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.     

Construction of viable and lethal mutations in the origin of bacteriophage 'phi' X174 using synthetic oligodeoxyribonucleotides

Six different synthetic deoxyhexadecamers complementary to the origin of bacteriophage φX174, corresponding to nucleotides 4299 to 4314, except for one preselected nucleotide change were used as primers for DNA synthesis on wild-type φX² DNA as a template. DNA synthesis was performed with Escherichia coli DNA polymerase I (Klenow fragment) in the presence of DNA ligase. Heteroduplex RFIV DNA was isolated and, after limited digestion with DNAase I, complementary strands containing the mutant primers were isolated. The biological activity of these complementary strands was assayed in spheroplasts. Spheroplasts were made from E. coli K58 ung^? (uracil N-glycosylase) to prevent degradation of the complementary strands caused by uracil incorporation (Baas et al., 1980a).Using (5′-³²P) end-labeled primers, it was shown that all tested DNA polymerase preparations, including phage T4 DNA polymerase, contained variable amounts of 5′ → 3′ exonuclease activity. This nick translation activity may result in removal of the mutation in the primers, and therefore in isolation of wild-type complementary DNA instead of mutant complementary DNA.Restriction enzyme analysis of completed RFIV DNA showed that the primers can initiate DNA synthesis at more than one place on the φX174 genome. These complications result in a mixed population of complementary strand DNAs synthesized in vitro. Nevertheless, the desired mutants were picked up with high frequency using a selection test that is based on the difference in ultraviolet light sensitivity of homoduplex and heteroduplex φX174 RF DNA. Heteroduplex φX174 RF DNA is two to three times more sensitive to ultraviolet light irradiation than is homoduplex φX174 RF DNA (Baas &; Jansz, 1971,1972). Phage DNA derived from single plaque lysates of two of the six mutant complementary strand DNA preparations yielded, after annealing with wild-type complementary strand DNA, heteroduplex DNA with high frequency. DNA sequence analysis in the origin region of RF DNA obtained from these two phage preparations revealed the presence of the expected mutation. RFI DNA of these two origin mutants was nicked by φX174 gene A protein in the same way as wild-type φX174 RFI DNA.Phage DNA derived from single plaque lysates of the other four mutant complementary strand DNA preparations yielded exclusively homoduplex DNA after annealing with wild-type complementary strand DNA. It is concluded that priming with these deoxyhexadecamers resulted in the synthesis of complementary φX174 DNA with lethal mutations. The implications of these results, the construction of two silent, viable φX174 origin mutants and the failure to detect four others, for the initiation mechanism of φX174 RF DNA replication are discussed.     

Mapping of recognition sites for the restriction endonuclease from Escherichia coli K12 on bacteriophage PM2 DNA.

Several mutations in gene B of phage S13 appear to shorten the B protein by elimination of an N-terminal fragment, without destroying the B protein function. The shortened B protein resulting from each of these mutations can block the unique DNA-nicking properties of the S13 gene A protein. Because of the block in gene A function, normal gene B protein may have a function in phage DNA synthesis in addition to its known role in catalyzing capsid assembly.From gel electrophoresis the mutant B protein is estimated to be shorter than the normal S13 B protein by 1720 ± 70 daltons and is therefore believed to be an internal reinitiation fragment. The reinitiated fragments are functional and are made in about twice the amount of the normal B protein.The phage mutants which yield the reinitiation fragments are double mutants, each phage containing the same gene B nonsense mutation and each appearing to contain a different compensating gene B mutation. Various data support the assumption that the compensating mutations are frame-shifts, including the fact that suppression does not restore the normal-sized B protein. The reinitiation is assumed to occur at a pre-existing out-of-phase initiator codon, near the nonsense triplet; the correct reading frame would then be restored by each of the several different compensating mutations.The position of the normal S13 B protein in the gel electrophoresis pattern has been located both by elimination and shifting of the B peak, using appropriate amber mutants. The molecular weight of the S13 B protein is about 17,200, and is 2100 daltons less than the B protein of phage φX174; the S13 B protein can nevertheless substitute for the φX 174 B protein. Thus substantial portions of the B protein can be deleted without destroying its function.     

Viral DNA-synthesizing intermediate complex isolated during assembly of bacteriophage phi X174.

A DNA protein complex that is a precursor of mature phi X174 phage was isolated. The complex sedimented with an S value of 50 in a sucrose gradient and contained phage DNA consisting of a replicative form molecule with an extended tail of single-stranded viral DNA. The viral-strand DNA ranged from one to two genomes in length. Proteins coded on the phi X174 genome as well as the host genome were associated with the viral DNA in the 50S precursor complex. Our results indicated that both viral DNA synthesis and cleavage of the growing viral-strand DNA occurred in the 50S complex.     

