Photodynamic effect of proflavine on ?X174 bacteriophage, its DNA replicative form and its isolated single-stranded DNA: Inactivation, mutagenesis and repair

Summary In contrast to that what is observed with most inactivating agents, proflavine-mediated photoinactivation is about 10 times more efficient on double-stranded X 174 replicative form DNA (RFI) than on isolated single-stranded X 174 DNA. Both X RFI DNA and encapsidated DNA have similar sensitivities to proflavine and light treatment.With the three substrates studied, reactivation can occur through high multiplicity of infection and depends upon the cellular rec A gene product. No effect of the pol A, uvr A or lex A gene mutations has been found on either phage or DNA inactivation rates.The photodynamically induced lesions can be repaired at least in part, by the SOS repair system induced in the host-cells by a 100 J ·m^-2 UV irradiation. SOS repair does not occur with bacteria (or spheroplasts) irradiated in the presence of chloramphenicol.Reversion frequency of the X 174 amber mutations indicates that 1) photodynamically induced lesions are mutagenic whether the rec A gene product is present or not in the indicator bacteria; 2) induction of the SOS repair system is accompanied by a mutagenic process which almost results in a two fold increase of the reversion frequency; and 3) multiplicity reactivation occurs through a recombinational process and is not mutagenic per se.     

Differential survival and chloramphenicol-insensitive error-prone repair of hydroxylamine-inactivated θX174 bacteriophage mutants

Features of inactivation, repair and concomitant mutagenesis of hydroxylamine- treated θX174 bacteriophages are reported here. (1) For reasons unknown, the nonsense phage mutants tested here were far more sensitive to hydroxylamine than the wild-type phage. In contrast, the sensitivities of these same θX174 mutants to UV-irradiation are indistinguishable. (2) Hydroxylamine-treated amber phages mutated to ochre but not to wild-type particles, i.e., G → A transition events were recovered. (3) The repair of θX174 phages from hydroxylamine-induced damage was error-prone, but unlike UV damage, did not require protein synthesis de novo. Possible mechanims of these novel features are discussed.     

The nucleotide sequence of bacteriophage φX174

The complete nucleotide sequence of the DNA of bacteriophage φX174 has been determined. The provisional sequence (Sanger et al., 1977a) deduced largely by the plus and minus method, has been completed and confirmed, predominantly using the terminator method (Sanger et al., 1977b). About 30 revisions were found to be necessary in the 5386-nucleotide sequence. The amino acid sequences of the ten proteins for which the DNA codes have also been deduced.     

The role of nonspecific serum factors in the antibody response to the ΦX 174 bacteriophage

The role of the “antibody cofactor” and of other heat-labile serum components (complement) in the neutralization of the ?X 174 bacteriophage by means of specific antibodies was studied. Sera of white mice, guinea-pigs and rabbits obtained mainly early after phage administration were investigated. The character of antibodies was estimated from their sensitivity to 2-mercaptoethanol or else by chromatography on Sephadex G-200. Sera from the first days after the administration of the phage containing mostly type 19S antibodies, and sera from later periods after the administration containing mostly type 7S antibodies, were tested. (Some evidence was also obtained about the formation of slowly sedimenting antibodies sensitive to 2-mercaptoethanol in the rabbit.) With a single exception the tested sera showed no significant decrease of the neutralization activity after 30-mins. heating at 56°C or at 60°C and no increase of the neutralization power could be observed after the application of homologous or normal mouse serum. It is concluded that the heat-labile components of normal sera including the complement and the “antibody cofactor” play no role in specific phage neutralization.     

Complementation experiments between conditional lethal mutants of bacteriophage ?X174

Summary Complementation experiments with temperature sensitive (ts) and suppressor sensitive (sus) mutants of bacteriophage X174 unambiguously revealed five cistrons on the basis of a clear bipartition of burst sizes.A new group of sus mutants (emeralds) was found, defective in a function essential for growth in Shigella sonnei V64.The complementation between ts and sus mutants was in general asymmetric in that the yield of ts particles was lower than that of the sus particles. The mutants of one cistron (defective in RF-replication) showed a completely asymmetric complementation behaviour both of ts and sus mutants. The ts mutants of this group, which show to be early, appear to be defective in two functions.The possibility is discussed that in each cell only one phage genome is replicated. This would explain both kinds of asymmetric complementation and the low burst sizes that were obtained when mutants of particular genes were complemented.     

