides. No 5'-3'-exonuclease activity was detected. The inhibitor/activator spectrum of the PRD1 DNA polymerase was also studied. An in vitro replication system with purified components for bacteriophage PRD1 was established. Formation of the P8-dGMP replication initiation complex was a prerequisite for phage DNA replication, which proceeded from the initiation complex and yielded genome length replication products.     

Cleavage and circularization of single-stranded DNA: a novel enzymatic activity of phi X174 A* protein.

Purified phi X gene A* protein cleaves phi X single stranded DNA. The cleavage appears to be stoichiometric, whereby a gene A* protein molecule cleaves a phosphodiester bond and binds to the DNA fragment. The size of the cleavage product was inversely proportional to the ratio of A* protein to DNA in the reaction mixture. The cleavage of the DNA resulted in the formation of an A* protein - ssDNA complex identified on SDS-polyacrylamide gels and by banding in CsCl. An A* protein-ssDNA complex was isolated by gel filtration and shown to be active in a ligating reaction in which the two ends of the DNA fragment were joined to form a covalently closed circle. The joining reaction required Mg++ ions and was accompanied by the release of the protein from the DNA.     

Interaction of gene 5 protein of phage f1 with single and double-stranded DNA and polynucleotides

The fluorescence method was used to reveal some differences in the interaction of gene 5 protein of phage f1 with single- and double-stranded polynucleotides (DNA). The binding with the duplexes is non-cooperative and the Kapp is twice lower than that for the cooperative formation of the complex with single-stranded structures. In the complex with a double-stranded polynucleotide (DNA) the protein cover 3 nucleotide pairs. The complex dissociates with a lower concentration of salt and the contribution of the energy of nonelectrostatic interactions to the total energy of complex formation for it is lower than for the complex with single-stranded DNA. In the complex of protein with single-stranded structure the fluorescence of the tyrosine (Tyr) residues is quenched to a greater degree and their accessibility to the external quencher is lower than that of the complex with double-stranded polynucleotides (DNA). The suggestion is made that in destabilization of nucleic double helices by gene 5 protein of phage f1, a great role belongs to Tyr residues because of their high affinity to single-stranded structures and because of their different localization in the complexes with single- and double-stranded polynucleotides.     

The influence of host DNA replication on the formation of infectious and transducing Mu-particles

Summary We have investigated the influence of bacterial DNA replication on the formation of infectious and transducing Mu-particles.The data obtained agree with the previous findings that growth of phage Mu is independent of the host dnaA gene product (Toussaint and Faelen 1974), but requires bacterial replication forks (Fitts and Taylor 1980). The replication of transducting DNA during phage development (Teifel and Schmieger 1979) is controlled by the host and is not a precondition for its packaging. Packaging of transducing DNA does not require a nearby Mu genome.     

Late gene function in bacteriophage T4 in the absence of phage DNA replication

Under certain conditions the late genes of coliphage T4 may function in the absence of phage DNA replication. Quasi-late gene function is the function of certain late genes in the absence of both phage DNA replication and the product of the maturation gene 55. It does not depend on how phage DNA synthesis is prevented. Replication-uncoupled late gene function is late gene function from unreplicated DNA in the absence of phage ligase, and is still under the control of gene 55. It is most efficient if phage DNA replication is prevented by a mutation in the phage gene (43) for DNA polymerase. Both quasi-late gene function and replication-uncoupled late gene function are enhanced by the presence of mutations controlling a phage exonuclease (gene 46 or 47).     

Identification and preliminary characterization of a mutant defective in the bacteriophage T4-induced unfolding of the Escherichia coli nucleoid.

The nucleoids of Escherichia coli S/6/5 cells are rapidly unfolded at about 3 min after infection with wild-type T4 bacteriophage or with nuclear disruption deficient, host DNA degradation-deficient multiple mutants of phage T4. Unfolding does not occur after infection with T4 phage ghosts. Experiments using chloramphenicol to inhibit protein synthesis indicate that the T4-induced unfolding of the E. coli chromosomes is dependent on the presence of one or more protein synthesized between 2 and 3 min after infection. A mutant of phage T4 has been isolated which fails to induce this early unfolding of the host nucleoids. This mutant has been termed "unfoldase deficient" (unf-) despite the fact that the function of the gene product defective in this strain is not yet known. Mapping experiments indicate that the unf- mutation is located near gene 63 between genes 31 and 63. The folded genomes of E. coli S/6/5 cells remain essentially intact (2,000-3,000S) at 5 min after infection with unfoldase-, nuclear disruption-, and host DNA degradation-deficient T4 phage. Nuclear disruption occurs normally after infection with unfoldase- and host DNA degradation-deficient but nuclear disruption-proficient (ndd+), T4 phage. The host chromosomes remain partially folded (1,200-1,800S) at 5 min after infection with the unfoldase single mutant unf39 x 5 or an unfoldase- and host DNA degradation-deficient, but nuclear disruption-proficient, T4 strain. The presence of the unfoldase mutation causes a slight delay in host DNA degradation in the presence of nuclear disruption but has no effect on the rate of host DNA degradation in the absence of nuclear disruption. Its presence in nuclear disruption- and host DNA degradation-deficient multiple mutants does not alter the shutoff to host DNA or protein synthesis.     

