Mechanism of adsorption and eclipse of bacteriophage phi X174. II. Attachment and eclipse with isolated Escherichia coli cell wall lipopolysaccharide

Asymmetry in icosahedral viruses

Although icosahedral viruses have obvious and highly symmetrical features, asymmetric structural elements are also present. Asymmetric features may be inherent since the genome and location of minor capsid proteins are typically incorporated without adhering to icosahedral symmetry. Asymmetry also develops during the virus life cycle in order to accomplish key functions such as genome packaging, release, and organization. However, resolving asymmetric features complicates image processing during single-particle cryoEM analysis. This review summarizes the current state of knowledge regarding asymmetric structural features with specific examples drawn from members of picornaviridae, parvoviradae, microviradae, and leviviridae.

Structural changes of tailless bacteriophage ΦX174 during penetration of bacterial cell walls

Unlike tailed bacteriophages, which use a preformed tail for transporting their genomes into a host bacterium, the ssDNA bacteriophage ΦX174 is tailless. Using cryo-electron microscopy and time-resolved small-angle X-ray scattering, we show that lipopolysaccharides (LPS) form bilayers that interact with ΦX174 at an icosahedral fivefold vertex and induce single-stranded (ss) DNA genome ejection. The structures of ΦX174 complexed with LPS have been determined for the pre- and post-ssDNA ejection states. The ejection is initiated by the loss of the G protein spike that encounters the LPS, followed by conformational changes of two polypeptide loops on the major capsid F proteins. One of these loops mediates viral attachment, and the other participates in making the fivefold channel at the vertex contacting the LPS.

Identification and characterization of a novel flagellum-dependent Salmonella-infecting bacteriophage, iEPS5

A novel flagellatropic phage of Salmonella enterica serovar Typhimurium, called iEPS5, was isolated and characterized. iEPS5 has an icosahedral head and a long noncontractile tail with a tail fiber. Genome sequencing revealed a double-stranded DNA of 59,254 bp having 73 open reading frames (ORFs). To identify the receptor for iEPS5, Tn5 transposon insertion mutants of S. Typhimurium SL1344 that were resistant to the phage were isolated. All of the phage-resistant mutants were found to have mutations in genes involved in flagellar formation, suggesting that the flagellum is the adsorption target of this phage. Analysis of phage infection using the ΔmotA mutant, which is flagellated but nonmotile, demonstrated the requirement of flagellar rotation for iEPS5 infection. Further analysis of phage infection using the ΔcheY mutant revealed that iEPS5 could infect host bacteria only when the flagellum is rotating counterclockwise (CCW). These results suggested that the CCW-rotating flagellar filament is essential for phage adsorption and required for successful infection by iEPS5. In contrast to the well-studied flagellatropic phage Chi, iEPS5 cannot infect the ΔfliK mutant that makes a polyhook without a flagellar filament, suggesting that these two flagellatropic phages utilize different infection mechanisms. Here, we present evidence that iEPS5 injects its DNA into the flagellar filament for infection by assessing DNA transfer from SYBR gold-labeled iEPS5 to the host bacteria.

Synergistic action of gentamicin and bacteriophage in a continuous culture population of Staphylococcus aureus

With the increasing frequency of antibiotic resistance and the decreasing frequency of new antibiotics entering the market, interest has returned to developing bacteriophage as a therapeutic agent. Acceptance of phage therapy, however, is limited by the unknown pharmacodynamics of a replicating agent, as well as the potential for the evolution of resistant bacteria. One way to overcome some of these limitations is to incorporate phage and antibiotics into a dual therapy regimen; however, this increases the complexity of the pharmacodynamics. The aim of this study is to develop an experimental system to evaluate the pharmacodynamics of dual phage-drug therapy. A continuous culture system for Staphylococcus aureus is used to simulate the pharmacokinetics of periodic antibiotic dosing alone and in combination with lytic phage. A computer model representation of the system allows further evaluation of the conditions governing the observed pharmacodynamics. The results of this experimental/modeling approach suggest that dual therapy can be more efficacious than single therapies, particularly if there is an overlap in the physiological pathways targeted by the individual agents. In this case, treatment with gentamicin induces a population of cells with a strong aggregation phenotype. These aggregators also have an increased ability to form biofilm, which is a well-known, non-genetic mechanism of drug resistance. However, the aggregators are also more susceptible than the parental strain to the action of the phage. Thus, dual treatment with gentamicin and phage resulted in lower final cell densities than either treatment alone. Unlike in the phage-only treatment, phage-resistant isolates were not detected in the dual treatment.