Genes and regulatory sequences of bacteriophage ∅X174

Fragments of the DNA of bacteriophage ∅X174 were inserted in the plasmids pACYC177 and pBR322, in order to test the in vivo effects of separate phage genes and regulatory sequences. The ∅X174 inserts were identified by recombination and complementation with phage mutants, followed by restriction enzyme analysis. The genes B, C, F and G can be maintained stably in the cell even when there is efficient expression of these viral genes. Recombinant plasmids with the complete genes D and E can only be maintained when the expression of these genes is completely blocked. Expression of complete H and J genes could not yet be demonstrated. The intact gene A was apparently lethal for the host cell, as it was never found in the recombinants. The genes F and G are expressed, even when they are not preceded by one of the well characterized viral or plasmid promoter sequences. Screening of the nucleotide sequence of ∅X174 gives two promoter-like sequences just in front of the two genes. Viral sequences with replication signals (the ∅X174 (+) origin of replication, the initiation site for complementary strand synthesis and the incompatibility sequence) appeared to be functional also when inserted in recombinant plasmids. A plasmid with the ∅X (+) origin can be forced to a rolling circle mode of replication. The A protein produced by infecting phages works in trans on the cloned viral origin. The (−) origin can function as initiation signal for complementary strand synthesis during transduction of single-stranded plasmid DNA. The intracellular presence of the incompatibility sequence on a plasmid prevents propagation of infecting phages.     

Effects of mutations in genesfadR,fabB, fadE,andenvC ofEscherichia coli on the action of the lysis gene of bacteriophageϕX174

The lytic effect of the expression of the cloned geneE of bacteriophage X174 inEscherichia coli is considerably amplified by a mutation in thefadR gene, which primarily affects the regulation of fatty acid degradation. In contrast, reduction of the fluidity of the cell membranes by use of thefabB andfadE mutations, which interfere with the synthesis and the oxidation of unsaturated fatty acids, severely inhibits the action of the X174 lysis gene product. A chain-forming mutant carrying a pleiotropic mutation in theenvC locus is also refractory to the X174 lysis protein. As shown by reversion and complementation of theenvC mutatation, a defect in at least one additional gene (rle) is involved in the generation of this refractoriness.     

Excision repair participates in the Weigle reactivation of ultraviolet light-irradiated φ X174 double-stranded DNA

The efficiency of Weigle reactivation of ultraviolet light-irradiated single and double-stranded φX174 DNA by wild-type and excision repair-defective E. coli hosts was determined. After limited exposure to ultraviolet light, the efficiency of Weigle reactivation by an ultraviolet light-irradiated wild-type host was greater for double-stranded φX174 DNA than for its single-stranded counterpart. However, the efficiency of inducible until it became constant at a value 1.5 times less than that for single-stranded form of φX174 DNA. The efficiency of Weigle reactivation of the single-stranded DNA molecule by the same host, however, was independent of the dose to the DNA, as were the efficiencies of reactivation for both forms of φX174 DNA by ultraviolet light-irradiated excision repair-deficient hosts. In excision repair-defective hosts the efficiency of Weigle reactivation of double-stranded φX174 DNA was also 1.5 time less than that for the single-stranded molecule.These results suggest that the Weigle reactivation of double-stranded φX174 DNA is mediated in part by an excision repair process, and that this component of Weigle reactivation eventually can be saturated by ultraviolet light-induced DNA damage leaving other repair processes, such as trans-damage synthesis, responsible for the remaining inducible reactivation.     

Alterations of the cytoplasmic and outer membranes ofEscherichia coli infected with bacteriophage ϕX174

InEscherichia coli C infected with bacteriophage X174, the cytoplasmic and outer membranes of the host bacterium exhibit various alterations in their protein composition as revealed by sodium dodecyl sulfate gel electrophoresis of purified membranes. These alterations result mainly from the action of the lysis gene product of the phage. One effect of the changes occurring in the membranes results in different rates of release of wild-type phage and its lysis-negative mutant from glycine spheroplasts. The activity of phospho-MurNAc-pentapeptide translocase, an enzyme involved in murein synthesis and located in the cytoplasmic membrane, is unimpaired by these alterations.     

Phototoxicity of phenothiazine derivatives. I. Inactivating and mutagenic effects on bacteriophage φX174

Inactivation of φX174 bacteriophages as a function of the irradiation time in the near-UV and in the presence of triflupromazine (TFPZ), promazine (PZ), chlorpromazine (CPZ) or methoxypromazine (MTPZ) proceeds according to single hit kinetics. Acepromazine (ACPZ) has no significant activity. At low concentrations (0.1 mM) TFPZ and PZ are the most active compounds. Higher concentrations (up to 5 mM) result in a protective effect by these two compounds but cause increased inactivation rates in the case of MTPZ or CPZ. Photoinactivation mediated by TFPZ or CPZ increases the reversion frequency of a φXamber mutant. Neither MTPZ nor PZ sensitization induces mutagenesis. The effect of NaN₃ on the phage inactivation rate varies depending upon both the sensitizer and the concentration of the quencher. Phage inactivation in an N₂ atmosphere is measurable only in the presence of high concentrations of CPZ and MTPZ. The drugs do not show any selectivity for calf thymus DNA or bovine serum albumin, at least as measured by dialysis equilibrium experiments.     

Effect of Oxidized Polyamines on the Infectivity of φX174 DNA

Oxidized spermine and oxidized spermidine inhibited markedly the infectivity of the 6 m-urea treated φX174 particle, whereas they did not inactivate the infectivity of the untreated phage particle. They also markedly inhibited the infectivity of φX174 DNA, while φX174 RF I DNA was less sensitive to these reagents. These facts suggested that oxidized polyamines could react with phage DNA.

