Inactivation of bacteriophage PM2 during storage

The kinetics of bacteriophage inactivation in the medium that is optimal for its storage has been studied at temperatures from 4 to 55 degrees C. The plot of Arrhenius dependence of the constant of inactivation rate consists of the two linear parts with the energies of activation Ea = 25 kcal/mol for 4-37 degrees C and Ea = 91 kcal/mol for 37-55 degrees C. The DNA of inactivated bacteriophage remained mostly in superspiralized form and completely preserved its biological activity as tested by transfection in spheroplasts. The analysis of inactivation kinetics suggests ageing of virions cultivated at 4 degrees C. The addition of watersoluble antioxidant amoxipin did not change the inactivation kinetics. The addition of antioxidant ionol with twin-80 increased the inactivation that was paralleled by the bacteriophage DNA degradation.     

Control of membrane morphogenesis in bacteriophage PM2

The regulation of membrane formation in bacteriophage PM2 serves as a simple model for changes in membrane structure in eukaryotic cells. Prior to Pseudomonas host lysis, wild-type virions mature to an icosahedral morphology at the inner face of the cytoplasmic membrane. The proliminary charcterization of two temperature-sensitive mutants of PM2 is described. In cells infected at the restrictive temperature with ts 1, an abundance of “empty” virus-size membrane vesicles are seen. Synthesis of DNA is also reduced in ts 1 infected cells. The preponderance of vesicles is not sen in cells infected with wil-type virus or with ts 1 at the permissive temperature. The “empty” appearance of the viral membranes suggests that viral DNA is not encapsulated. The major viral capsid protein (MW 26,000) is located just out side the viral membrane and normallyl sediments with host and virus membranes; insted, large amounts of capsid protein can be precipitated from the supernatant with TCA. Compared to cells infected with wild type virus, cells infected with is 5 at th restrictive temperature produce inside the cell an aboundance of virus-soze membrane vesicles. Taken Together, These results with viral mutants suggest that formation of a viral membrane of the proper size does not require a DNA core around which to form, or an outer scaffolding of coat protein against which to form a spherical bilayer.     

Photoinactivation of bacteriophage PM2 by cyanine dyes]

Photoinactivation of the lipid-containing bacteriophage PM2 by visible light and cyanine dyes (carbo- and dicarbocyanines), aluminum phtalocyanine tetrasulfonate and methylene blue was studied. It was concluded that cyanine dye aggregates adsorbed on phage particles and oxygen are essential for phage photoinactivation.     

Penetration of membrane-containing double-stranded-DNA bacteriophage PM2 into Pseudoalteromonas hosts

The icosahedral bacteriophage PM2 has a circular double-stranded DNA (dsDNA) genome and an internal lipid membrane. It is the only representative of the Corticoviridae family. How the circular supercoiled genome residing inside the viral membrane is translocated into the gram-negative marine Pseudoalteromonas host has been an intriguing question. Here we demonstrate that after binding of the virus to an abundant cell surface receptor, the protein coat is most probably dissociated. During the infection process, the host cell outer membrane becomes transiently permeable to lipophilic gramicidin D molecules proposing fusion with the viral membrane. One of the components of the internal viral lipid core particle is the integral membrane protein P7, with muralytic activity that apparently aids the process of peptidoglycan penetration. Entry of the virion also causes a limited depolarization of the cytoplasmic membrane. These phenomena differ considerably from those observed in the entry process of bacteriophage PRD1, a dsDNA virus, which uses its internal membrane to make a cell envelope-penetrating tubular structure.     

Isolation and characterization of bacteriophage PM2 from Aeromonas hydrophila

PM2 is an Aeromonas-specific bacteriophage isolated on A. hydrophila strain AH-3. The bacteriophage receptor for this phage was found to be the lipopolysaccharide (LPS), specifically a low-molecular weight LPS fraction (LPS-core oligosaccharides). Mutants resistant to this phage were isolated and found to be devoid of LPS O-antigen and altered in the LPS-core. No other outer-membrane (OM) molecules appeared to be involved in phage binding.     

Calcium requirement for assembly of the lipid-containing bacteriophage PM2

The bacteriophage PM2 requires extracellular Ca²⁺ at concentrations greater than 3 · 10⁻⁴ M for the production of viable virus, whereas the host cell Pseudomonas BAL-31 grows normally in medium containing 3 · 10⁻⁵ M Ca²⁺ (low calcium). Virus attachment occurs normally in low calcium, the infected cultures partially lyse, but no infectious virus particles are released. Sucrose gradient analysis shows that lysates made in low calcium contain no PM2-like particles. The addition of calcium very late in the infectious cycle completely restores virus production to cultures infected in low calcium, whereas removal of calcium after infection prevents virus production. Our experiments indicate that Ca²⁺ is essential for some process late in the lytic cycle, such as the final assembly of stable, infectious PM2 particles.     

Molecular cloning and physical map of bacteriophage PM2 DNA

The entire genome and the DNA fragments of the lipid-containing bacteriophage pM2 were cloned in the pBR322 plasmid vector. A physical map including the sites for the following restriction enzymes was obtained: HpaII, HaeIII, TthI, Sau96I, AvaII, PstI, BstNI, AccI, HincII, HpaI and HindIII. No restriction sites on PM2 DNA were found for BalI, BamHI, BclI, BglI, BglII, BstEII, KpnI, PvuII, SacI, SalI, Sau3A, XbaI and XhoI.     