Figure-8 configuration of dimers of S13 and φX174 replicative form DNA

Evidence from electron microscopy of the replicative form of S13 and φX174 DNA shows the presence of a “figure-8” configuration. This species consists of two monomer length and one dimer length circular strands in covalently closed circular form and containing a fused junction that divides the molecule into two equal circular segments. Its existence is supported by the demonstration that it is converted by digestion with the restriction endonuclease of Hemophilus influenzae strain Rd to α- and X-shaped forms that retain the fused junction, and by examination by electron microscopy in the presence of ethidium bromide, which eliminates tangling and accidental overlays of parts of the DNA molecules. Kgure-8s are present to the extent of about 5% of the dimers present in replicative form DNA. They are proposed to be intermediates in genetic recombination in S13 and φX174.     

Electron microscope study of the structures of the Bacillus subtilis prophages, SPO2 and phi105

Circular duplex structures of the correct length are observed in the electron microscope in hybridization mixtures of lysogen DNA and mature phage DNA for the case of the temperate Bacillus subtilis bacteriophage SPO2. This result shows that the sequence order of the prophage is a circular permutation of that of the mature phage. By making heteroduplexes of prophage DNA with that of the SPO2 deletion mutants, R90 and S25, the att site of the phage has been mapped at 61.2 ± 0.6% from one end of the mature phage DNA, which has a length of 38,600 base pairs. In the same co-ordinate system, the R90 deletion extends from 58.9 ± 0.7 to 66.8 ± 0.8% on the SPO2 chromosome, whereas the S25 deletion extends from 63.2 ± 0.6 to 66.9 ± 0.7%. In similar experiments with lysogen and mature phage DNA's of the temperate B. subtilis phage, φ105, no circular structures were seen. This result shows that the sequence order in the prophage and the phage are colinear, without circular permutation.     

A technique for mapping transfer RNA genes by electron microscopy of hybrids of ferritin-labeled transfer RNA and DNA: the phi-80hpsu+3-system

A method for mapping transfer RNA genes on single strands of DNA is described. tRNA is covalently coupled to the electron-opaque label, ferritin. The ferritinlabeled tRNA, Fer-tRNA, is hybridized to a single strand of DNA, or to a single- strand region of a DNA in a heteroduplex. The sites where the Fer-RNA binds to the complementary sequence on the DNA are then mapped by electron microscopy. Several alternative coupling procedures are described (see Fig. 1). In HzI a — COCH₂Br group is attached to ferritin by acylation. 3'-Oxidized tRNA is joined to HSRCONHNH₂ by hydrazone formation. Ferritin is then coupled to tRNA by reaction of the CBr and SH bonds. In the BI procedure a lysine amino group of ferritin is coupled by Schiff base formation with 3'-oxidized RNA. The conjugate is stabilized by borohydride reduction. In the BII procedure, a —COCH₂Br group is attached to ferritin. (H₂NCH₂CH₂S—)₂ is coupled to oxidized tRNA by Schiff base formation and borohydride reduction. An SH group is exposed by reduction. This HS-tRNA is coupled to a —COCH₂Br group attached to ferritin. All the procedures work but BII is recommended. Methods for purifying the Fer-tRNA and the Fer-tRNA-DNA hybrid are described. For the transducing phages, φ80hpsu^+,?_III and φ80hpsu^?_III, the DNA molecules each carry a piece of bacterial DNA of length 0·066±0·007 λ unit (3100 nucleotide pairs; we find the length of λ is 8·99 φX174 units) replacing a piece of phage DNA of φ80h of length 0·045±0·005 λ unit. The left junction of this bacterial DNA with phage DNA (referred to as P-B′) is at or close to the att site. The two tandem tyrosine genes of φ80hpsu^+,?_III and the single tRNA gene of φ80hpsu^?_III have been mapped at a position 1100 nucleotides to the right of the left (P·B′) junction of phage DNA and bacterial DNA, by hybridizing Escherichia coli Fer-tRNA to φ80hpsu_III/φ80h heteroduplexes. The separation of the two ferritin labels in φ80hpsu^+,?_III hybrids gives 140±20 nucleotides as the size of a single tyrosine tRNA gene.     

The mechanism of replication of phi X174 single-stranded DNA. II. The role of viral proteins

We have studied the replication of φX174 DNA in Escherichia coli infected with various amber mutants (cistrons I to VII) of φX. Previous research showing that some of these mutants are able to form replicative form (RF) DNA but are unable to produce net amounts of viral progeny single-stranded DNA has been confirmed and extended. Evidence is presented that a defect in any one of four viral cistrons prevents the asymmetric replication of the RF to produce progeny viral DNA. At least four virus-coded proteins, three of which are part of the mature virion, must be present before single-stranded DNA synthesis can even be initiated; the possibility that single-stranded DNA is made and then degraded or converted to RF is eliminated. Mutants in one cistron (II) do permit the asymmetric replication of RF at late times, but the displaced viral strand is incorporated into a defective particle and subsequently may be partially degraded. Both RFI (superhelix) and RFII are present in roughly comparable amounts throughout the normal latent period in infections with wild-type phage or any of the phage mutants.     

