Transfection of Corynebacterium glutamicum with Temperate Phage ϕ CG1

Versatile plasmid vectors useful for gene cloning in Brevibacterium lactofermentum, a glutamic acid-producing bacterium, have been constructed. The trimethoprim (Tp)-resistant dihydrofolate reductase gene derived from chromosomal DNA of the Tp-resistant mutant of B. lactofermentum was introduced into pAM330, a cryptic plasmid in B. lactofermentum. The constructed cloning vector pAJ228 (7.6kb) exists in 10 to 20 copies in cells of B. lactofermentum and donated Tp-resistance, which is a useful selective marker of transformants. pAJ228 was further improved to a versatile plasmid vector pAJ224 having some profitable characteristics such as smaller size (3.7 kb), higher copy number (60 ~ 80 copies), and additional useful cloning sites (Bam HI, Pst I and Sal I) equipped with two different promoters arranged at both orientations for the expression of passenger DNA without promoter. These plasmids were stably retained in B. lactofermentum even in the absence of Tp over many generations. Thus, they have been found very powerful vectors for gene cloning in Brevibacterium and the related bacteria.     

DNA Products in In Vitro DNA Synthesis Using Bacteriophage ϕX174 Single-stranded DNA

We described product analysis of DNA synthesized in chloroplast lysate from liverwort Marchantia polymorpha L. cell suspension cultures. Characteristics of in vitro DNA synthesis by chloroplast lysate using bacteriophage ?X174 single-stranded DNA were very similar to those in the case of double-stranded calf thymus DNA reported previously. Autoradiographic analysis clearly showed the incorporation of radioactive [α-³²P]-dCTP into DNA molecules associated with bacteriophage ?X174 single-stranded template DNA, indicating conversion of bacteriophage ?X174 single-stranded DNA to double-stranded DNA (RF III, double-stranded linear molecule). Experiments on the fate of [³²P]-labeled single-stranded DNA also showed a clear conversion of the single-stranded DNA to double-stranded DNA. Furthermore, patterns of sucrose density gradient centrifugations (neutral and alkaline) showed the production of two major components in in vitro DNA synthesis by chloroplast lysate. This also indicated conversion of bacteriophage ?X174 single-stranded DNA to double-stranded DNA (RF III form). Our results suggest that the mechanism of chloroplast DNA replication could be the mode of strand-displacement DNA synthesis as seen in animal mitochondrial DNA synthesis.     

Environmental Factors that influence the Transition from Lysogenic to Lytic Existence in the ϕHSIC/Listonella pelagia Marine Phage–Host System

The marine phage ϕHSIC has been previously reported to enter into a pseudolysogenic-like interaction with its host Listonella pelagia. This phage–host system displays behaviors that are characteristic of both pseudolysogeny and lysogeny including a high rate of spontaneous induction and chromosomal integration of the prophage. To determine what parameters may influence the transition from lysogenic to lytic existence in the ϕHSIC/L. pelagia phage–host system, cultures of this organism were incubated under different environmental conditions, while host cell growth and bacteriophage production were monitored. The environmental parameters tested included salinity, temperature, a rapid temperature shift, and degree of culture aeration. The highest titers of phage were produced by HSIC-1a cells grown in high-salinity nutrient artificial seawater media (67 ppt with a natural salinity equivalent of 57 ppt) or those cultured in highly aerated nutrient artificial seawater media (cultures shaken at 300 rpm). Conversely, the lowest titers of phage were produced under low salinity or rate of aeration. In general, conditions that stimulated growth resulted in greater lytic phage production, whereas slow growth favored lysogeny. These results indicate that elevated salinity and aeration influenced the switch from lysogenic to lytic existence for the phage ϕHSIC. These results may have implications for environmental controls of the lysogenic switch in natural populations of marine bacteria.     

Isolation of DNA-dependent RNA polymerase fromStreptomyces granaticolor and its binding to phage ϕ29 DNA

Partially purified DNA-dependent RNA polymerase ofStreptomyces granaticolor was further separated on phosphocellulose in 50% glycerol and a single activity peak was obtained. The enzyme isolated in this way consisted of 4 main proteins with molar mass of 145, 132, 50 and 46 kg/mol. These four subunits, represented 93% proteins of the active fraction. To test the ability of RNA polymerase to recognize specific sites on DNA, binding sites for RNA polymerase on phage ϕ29 DNA were mapped by electron microscopy. The specific binding sites detected were compared with those for RNA polymerases fromEscherichia coli andBacillus subtilis.     

DNA Synthesis at the Site of a Red-Mediated Exchange in Phage λ

In phage lambda, progeny particles bearing unreplicated chromosomes are recombinant by action of lambda's Red system only near the right end of the chromosome. These recombinants are frequently heterozygous (heteroduplex) for markers located there. In replication-blocked crosses involving two heavy-labeled parents we find that particles in the solitary peak, containing progeny with fully conserved DNA, vary in density. Those on the heavy side of this peak are more apt to be heterozygous than are those on the light side. The data fit a model in which a double chain cut at cos, lambda's packaging origin, is followed by partial exonucleolytic degradation of lambda's r chain from the right end leftward. The exposed l chain, which thereby constitutes a 3' overhang, invades an intact, circular homologue after itself suffering some degradation. Completion of the recombinant chromosome sometimes involves DNA synthesis primed by the invading chain.     