Coevolution of bacteria and their viruses

Coevolution between bacteria and bacteriophages can be characterized as an infinitive constant evolutionary battle (phage-host arm race), which starts during phage adsorption and penetration into host cell, continues during phage replication inside the cells, and remains preserved also during prophage lysogeny. Bacteriophage may exist inside the bacterial cells in four forms with different evolutionary strategies: as a replicating virus during the lytic cycle, in an unstable carrier state termed pseudolysogeny, as a prophage with complete genome during the lysogeny, or as a defective cryptic prophage. Some defensive mechanisms of bacteria and virus countermeasures are characterized, and some evolutionary questions concerning phage-host relationship are discussed.

Haloarchaeal myovirus φCh1 harbours a phase variation system for the production of protein variants with distinct cell surface adhesion specificities

The φCh1 myovirus, which infects the haloalkaliphilic archaeon Natrialba magadii, contains an invertible region that comprises the convergent open reading frames (ORFs) 34 and 36, which code for the putative tail fibre proteins gp34 and gp36 respectively. The inversion leads to an exchange of the C-termini of these proteins, thereby creating different types of tail fibres. Gene expression experiments revealed that only ORF34 is transcribed, indicating that φCh1 produces tail fibre proteins exclusively from this particular ORF. Only one of the two types of tail fibres encoded by ORF34 is able to bind to Nab. magadii in vitro. This is reflected by the observation that during the early phases of the infection cycle, the lysogenic strain L11 carries its invertible region exclusively in the orientation that produces that specific type of tail fibre. Obviously, Nab. magadii can only be infected by viruses carrying this particular type of tail fibre. By mutational analysis, the binding domain of gp34 was localized to the C-terminal part of the protein, particularly to a galactose-binding domain. The involvement of galactose residues in cell adhesion was supported by the observation that the addition of α-D-galactose to purified gp34 or whole virions prevented their attachment to Nab. magadii.

Genomic evolution in a virus under specific selection for host recognition

Genetic variation in viral structural proteins is often explained by evolutionary escape of strong host defenses through processes such as immune evasion, host switching, and tissue tropism. An understanding of the mechanisms driving evolutionary change in virus surface proteins is key to designing effective intervention strategies to disease emergence. This study investigated the predictability of virus genomic evolution in response to highly specific differences in host receptor structure. The bacteriophage PhiX174 was evolved on three E. coli mutant hosts, each differing only by a single sugar group in the lipopolysaccharides, used for phage attachment. Large phage populations were used in order to maximize the amount of sequence space explored by mutation, and thus the potential for parallel evolution. Repeatability was assessed by genome sequencing of multiple isolates from endpoint populations and by fitness of the endpoint population relative to its ancestor. Evolutionary lines showed similar magnitudes of fitness increase between treatments. Only one mutation, occurring in the internal DNA pilot protein H, was completely repeatable, and it appeared to be a necessary stepping stone toward further adaptive change. Substitutions in the surface accessible major capsid protein F appeared to be involved in capsid stability rather than specific interactions with host receptors, suggesting that non-specific alterations to capsid structure could be an important component of adaptation to novel hosts. 33% of mutations were synonymous and showed evidence of selection on codon usage. Lastly, results supported previous findings that evolving populations of small ssDNA viruses may maintain relatively high levels of genetic variation.