Functional Interactions between the DNA Ligase of ESCHERICHIA COLI and Components of the DNA Metabolic Apparatus of T4 Bacteriophage

T4 phage completely defective in both gene 30 (DNA ligase) and the rII gene (function unknown) require at least normal levels of host-derived DNA ligase (E. coli lig gene) for growth. Viable E. coli mutant strains that harbor less than 5% of the wild-type level of bacterial ligase do not support growth of T4 doubly defective in genes 30 and rII (T4 30- rII- mutants). We describe here two classes of secondary phage mutations that permit the growth of T4 30- rII- phage on ligase-defective hosts. One class mapped in T4 gene su30 (Krylov 1972) and improved T4 30- rII- phage growth on all E. coli strains, but to varying degrees that depended on levels of residual host ligase. Another class mapped in T4 gene 32 (helix-destabilizing protein) and improved growth specifically on a host carrying the lig2 mutation, but not on a host carrying another lig- lesion (lig4). Two conclusions are drawn from the work: (1) the role of DNA ligase in essential DNA metabolic processes in T4-infected E. coli is catalytic rather than stoichiometric, and (2) the E. coli DNA ligase is capable of specific functional interactions with components of the T4 DNA replication and/or repair apparatus.     

In vitro replication of bacteriophage PRD1 DNA. Metal activation of protein-primed initiation and DNA elongation.

Bacteriophage PRD1 replicates its DNA by means of a protein-primed replication mechanism. Compared to Mg2+, the use of Mn2+ as the metal activator of the phage DNA polymerase results in a great stimulation of the initiation reaction. The molecular basis of the observed stimulatory effect is an increase in the velocity of the reaction. The phage DNA polymerase is also able to catalyze the formation of the initiation complex in the absence of DNA template. Although the presence of Mn2+ does not affect either the polymerization activity or the processivity of the DNA polymerase, this metal is unable to activate the overall replication of the phage genome. This can be explained by a deleterious effect of Mn2+ on the 3'-5'-exonucleolytic and/or the strand-displacement activity, the latter being an intrinsic function of the viral DNA polymerase required for protein-primed DNA replication.     

Method for determining whether a gene of Escherichia coli is essential: application to the polA gene

We have developed a general method for determining whether a gene of Escherichia coli is essential for viability. The method requires cloned DNA spanning the gene in question and a reasonably detailed genetic and physical map of the cloned segment. Using this information, one constructs a deletion of the target gene in vitro. For convenience, the deletion can be marked by an antibiotic resistance gene. A DNA segment containing the deletion is then cloned onto an att delta phage lambda vector. Integration of this phage, by homologous recombination at the target locus, and subsequent excision provide an efficient route for crossing the marked deletion onto the bacterial chromosome. Failure to delete the target gene indicates either that the resulting deletion was not viable or that the desired recombinational event did not take place. The use of prophage excision to generate the deletion allows one to estimate the fraction of deletion-producing events by analysis of the other product of the excision, the phage produced on induction of the prophage. In this way one can determine whether failure to recover a particular chromosomal deletion was due to its never having been formed, or, once formed, to its failure to survive. Applying this method to the polA gene, we found that polA is required for growth on rich medium but not on minimal medium. We repeated the experiment in the presence of plasmids carrying functional fragments of the polA gene, corresponding to the 5'-3' exonuclease and the polymerase-3'-5' exonuclease portions of DNA polymerase I. Surprisingly, either of these fragments, in the absence of the other, was sufficient to allow growth on rich medium.     