Break-Join Recombination in Phage λ

In phage lambda, when DNA replication is blocked, recombination mediated by the Red pathway occurs only near the double-chain break site, cos, that defines the termini of the virion chromosome. The recombinants initiated by cos contain newly synthesized DNA near cos, in amount corresponding to a few percent of the length of lambda. A restriction enzyme cut delivered to one parent far from cos results in elevated recombination near the restriction site. Recombinants induced by this cut have a similarly small amount of DNA synthesis in these replication-blocked crosses. When restriction cuts are introduced in the presence of normal amounts of all of the DNA replication enzymes, many of the resulting recombinants still enjoy, at most, a small amount of DNA synthesis associated with the exchange event. Thus, these experiments fail to support the previously considered possibility that Red-mediated recombination in lambda proceeds largely through a break-copy pathway.     

Physical and Biological Properties of Phage φ29 Deoxyribonucleic Acid

Deoxyribonucleic acid (DNA) molecules having a mean length of 5.8 mum were released from purified Bacillus subtilis bacteriophage phi29 with 2 m sodium perchlorate. Small 0.1 to 0.2-mum molecules were also detected in these DNA preparations. Since intact single chains annealed to form linear duplex molecules, phage phi29 DNA was found to be nonpermuted. The molecular weights of single chains of phi29 DNA were approximately half that of native DNA, as determined by analytical band sedimentation in CsCl, indicating that phi29 DNA is composed of two continuous polynucleotide chains. The molecular weight values of native and annealed phi29 DNA from sedimentation agreed with the molecular weight values obtained from electron microscopy. The infectivity of phi29 DNA was reduced to a low level by alkaline denaturation and was partially restored by annealing.     

Nonreplicated DNA and DNA Fragments in T4 r? Bacteriophage Particles: Phenotypic Mixing of a Phage Protein

"Conservative phage" containing a genome derived from an infecting phage particle which has not undergone replication in the cell but nevertheless has become encapsulated and released in a normal phage particle, are found after infection of Escherichia coli with rII(-) or rI(-) mutants under conditions which result in rapid lysis. If such conservative phage are derived from a mixed infection with v(+) and v(1) phage, they display phenotypic mixing of the v gene product (an endonuclease carried in the phage particle). Populations of rI and rII mutant phage grown under conditions of rapid lysis include particles containing short DNA fragments. It is suggested that a "maturation defect", common to rI and rII mutants, but absent in rIII mutants, may account for the encapsulation of nonreplicated DNA as well as that of the DNA fragments.     

Electron Microscopic Study on the Inner Structure of a Lipid-containing Acido-thermophilic Phage, ϕNS11

The inner structure of a lipid-containing phage, ?NS11, was examined under an electron microscope. The thin-sectioned or urea-treated and negatively stained phage showed a central core and an outer shell. Treatment of the phage with chloroform or Tris-HCl (pH 8) visualized the outer and the inner protein shells, which had hexagonal outlines. Particles having tail-like structures were sometimes observed in 4 m urea-treated samples. Based on these observations, a possible inner structure of the phage was proposed.     

Conditional Mutations in the Yeast DNA Primase Genes Affect Different Aspects of DNA Metabolism and Interactions in the DNA Polymerase α-Primase Complex

Different pri1 and pri2 conditional mutants of Saccharomyces cerevisiae altered, respectively, in the small (p48) and large (p58) subunits of DNA primase, show an enhanced rate of both mitotic intrachromosomal recombination and spontaneous mutation, to an extent which is correlated with the severity of their defects in cell growth and DNA synthesis. These effects might be attributable to the formation of nicked and gapped DNA molecules that are substrates for recombination and error-prone repair, due to defective DNA replication in the primase mutants. Furthermore, pri1 and pri2 mutations inhibit sporulation and affect spore viability, with the unsporulated mutant cells arresting with a single nucleus, suggesting that DNA primase plays a critical role during meiosis. The observation that all possible pairwise combinations of two pri1 and two pri2 alleles are lethal provides further evidence for direct interaction of the primase subunits in vivo. Immunopurification and immunoprecipitation studies on wild-type and mutant strains suggest that the small subunit has a major role in determining primase activity, whereas the large subunit directly interacts with DNA polymerase α, and either mediates or stabilizes association of the p48 polypeptide in the DNA polymerase α-primase complex.     