Specific interaction of fused H protein of bacteriophage phiX174 with receptor lipopolysaccharides

The DNA fragment encoding the spike H protein of bacteriophage phiX174 was amplified by polymerase chain reaction. The fragment was sub-cloned into pQE-30 to yield pQE-H. The histidine-tagged H protein (HisH) was obtained from the cell extract of Escherichia coli M15 (pREP4) harboring pQE-H and purified by nickel chelating and anion-exchange chromatographies. HisH was shown to bind dose-dependently to the lipopolysaccharides (LPSs) isolated from phiX174-sensitive strains, E. coli C or Salmonella typhimurium TV119 (Ra mutant). In sharp contrast, HisH did not bind to the LPSs from insensitive strains, E. coli F583 (Rd2 mutant) or E. coli O111:B4 (smooth strain). Since the same selectivity was observed in the plaque counting assay for in vitro inactivation of phiX174, the spike H protein was shown to recognize receptor LPS.

The structure of coxsackievirus B3 at 3.5 A resolution

BACKGROUND

Group B coxsackieviruses (CVBs) are etiologic agents of a number of human diseases that range in severity from asymptomatic to lethal infections. They are small, single-stranded RNA icosahedral viruses that belong to the enterovirus genus of the picornavirus family. Structural studies were initiated in light of the information available on the cellular receptors for this virus and to assist in the design of antiviral capsid-binding compounds for the CVBs.

RESULTS

The structure of coxsackievirus B3 (CVB3) has been solved to a resolution of 3.5 A. The beta-sandwich structure of the viral capsid proteins VP1, VP2 and VP3 is conserved between CVB3 and other picornaviruses. Structural differences between CVB3 and other enteroviruses and rhinoviruses are located primarily on the viral surface. The hydrophobic pocket of the VP1 beta-sandwich is occupied by a pocket factor, modeled as a C16 fatty acid. An additional study has shown that the pocket factor can be displaced by an antiviral compound. Myristate was observed covalently linked to the N terminus of VP4. Density consistent with the presence of ions was observed on the icosahedral threefold and fivefold axes.

CONCLUSIONS

The canyon and twofold depression, major surface depressions, are predicted to be the primary and secondary receptor-binding sites on CVB3, respectively. Neutralizing immunogenic sites are predicted to lie on the extreme surfaces of the capsid at sites that lack amino acid sequence conservation among the CVBs. The ions located on the icosahedral threefold and fivefold axes together with the pocket factor may contribute to the pH stability of the coxsackieviruses.

DNA packaging intermediates of bacteriophage φX174

BACKGROUND

Like many viruses, bacteriophage phi X174 packages its DNA genome into a procapsid that is assembled from structural intermediates and scaffolding proteins. The procapsid contains the structural proteins F, G and H, as well as the scaffolding proteins B and D. Provirions are formed by packaging of DNA together with the small internal J proteins, while losing at least some of the B scaffolding proteins. Eventually, loss of the D scaffolding proteins and the remaining B proteins leads to the formation of mature virions.

RESULTS

phi X174 108S 'procapsids' have been purified in milligram quantities by removing 114S (mature virion) and 70S (abortive capsid) particles from crude lysates by differential precipitation with polyethylene glycol. 132S 'provirions' were purified on sucrose gradients in the presence of EDTA. Cryo-electron microscopy (cryo-EM) was used to obtain reconstructions of procapsids and provirions. Although these are very similar to each other, their structures differ greatly from that of the virion. The F and G proteins, whose atomic structures in virions were previously determined from X-ray crystallography, were fitted into the cryo-EM reconstructions. This showed that the pentamer of G proteins on each five-fold vertex changes its conformation only slightly during DNA packaging and maturation, whereas major tertiary and quaternary structural changes occur in the F protein. The procapsids and provirions were found to contain 120 copies of the D protein arranged as tetramers on the two-fold axes. DNA might enter procapsids through one of the 30 A diameter holes on the icosahedral three-fold axes.