Phi X 174 gene A protein does not cleave at a mouse mitochondrial DNA sequence homologous to the phi X and G4 cleavage site

The light strand origin of replication of mouse mitochondrial DNA contains a 30-nucleotide region which is 60% homologous to the 30-nucleotide conserved sequence in φX174 and G4 viral DNAs known to contain the viral gene A protein cleavage site. Gene A protein does not cleave closed circular mouse mitochondrial DNA under conditions in which φX174 closed circular DNA is cleaved.     

Involvement of a Cell Envelope Component of Escherichia coli in the Early Stages of Infection with Bacteriophage ϕX174

Envelope fraction I prepared from a ?X174 sensitive host, KD4301, showed a strong eclipsing activity, while the lipopolysaccharide (LPS) fraction showed a weak activity. The eclipsing activity in envelope fraction I was sensitive to heat treatment, while that in the LPS fraction was insensitive. When the complete phage particles (114S) were treated with envelope fraction I, the eclipsed particles (70S) and a rapidly sedimenting component were obtained, but when they were treated with LPS, only 70S eclipsed particles were obtained. Electron microscopic observation showed that there were two types of eclipsed particles formed on treatment with fraction I; in one of them phage DNA was extruded from the phage particles as a thick bundle, and in the other more than 95% of the phage DNA was extruded from the phage particles. The rapidly sedimenting component was the membrane-eclipsed particle complex. LPS gave only one type of eclipsed particles in which DNA was extruded as a thick bundle. These results indicate that a heat labile component in the cell envelopes other than LPS is involved in the extrusion of ?X174 DNA.     

Comparison of partial denaturation maps with the known sequence of simian virus 40 and phi X174 replicative form DNA.

Electron microscope partial denaturation maps of two viral DNAs, simian virus 40 and φX174 replicative form, have been obtained. A simple computer program has been developed to predict denaturation maps from any given DNA sequence, based on the percentage of A · T base-pairs along the molecule. Maps constructed from the SV40 DNA and φX174 replicative form DNA base sequence show a good correlation with the experimental maps. The results show that the regions of a DNA molecule that denature first are, in fact, those regions with the highest content of adenine and thymine base-pairs.     

A novel single strand endonuclease specific for ØX174 DNA

A highly specific endonuclease activity, presumably involving one or both of the products of the ØX174 gene A, has been isolated from ØX174-infected $\text{E. coli}$ by DNA-cellulose chromatography. The enzyme is not present in uninfected cells and binds extremely tightly to DNA-cellulose. It extensively degrades ØX174 viral DNA but does not degrade the circular or linear forms of single stranded viral DNA of either M13, an unrelated filamentous phage, or G4, a ØX-type phage.     

Atomic Structure of the Degraded Procapsid Particle of the Bacteriophage G4: Induced Structural Changes in the Presence of Calcium Ions and Functional Implications

Bacteriophage G4 and φX174 are members of the Microviridae family. The degree of similarity of the structural proteins ranges from 66% identity of the F protein to 40% identity of the G protein. The atomic structure of the φX174 virion had previously been determined by X-ray crystallography. Bacteriophage G4 procapsids, consisting of the structural proteins F, G, D, B, H, and small traces of J but no DNA, were set up for crystallization. However, the resultant crystals were of degraded procapsid particles, which had lost the assembly scaffolding proteins D and B, resulting in particles that resembled empty virions.The structure of the degraded G4 procapsid has been determined to 3.0 Å resolution. The particles crystallized in the hexagonal space groupP6₃22 with unit cell dimensionsa=b=414.2(5) Å andc=263.0(3) Å. The diffraction data were collected at the Cornell High Energy Synchrotron Source (CHESS) on film and image plates using oscillation photography. Packing considerations indicated there were two particles per unit cell. A self-rotation function confirmed that the particles were positioned on 32 point group special positions in the unit cell. Initial phases were calculated to 6 Å resolution, based on the known φX174 virion model. Phase information was then extended in steps to 3.0 Å resolution by molecular replacement electron density modification and particle envelope generation.The resulting electron density map was readily interpretable in terms of the F and G polypeptides, as occur in the mature capsid of φX174. In a few regions of the electron density map there were inconsistencies between the density and the published amino acid sequence. Redetermining the amino acid sequence confirmed that the density was correct. The r.m.s. deviation between the C^αbackbone of the mature capsid of φX174 and the degraded G4 procapsid was 0.36 Å for the F protein and 1.38 Å for the G protein. This is consistent with the greater conservation of the F protein compared to the G protein sequences among members of the Microviridae family. Functionally important features between φX174 and G4 had greater conservation.Calcium ions (Ca^{2 +}) were shown to bind to G4 at a general site located near the icosahedral 3-fold axis on the F protein capsid, equivalent to sites found previously in φX174. Binding of Ca^{2 +}also caused the ordering of the conserved region of the DNA binding protein J, which was present in the degraded procapsid particle in the absence of DNA.     