The possible reasons of the insensitivity of phage φX174 particle and less sensitivity of φX174 RF I DNA to these reagents were discussed.     

Effect of Chloramphenicol on the DNA Synthesis of Bacteriophage ϕX174

In bacteriophage ?X174 infection, the net synthesis of replicative form DNA ceased between 15 and 20 min after infection. When 30 μg of chloramphenicol/ml was added, net RF synthesis, however, continued beyond the normal time and level of turn-off. Experiments with ?X174 mutants unable to synthesize single-stranded DNA showed that a protein synthesis was required for the cessation of net RF synthesis and the protein was synthesized between 10 and 15 min after infection.     

Stimulation of autolysis by adsorption of bacteriophage ØX174 to isolated cell walls

Adsorption of ØX174 to cell wall fragments fromE. coli labeled with³H-diaminopimel ic acid results in limited degradation of murein due to stimulation of autolysis. Pure murein was not degraded by ØX174.     

Location of the 5-Methylcytosine Group on the Bacteriophage φX174 Genome

Bacteriophage phiX174 DNA was labeled in vivo with [methyl-(3)H]methionine. The methyl-labeled progeny DNA was extracted from purified bacteriophage phiX174 particles and was used as template for in vitro synthesis of the complementary strand in the presence of the nucleoside triphosphates and Escherichia coli polymerase I. The resultant replicative form DNA was then cleaved, in separate experiments, with restriction endonucleases from Haemophilus influenzae and H. aegyptius. The DNA fragments were analyzed by polyacrylamide gel electrophoresis. It is concluded that the single methylcytosine in the viral DNA is located in a specific region of the phiX174 genome, very likely in gene H.     

Experimental evolution and genome sequencing reveal variation in levels of clonal interference in large populations of bacteriophage φX174

Background

The first step of GPI anchor biosynthesis is catalyzed by PIG-A, an enzyme that transfers N -acetylglucosamine from UDP- N -acetylglucosamine to phosphatidylinositol. This protein is present in all eukaryotic organisms ranging from protozoa to higher mammals, as part of a larger complex of five to six 'accessory' proteins whose individual roles in the glycosyltransferase reaction are as yet unclear. The PIG-A gene has been shown to be an essential gene in various eukaryotes. In humans, mutations in the protein have been associated with paroxysomal noctural hemoglobuinuria. The corresponding PIG-A gene has also been recently identified in the genome of many archaeabacteria although genes of the accessory proteins have not been discovered in them. The present study explores the evolution of PIG-A and the phylogenetic relationship between this protein and other glycosyltransferases.

Results

In this paper we show that out of the twelve conserved motifs identified by us eleven are exclusively present in PIG-A and, therefore, can be used as markers to identify PIG-A from newly sequenced genomes. Three of these motifs are absent in the primitive eukaryote, G. lamblia. Sequence analyses show that seven of these conserved motifs are present in prokaryote and archaeal counterparts in rudimentary forms and can be used to differentiate PIG-A proteins from glycosyltransferases. Using partial least square regression analysis and data involving presence or absence of motifs in a range of PIG-A and glycosyltransferases we show that (i) PIG-A may have evolved from prokaryotic glycosyltransferases and lipopolysaccharide synthases, members of the GT4 family of glycosyltransferases and (ii) it is possible to uniquely classify PIG-A proteins versus glycosyltransferases.

Conclusion

Besides identifying unique motifs and showing that PIG-A protein from G. lamblia and some putative PIG-A proteins from archaebacteria are evolutionarily closer to glycosyltransferases, these studies provide a new method for identification and classification of PIG-A proteins.     

Influence of the Chlamydia pneumoniae AR39 bacteriophage ϕCPAR39 on chlamydial inclusion morphology

The human respiratory tract pathogen Chlamydia pneumoniae AR39 is naturally infected by the bacteriophage ?CPAR39. The phage genome encodes six ORFs, [ORF8, ORF4, ORF5, and viral protein (VP) 1, VP2 and VP3]. To study the growth of the phage, antibodies were generated to VP1 and used to investigate the ?CPAR39 infection. Using immunofluorescence laser confocal microscopy and two-dimensional gel electrophoresis, we investigated the ?CPAR39 infection of C. pneumoniae AR39. It was observed that ?CPAR39 infection differentially suppressed the C. pneumoniae protein synthesis as the polymorphic membrane protein 10 and the secreted chlamydial protein Cpn0796 was hardly expressed while the secreted chlamydial protein Cpaf was expressed, but not secreted. The inclusion membrane protein, IncA, was demonstrated to surround the phage-infected abnormal reticulate bodies (RB) as well as being located in the inclusion membrane. As IncA is secreted by the type 3 secretion (T3S) system, it is likely that the T3S is disrupted in the phage-infected chlamydiae such that it accumulates around the infected RB.