Process of Infection with Bacteriophage φX174: XXXV. Cistron VIII

Twenty-two new amber and ochre mutants of phiX174 were isolated and classified into complementation groups. Three ochre mutants gave positive complementation tests with reference mutants in the seven previously defined groups and thus represent an eighth cistron. Studies of the physiology of infection in the nonpermissive condition for mutants in cistron VIII yielded the following information. (i) Replicative-form synthesis proceeds at a normal rate, and is turned off at the usual time. (ii) Synthesis of single-stranded deoxyribonucleic acid (DNA) is delayed until nearly 40 min after infection (in the absence of lysis), at which time a slow synthesis of infectious phage particles commences. The synthesis of infectious particles at late times is interpreted as a consequence of "leakage," and indicates that the cistron VIII product is required in very small quantities. (iii) During the normal period of single-strand synthesis, most of the replicative-form DNA is found in a form with properties similar to those of the transient intermediates of single-strand DNA synthesized during normal infection.     

Process of Infection with Bacteriophage φX174: XXIV. New Type of Temperature-sensitive Mutant

A group of temperature-sensitive mutants of phiX174 has been isolated which can go through a single, normal one-step growth cycle at 40 C but fail to form plaques at this temperature. Such mutants fail to initiate a second cycle at 40 C; however they can gain the capacity to infect at 40 C, upon incubation for 10 min in broth at 30 C. In regaining the ability to infect, the phage appear to undergo a temperature-dependent conformational alteration. The inverse process, a reversible loss of ability to infect at 40 C, is observed when such phage produced at 30 C are incubated for 2 hr at 40 C. The defect in initiation of a second cycle of infection appears to be in the injection of viral deoxyribonucleic acid. A two-step complementation test has been used to identify the cistron coding for the affected function. Such mutants are also unusually sensitive to an irreversible thermal inactivation when incubated at 40 C.     

Process of Infection with Bacteriophage φX174: XXXIV. Kinetics of the Attachment and Eclipse Steps of the Infection

The products of phiX cistrons II, III, and VII are demonstrated to affect the attachment of the phage to its host Escherichia coli C; therefore, by inference, these cistrons influence, directly or indirectly, the structure of proteins in the virus particle. Two of the mutations which alter attachment kinetics, ts79 in cistron III and h in cistron VII, also affect the electrophoretic mobility of the virus and emphasize the role of charge in the attachment interaction with the host. The kinetics for attached phage to go into "eclipse" are first-order and biphasic; about 85% of the phage eclipse at one rate (k(e) = 0.86 min(-1)) and the remainder do so at a distinctly lower rate (k(e) = 0.21 min(-1)). No phiX cistrons yet identified affect the eclipse process. The lowest temperature at which eclipse is detected is 19 C. The Arrhenius activation energy for phage eclipse has the high value of 36.6 kcal/mole, indicating the cooperative nature of the event.     

Process of Infection with Bacteriophage φX174: XXXIII. Templates for the Synthesis of Single-Stranded Deoxyribonucleic Acid

The origin of the templates for the synthesis of X174 progeny single-stranded deoxyribonucleic acid was studied by means of the mutagenic activity associated with the decay of incorporated ³H-labeled 5-cytosine. The results indicate that the single-strand synthesis occurs in an asymmetric semiconservative manner using as template the complementary strands of the pool of replicative from molecules accumulated during the eclipse period. These complementary strands are repeatedly used as templates, and there is no detectable preferential use of complementary strand templates made early in the eclipse versus those made late.     

Second-Site Suppressors of a Cold-Sensitive Prohead Accessory Protein of Bacteriophage φX174

This study describes the isolation of second-site suppressors which correct for the defects associated with cold-sensitive (cs) prohead accessory proteins of bacteriophage phi X174. Five phenotypically different suppressors were isolated. Three of these suppressors confer novel temperature-sensitive (ts) phenotypes. They were unable to complement a ts mutation in gene F which encodes the major coat protein of the phage. All five suppressor mutations confer nucleotide changes in the gene F DNA sequence. These changes define four amino acid sites in the gene F protein. Three suppressor mutations placed into an otherwise wild-type background display a cold resistant phenotype in liquid culture infections when compared to a wild-type phi X174 control.     