Encapsidation of heterologous RNAs by bacteriophage MS2 coat protein.

The RNA bacteriophages of E. coli specifically encapsidate a single copy of the viral genome in a protein shell composed mainly of 180 molecules of coat protein. Coat protein is also a translational repressor and shuts off viral replicase synthesis by interaction with a RNA stem-loop containing the replicase initiation codon. We wondered whether the translational operator also serves as the viral pac site, the signal which mediates the exclusive encapsidation of viral RNA by its interaction with coat protein. To test this idea we measured the ability of lacZ RNA fused to the translational operator to be incorporated into virus-like particles formed from coat protein expressed from a plasmid. The results indicate that the operator-lacZ RNA is indeed encapsidated and that nucleotide substitutions in the translational operator which reduce the tightness of the coat protein-operator interaction also reduce or abolish encapsidation of the hybrid RNA. When coat protein is expressed in excess compared to the operator-lacZ RNA, host RNAs are packaged as well. However, elevation of the level of operator-lacZ RNA relative to coat protein results in its selective encapsidation at the expense of cellular RNAs. Our results are consistent with the proposition that this single protein-RNA interaction accounts both for translational repression and viral genome encapsidation.     

Interaction between bacteriophage PM2 protein IV and DNA.

The interaction between DNA and the structural protein IV of bacteriophage PM2 was studied by co-sedimentation, filter binding and electron microscopy. The co-sedimentation data and the sigmoid-shaped filter binding curve were interpreted in terms of co-operative binding. At a given DNA/protein input ratio, some DNA molecules were associated with a large amount of protein IV while others had no detectable protein bound to them. Electron microscopic examination of DNA-protein IV mixtures showed highly condensed DNA molecules alongside uncomplexed native DNA. Dissociation experiments revealed the presence of two types of complexes. Type I dissociated rapidly while type II had a long half-life. Dissociation of complexes obtained with increasing protein/DNA ratios suggested that the type I complex was a precursor of type II complex. Protein IV binds equally well to superhelical, relaxed or linear DNA as well as to single-stranded DNA. These observations lead to a model for the interaction and for the consequent alterations in the DNA structure.     

Infection of spheroplasts of Pseudomonas with DNA of bacteriophage PM2

Summary Spheroplasts of Pseudomonas BAL-31/PM2, obtained by treatment of the bacteria with lysozyme, can be infected with purified DNA from bacteriophage PM2. After 4 h of incubation the yield of progeny phage reaches a value of 10⁷-6×10⁷ plaque forming units/g PM2 DNA. The yield increases linearly with the concentration of DNA over at least 3 orders of magnitude.The biological activity of double-stranded circular PM2 DNA containing one or more single-strand breaks per molecule (component II), does not differ significantly from that of intact PM2 DNA (component I). Single-stranded PM2 DNA obtained by denaturation of component II, and the irreversible alkali-denatured form of component I are also infective.     

Characterization of temperature-sensitive mutants of bacteriophage PM2: Membrane mutants

Summary In an effort to understand the genetic regulation of membrane morphogenesis, twenty-nine temperature-sensitive mutants of the membrane-containing bacteriophage PM2 were isolated. Characterization at restrictive temperature revealed groups showing no lysis (Groups I–IV), partial lysis (Groups V–VIII), and full lysis (Groups IX–XII) of the host Pseudomonas BAL-31. When the cell lysis data are considered in conjunction with data on stimulation of viral DNA synthesis, at least six mutant groups are defined. Analysis by gel electrophoresis of the pattern of viral proteins synthesized under restrictive conditions further divides the mutants into twelve groups. Temperature shift experiments delineate early, intermediate and late mutants. Complementation data support some of these groupings. The observed low levels of complementation and recombination are discussed in terms of gene product/genome restriction, bound to the membrane at the site of infection.It is of particular interest to membrane morphogenesis that under restrictive conditions late mutants in Groups II, III and IV make empty-appearing vesicles inside the cell that are the size of virus membranes as seen in thin sections of cells in the electron microscope. Mutants ts 1 (Group II) and ts 12 (Group III) show defects in their ability to incorporate into membranes viral structural proteins sp 13 and sp 6.6. The possibility is discussed that either of these proteins control the size and shape of the viral membrane.     

Structure and synthesis of a lipid-containing bacteriophage. Amphiphilic properties of protein IV of bacteriophage PM2

Interactions between lipids and the DNA-binding protein (protein IV) purified from bacteriophage PM2 were studied in vitro. The efficiency of incorporation of protein IV into single-walled liposomes was more than 90%. Protein IV embedded in liposomes interacted more strongly with PM2 DNA than protein IV alone. The DNA--protein-IV--liposome complex was relatively stable as observed by sedimentation behavior on a sucrose gradient. The interaction between DNA and the protein-IV--liposome was abolished by tryptic digestion, even though 40% of the protein remained in the vesicle. More than 70% of the amino acids of this embedded peptide segment were hydrophobic. Carboxypeptidase digestion of the protein-IV--liposome caused a release of 20% of the radioactivity of the vesicle without changing the DNA-binding ability of the complexes. Modification of the protein-IV--liposome with the chemical probe, 2,4-dinitrofluorobenzene, and analysis of the tryptic peptides released from the protein-IV--liposome demonstrated that the N-terminal basic amino acid cluster segment responsible for the DNA binding was located on the outer surface of the bilayer. These results support an earlier model in which protein IV anchors itself in the inner leaflet of the PM2 bilayer membrane, interacting with the DNA in the virion.