Nucleoside and nucleotide inactivation of R17 coat protein: evidence for a transient covalent RNA-protein bond

R17 coat protein forms a specific complex with a 21-nucleotide RNA hairpin containing the initiation site for the phage replicase gene. The RNA binding activity of the protein is inhibited by prior incubation with 5-bromouridine (BrU). The inactivation occurs with pseudo-first-order kinetics, and the inactive protein is stable to dilution. RNA binding activity of the BrU-inactivated protein is restored upon incubation with dithiothreitol. Inactivation of coat protein by N-ethylmaleimide or p-(chloromercuri)-benzenesulfonate indicates that a cysteine residue is located near the RNA binding site. Since 5-bromodeoxyuridine does not inactivate coat protein, a specific binding event appears to be required before inactivation can occur. Surprisingly, unmodified cytidine nucleotides also inactivate coat protein, with a specificity similar to the modified analogues. These results are discussed with regard to the formation of a transient covalent RNA-protein bond.     

Interaction between the gene 5 protein, gene 5 protein/single stranded fd DNA complex and gene 8 protein of the filamentous phage fd

An affinity column consisting of gene 8 protein, the major coat protein of fd phage, bound to Sepharose was prepared. Isolated gene 5 protein/single stranded fd DNA complex was found to bind to this column and was eluted with fd phage single stranded fd DNA. pH changes, and 1 M CaCl2 were not effective in eluting the protein from the affinity column. Gene 5 protein/single stranded fd DNA complex from the crude extracts of fd-infected E. coli also bound to the column, as did isolated gene 5 protein; whereas fd single stranded DNA alone did not. These results may be relevant for the illucidation of the molecular events occurring in the early stages of fd phage assembly.     

Molecular analysis of the UV protection and mutation genes carried by the I incompatibility group plasmid TP110.

The abortive infection of bacteriophage T7 in Shigella sonnei D2 371-48 is characterized by a premature inhibition of phage DNA replication and nucleolytic breakdown of all phage DNA. Mutations in T7 gene 10 which are recessive to the presence of the wild-type allele can alleviate the restriction of phage growth. Phage T3 productively infects S. sonnei D2 371-48, as does a T7-T3 hybrid phage that contains, in particular, a gene 10 of T7 origin. It is the presence of T3 DNA ligase that allows phage growth on S. sonnei D2 371-48, and this enzyme can also rescue wild-type T7 from the abortive infection. T7+ is therefore functionally ligase deficient during the infection of S. sonnei D2 371-48; this deficiency is a result of the expression of the phage capsid protein, but it is independent of the assembly of the protein into a procapsid or other morphogenetic structure.     

Control of directionality in L5 integrase-mediated site-specific recombination

Mycobacteriophage L5 is a temperate phage that forms lysogens in Mycobacterium smegmatis. These lysogens carry an integrated L5 prophage inserted at a specific chromosomal location and undergo subsequent excision during induction of lytic growth. Both the integrative and excisive site-specific recombination events are catalyzed by the phage-encoded tyrosine integrase (Int-L5) and require the host-encoded protein, mIHF. The directionality of these recombination events is determined by a second phage-encoded protein, Excise, the product of gene 36 (Xis-L5); integration occurs efficiently in the absence of Xis-L5 while excision is dependent upon it. We show here that Xis-L5 binds to attR DNA, introduces a DNA bend, and facilitates the formation of an intasome-R complex. This complex, which requires mIHF, Xis-L5 and Int-L5, readily recombines with a second intasome formed by Int-L5, mIHF and attL DNA (intasome-L) to generate the attP and attB products of excision. Xis-L5 also strongly inhibits Int-L5-mediated integrative recombination but does not prevent either the protein-DNA interactions that form the attP intasome (intasome-P) or the capture of attB, but acts later in the reaction presumably by preventing the formation of a recombinagenic synaptic intermediate. The mechanism of action of Xis-L5 appears to be purely architectural, influencing the assembly of protein-DNA structures solely through its DNA-binding and DNA-bending properties.     

Filamentous phage replication initiator protein gpII forms a covalent complex with the 5' end of the nick it introduced

Rolling circle type DNA replication is initiated by introduction of a nick in the leading strand of the origin by the initiator protein, which in most cases binds covalently to the 5' end of the nick. In filamentous phage, however, such a covalent complex has not been detected. Using a suitable substrate and short reaction time, we show that filamentous phage initiator gpII forms a covalent complex with nicked DNA, which rapidly dissociates unless gpII is inactivated. A peptide-DNA complex was isolated from trypsin digest of the complex by ion-exchange column chromatography and gel filtration, and its peptide sequence was determined. The result indicated that gpII was linked to DNA by the tyrosine residue at position 197 from the N-terminus. The mutant protein in which this tyrosine was replaced by phenylalanine did not show any detectable activity to complement gene II amber mutant phage in vivo. In vitro, the mutant protein recognized the origin and bent DNA as well as the wild-type does, but failed to introduce a nick and to relax the superhelicity of cognate DNA.