The Process of Infection with Bacteriophage ?X174 XIII. Evidence for an Essential Bacterial “Site”

The burst of a starved bacterium infected with several øX174 bacteriophage was usually found to contain genetic traits of only one of the possible parents; less often, two phage multiplied in the same host cell. Unstarved cells, in contrast, supported the growth of at least four parental phage types. The unproductive phage seemed to be able to undergo the intracellular transition from parental single-stranded deoxyribonucleic acid to the double-stranded “replicative form” (RF). These results are taken to mean that some bacterial factor required for a step between RF synthesis and maturation of progeny is limited in starved cells.     

Second-Site Suppressors of a Cold-Sensitive External Scaffolding Protein of Bacteriophage φX174

This report describes the isolation and characterization of second-site suppressors of a cold-sensitive (cs) external scaffolding protein, gpD, of bacteriophage X174. Seven genetically distinct suppressors were isolated. Six of them are located in gene F which encodes the major coat protein of the virus. The seventh is located in gene J which encodes the DNA-binding protein. A subset of the suppressors are trans-acting. These second-site suppressors do not exhibit allele specificity; they are able to suppress defects associated with a csD protein for which they were not selected. The initial characterization of the second-site suppressors and their locations within the major coat protein suggest that the mechanism of suppression may involve both structural and stoichiometric phenomena.     

Mode of Host Cell Penetration by Bacteriophage φX174

Bacteriophage phiX174 is an icosahedral phage which attaches to host cells without the aid of a complex tail assembly. When phiX174 was mixed with cell walls isolated from the bacterial host, the virions attached to the wall fragments and the phage deoxyribonucleic acid (DNA) was released. Attachment was prevented if the cell walls were treated with chloroform. Release of phage DNA, but not viral attachment, was prevented if the cell walls were incubated with lysozyme or if the virions were inactivated with formaldehyde. Treatment of the cell walls with lysozyme released structures which were of uniform size (6.5 by 25 nm). These structures attached phiX174 at the tip of one of its 12 vertices, but the viral DNA was not released. The virions attached to these structures were oriented with their fivefold axis of symmetry normal to the long axis of the structure. No virions were attached to these structures by more than one vertex. Freeze-etch preparations of phiX174 adsorbed to intact bacteria showed that the virions were submerged to one half their diameter into the host cell wall, and the fivefold axis of symmetry was normal to the cell surface. A second cell could not be attached to the outwardly facing vertex of the adsorbed phage and thus the phage could not cross-link two cells. When the virions were labeled with (3)H-leucine, purified, and adsorbed to Escherichia coli cells, about 15% of the radioactivity was recovered as low-molecular-weight material from spheroplasts formed by lysozyme-ethylenediaminetetraacetic acid. Other experiments revealed that about 7% of the total parental virus protein label could be recovered in newly formed progeny virus.     

Cold-Sensitive Mutants of Bacteriophage φX174. II. Comparison of Two Cold-Sensitive Mutants

Cold-sensitive bacteriophage phiX174 mutants, another class of conditional lethals, were examined with regard to growth parameters, DNA synthesis, and particle properties. Two mutants, cs70 and cs82, were examined. Mutant cs70 was eclipse defective, showing altered eclipse kinetics at permissive temperature (40 C) and failing entirely to eclipse at restrictive temperature (25 C). Mutant cs70 replicated well at 25 C if allowed prior eclipse at 40 C. Mutant cs82 had wild-type eclipse at both temperatures but was defective in single-strand synthesis at 25 C, which led to delayed progeny phage appearance, decreased progeny phage synthesis rate, and greatly reduced burst size. The cs82 block could not be bypassed by temperature shift. Since complementation analysis of cs70 and cs82 was not feasible due to the unique properties of these mutants, those phiX174 properties affected by the virus coat were examined as an index of a mutation in a coat protein gene. Mutant cs70 had aberrant attachment kinetics at both 25 C and 40 C, evidence of a coat protein alteration. Mutant cs70 also exhibited significantly decreased thermal stability, further evidence of an altered virus structure. Mutant cs82 had increased thermal stability, but the difference was not sufficient to allow unequivocal assignment of this mutant to a coat protein gene. Both mutants had wild-type antiserum inactivation and host range, although cs70 was subject to less of (low-level) plating restriction by endogenous F(+) factors.     