Annealing Vs. Invasion in Phage λ Recombination

Genetic recombination catalyzed by λ's Red pathway was studied in rec(+) and recA mutant bacteria by examining both intracellular λ DNA and mature progeny particles. Recombination of nonreplicating phage chromosomes was induced by double-strand breaks delivered at unique sites in vivo. In rec(+) cells, cutting only one chromosome gave nearly maximal stimulation of recombination; the recombinants formed contained relatively short hybrid regions, suggesting strand invasion. In contrast, in recA mutant cells, cutting the two parental chromosomes at non-allelic sites was required for maximal stimulation; the recombinants formed tended to be hybrid over the entire region between the two cuts, implying strand annealing. We conclude that, in the absence of RecA and the presence of non-allelic DNA ends, the Red pathway of λ catalyzes recombination primarily by annealing.     

Plasmonic Circular Dichroism Study of DNA–Gold Nanoparticles Bioconjugates

Plasmonic circular dichroism (CD) responses of hybrid nanostructures containing noble metal nanoparticles and chiral molecules have received increasing interest with various applications in nanophotonics. Chiral biomolecules show strong CD signals typically found in the ultraviolet region, whereas, in the visible range, they produce a weak signal. Strengthening the CD signal in the visible region is of high importance, which could be achieved through fabrication of novel hybrid nanostructures. Herein, gold nanoparticles (GNPs) have been assembled via DNA linker to investigate the possibility of enhancing plasmonic CD signal in the visible range. DNA-linked assemblies with pre- and postannealed conditions were characterized by ultraviolet–visible spectroscopy, dynamic light scattering (DLS), and CD spectropolarimetry. In the presence of DNA linker with sticky ends, the aggregation phenomenon was traced by red shifts of surface plasmon resonance of nanoparticles. Time-dependent hybridization of single-stranded “sticky ends” with DNA-conjugated GNPs and increased probability of hydrogen bond formation lead to enhancement of CD signals in the ultraviolet region. Complexation of biomolecule and nanoparticle assemblies induced enhanced CD signals in the visible range, which was noticed both before and after purification. DLS characterization of the assemblies also confirmed the difference in the size of aggregates, which could be controlled by the linker molecules. This investigation encourages possibility of utilizing plasmonic CD technique as a tool for tracing fabricated nanostructure assemblies with enhanced characterization possibility.     

Role of φ29 connector channel loops in late-stage DNA packaging

Double-stranded DNA bacteriophages and their eukaryotic virus counterparts have 12-fold head-tail connector assemblages embedded at a unique capsid vertex. This vertex is the site of assembly of the DNA packaging motor, and the connector has a central channel through which viral DNA passes during genome packaging and subsequent host infection. Crystal structures of connectors from different phages reveal either disordered residues or structured loops that project into the connector channel. Given the proximity to the translocating DNA substrate, these loops have been proposed to play a role in DNA packaging. Previous models have proposed structural motions in either the packaging ATPase or the connector channel loops as the driving force that translocates the DNA into the prohead. Here, we mutate the channel loops of the Bacillus subtilis bacteriophage φ29 connector and show that these loops have no active role in translocation of DNA. Instead, they appear to have an essential function near the end of packaging, acting to retain the packaged DNA in the head in preparation for motor detachment and subsequent tail assembly and virion completion.     

Inhibition of Bacteriophage ϕX174 Replicaiive-form DNA Replication by Rifampicin

?X174 DNA synthesis as well as phage production was inhibited by rifampicin when added in early phase of infection. Rifampicin did not inhibit the formation of parental duplex replicative-form, RF, and it inhibited the synthesis of progeny RF under conditions where protein synthesis was not necessary to be synthesized continuously. In addition, replication of parental RF into progeny RF was inhibited by rifampicin under conditions where a high concentration of chloramphenicol did not affect the replication. Consequently, it could be concluded that RNA synthesis other than that required for protein synthesis was necessary for both the initiation and continuation of RF replication.     

Dissecting the role of the ?29 terminal protein DNA binding residues in viral DNA replication

Phage ϕ29 DNA replication takes place by a protein-priming mechanism in which the viral DNA polymerase catalyses the covalent linkage of the initiating nucleotide to a specific serine residue of the terminal protein (TP). The N-terminal domain of the ϕ29 TP has been shown to bind to the host DNA in a sequence-independent manner and this binding is essential for the TP nucleoid localisation and for an efficient viral DNA replication in vivo. In the present work we have studied the involvement of the TP N-terminal domain residues responsible for DNA binding in the different stages of viral DNA replication by assaying the in vitro activity of purified TP N-terminal mutant proteins. The results show that mutation of TP residues involved in DNA binding affects the catalytic activity of the DNA polymerase in initiation, as the K_m for the initiating nucleotide is increased when these mutant proteins are used as primers. Importantly, this initiation defect was relieved by using the ϕ29 double-stranded DNA binding protein p6 in the reaction, which decreased the K_m of the DNA polymerase for dATP about 130–190 fold. Furthermore, the TP N-terminal domain was shown to be required both for a proper interaction with the DNA polymerase and for an efficient viral DNA amplification.