In vivo methylation of replicating bacteriophage phi chi174 DNA

The pattern of DNA methylation during the infection of Escherichia coli C cells with bacteriophage φX174, has been studied. In vivo methylated DNA was isolated and analyzed using the following techniques: velocity sedimentation through neutral and alkaline sucrose gradients, isopycnic analysis, chromatography on benzoylated DBAE-cellulose columns and specific enzymatic digestion. All these analytical methods indicated that the DNA molecules that are methylated during the process of phage φX DNA replication are the replicating intermediates composed of a circular complementary strand and a viral strand larger than one genome length. It is concluded that methylation occurs on the nascent DNA strand of the replicating intermediates involved in the synthesis of progeny single-stranded DNA.     

DNA synthesis in nucleotide-permeable Escherichia coli cells. VII. Conversion of phi chi-174 DNA to its replicative form

On incubation with deoxynucleoside triphosphates and rATP, ether-treated (nucleotide-permeable) cells convert the single-stranded DNA of adsorbed bacteriophage φX174 particles to the double-stranded replicative forms. The main final product is the doubly-closed replicative form, RFI; a minor product is the relaxed form II. Interruptions in the nascent complementary strand of the viral DNA result in pieces corresponding to 5 to 10% of the unit length of the viral DNA. Pieces of similar size were previously seen in studies of the replication synthesis of Escherichia, coli DNA in ether-treated cells. Since the conversion of the single-stranded φX174 DNA to replicative form is known to be mediated entirely by host factors, it is argued that the viral single strands are replicated by macromolecular factors involed in the replication of E. coli DNA and that this is the reason why new φX174 DNA appears in short pieces. Possible consequences of this interpretation for an understanding of duplex replication are discussed. The joining of the short pieces of complementary φX174 DNA is inhibited at low deoxynucleoside triphosphate concentration (1 μM) but not by nicotinamide mononucleotide, which inhibits the NAD-dependent DNA ligase and blocks the conversion of RFII to RFI in ether-treated cells. The results are discussed with respect to previous studies on cell-DNA synthesis (Geider, 1972). It is argued that there are two polynucleotide joining mechanisms, of which only one requires NAD-dependent ligase action.     

Structure of an intermediate in the replication of bacteriophage φX174 deoxyribonucleic acid: The initiation site for DNA replication

Replicative form DNA composed of a closed complementary strand and a discontinuous viral strand has been isolated from cells infected with bacteriophage φX174 during the period of single-strand DNA synthesis. This RFII DNA was degraded by the restriction enzyme from Hemophilus influenzae, endonuclease R, and the products analyzed by polyacrylamide gel electrophoresis. The results indicate that there are two types of discontinuity in the viral strands of these molecules: (1) 65% of the molecules contain a gap, which causes a discrete increase in mobility of a specific restriction enzyme fragment, R3. This gap can be selectively repaired with Escherichia coli DNA polymerase I and nucleoside triphosphates, but the molecules are not converted to RFI by addition of E. coli polynueleotide ligase to the reaction mixture. Approximately 30 moles of radioactive TTP are incorporated per mole of RF DNA. (2) 35% of the RF molecules contain a discontinuity, which does not result in a detectable change in mobility of any restriction enzyme fragment. These RF molecules can be converted to RFI by the action of ligase and polymerase I in the presence of nucleoside triphosphates, with incorporation of only approximately one mole of radioactive TTP, specifically into fragment R3, per mole of RF DNA.When the reaction of late RFII DNA and polymerase I is allowed to proceed beyond the repair of the discontinuity, radioactive nucleotides are incorporated into endonuclease R fragments adjacent to R3 in the 5′ → 3′ direction. This technique was utilized to determine a partial order of endonuclease R fragments in φX174.These results suggest that the synthesis of single-strand DNA is initiated from a unique point in cistron A and proceeds clockwise round the φX174 genetic map (cistron order: ABCDEFGH). A comparison of these results with other studies on φX174 suggests that DNA synthesis in all stages of φX174 replication may be initiated from a specific locus on the genome, at or near cistron A.     

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA.

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.