Replication of Bacteriophage φX174 in a Temperature-Sensitive Deoxyribonucleic Acid Host Cell

Bacteriophage phiX174 is unable to replicate in Escherichia coli t3 at the restrictive temperature. However, if progeny phage synthesis is initiated at the permissive temperature, it will continue after a shift to the restrictive temperature.     

Requirement of Protein Synthesis for Bacteriophage φX174 Superinfection Exclusion

Within 5 to 10 min at 37 C, bacteria infected by bacteriophage phiX174 acquire the ability to exclude superinfecting phiX particles from reproducing themselves. The superinfecting phage are blocked at a stage prior to synthesis of the parental replicative form molecule; the superinfecting deoxyribonucleic acid remains as intact (infective) single strands. Establishment of superinfection exclusion and its maintenance require protein synthesis.     

Photodynamic Inactivation of Antigenic Determinants of Single-Stranded DNA Bacteriophage φX174

Bacteriophage phiX174 when photodynamically inactivated (i.e., when rendered unable to produce plaques as a result of exposure to visible light in air in the presence of proflavine) progressively lost their capacity to bind efficiently with homologous antiserum. Such loss of serum-blocking power was evident with heat-inactivated but not with UV-irradiated phage. The ability of the phages to adsorb to host cells, however, remained practically unaltered even after photodynamic inactivation. It thus appears that photodynamic damages in the so-called "jacket" component of the phiX174 coat proteins are partly responsible for the loss of plaque-forming ability, whereas the "spikes" are either poor antigens or insensitive to photodynamic treatment.     

Growth of a Capsid Mutant of Bacteriophage φX174 in a Temperature-Sensitive Strain of Escherichia coli

A capsid mutant of X174 is capable of forming replicative form and synthesizing single strands at the restrictive temperature in a dnaB mutant of Escherichia coli. Under similar conditions, the wild-type bacteriophage is incapable of either step in viral synthesis.     

Specific Endonuclease R Fragments of Bacteriophage φX174 Deoxyribonucleic Acid

The restriction enzyme from Hemophilus influenzae, endonuclease R, cleaves phiX174 replicative-form deoxyribonucleic acid (DNA) into at least 13 specific limit fragments. The molecular weights of 12 of the fragments have been estimated by gel electrophoresis and electron microscopy. Using the genetic assay for small fragments of phiX DNA, we have shown that we can salvage markers from the endonuclease R phiX-RF fragments.     

Replication of Bacteriophage φX174 DNA in a Temperature-Sensitive dnaE Mutant of Escherichia coli C

Bacteriophage phiX174 cannot grow in a temperature-sensitive dnaE (DNA polymerase III) mutant of Escherichia coli C at the nonpermissive temperature. The inability to grow is the result of inhibition of virus DNA synthesis. The synthesis of the parental replicative form is unaffected, but the replication of the replicative form and the synthesis of the single-stranded virus DNA are inhibited.     

Replication of Bacteriophage φX174 DNA in a Temperature-Sensitive dnaC Mutant of Escherichia coli C

Bacteriophage phiX174 cannot grow in a temperature-sensitive dnaC mutant of Escherichia coli C at the nonpermissive temperature. The inability to grow is the result of inhibition of virus DNA synthesis. Parental replicative form synthesis is not temperature sensitive. Single-stranded virus DNA continues to be synthesized for at least 45 min after shifting to the nonpermissive temperature late in infection. In contrast, the replication of the replicative form terminates within 5 min after shifting to the nonpermissive temperature.     

Genetic Assay for Small Fragments of Bacteriophage φX174 Deoxyribonucleic Acid

The double-stranded replicative form deoxyribonucleic acid (RF-DNA) of bacteriophage phiX174 was fragmented by pancreatic deoxyribonuclease, and the complementary strand fragments were then annealed to intact viral single strands. When such complexes infected Escherichia coli spheroplasts, some of the progeny virus bore genetic markers derived from the RF-DNA fragments. In this way, genetic markers have been salvaged from DNA fragments less than 50 nucleotides in length. This method is potentially useful as a specific assay to aid in the purification of genetically defined DNA fragments and also as a mechanism for the incorporation of small chemically synthesized DNA sequences into viral genomes.     

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.