CONCLUSIONS

Combining cryo-EM image reconstruction and X-ray crystallography has revealed the major conformational changes that can occur in viral assembly. The function of the scaffolding proteins may be, in part, to support weak interactions between the structural proteins in the procapsids and to cover surfaces that are subsequently required for subunit-subunit interaction in the virion. The structures presented here are, therefore, analogous to chaperone proteins complexed with folding intermediates of a substrate.

Lactococcal Bacteriophages Require a Host Cell Wall Carbohydrate and a Plasma Membrane Protein for Adsorption and Ejection of DNA

The mechanism of the initial steps of bacteriophage infection in Lactococcus lactis subsp. lactis C2 was investigated by using phages c2, ml3, kh, l, h, 5, and 13. All seven phages adsorbed to the same sites on the host cell wall that are composed, in part, of rhamnose. This was suggested by rhamnose inhibition of phage adsorption to cells, competition between phage c2 and the other phages for adsorption to cells, and rhamnose inhibition of lysis of phage-inoculated cultures. The adsorption to the cell wall was found to be reversible upon dilution of the cell wall-adsorbed phage. In a reaction step that apparently follows adsorption to the cell wall, all seven phages adsorbed to a host membrane protein named PIP. This was indicated by the inability of all seven phages to infect a strain selected for resistance to phage c2 and known to have a defective PIP protein. All seven phages were inactivated in vitro by membranes from wild-type cells but not by membranes from the PIP-defective, phage c2-resistant strain. The mechanism of membrane inactivation was an irreversible adsorption of the phage to PIP, as indicated by adsorption of [ 35 S] methionine-labeled phage c2 to purified membranes from phage-sensitive cells but not to membranes from the resistant strain, elimination of adsorption by pretreatment of the membranes with proteinase K, and lack of dissociation of 35 S from the membranes upon dilution. Following membrane adsorption, ejection of phage DNA occurred rapidly at 30°C but not at 4°C. These results suggest that many lactococcal phages adsorb initially to the cell wall and subsequently to host cell membrane protein PIP, which leads to ejection of the phage genome.

Atomic structure of single-stranded DNA bacteriophage phi X174 and its functional implications

The mechanism of DNA ejection, viral assembly and evolution are related to the structure of bacteriophage phi X174. The F protein forms a T = 1 capsid whose major folding motif is the eight-stranded antiparallel beta barrel found in many other icosahedral viruses. Groups of 5 G proteins form 12 dominating spikes that enclose a hydrophilic channel containing some diffuse electron density. Each G protein is a tight beta barrel with its strands running radially outwards and with a topology similar to that of the F protein. The 12 'pilot' H proteins per virion may be partially located in the putative ion channel. The small, basic J protein is associated with the DNA and is situated in an interior cleft of the F protein. Tentatively, there are three regions of partially ordered DNA structure,

The three-dimensional structure of frozen-hydrated bacteriophage phi X174

The three-dimensional structure of bacteriophage phi X174 (phi X174) was determined to approximately 2.6 nm resolution from images of frozen-hydrated 114 S particles. The outer surface of phi X174 is characterized by several prominent features: (i) 12 mushroom-shaped caps (approximately 7.1 nm wide x 3.8 nm high) are situated at each of the vertices of the icosahedral virion and extend to a maximum radius of 16.8 nm; (ii) a "collar" of density surrounds the base of each apical cap; and (iii) 20 conical protrusions (approximately 2.3 nm high) lie along the three-fold symmetry axes. The caps have a pentagonal morphology composed of five globular "subunits" and appear to be loosely connected to the underlying capsid. The distribution of the four gene products present in virions (60 copies each of gpF, gpG, and gpJ, and 12 copies of gpH), and the single-stranded DNA (ssDNA) genome cannot be directly discerned in the reconstructed density map, although plausible assignments can be made on the basis of solvent-excluded volume estimates and previous biochemical data. Thus, gpG accounts for most of the mass in the caps; gpH, a presumed cap protein, cannot be identified in part due to the symmetry-averaging procedures, but may be partially located within the interior of the capsid; and gpF and gpJ make up the remainder of the capsid. The genome appears to be less densely packaged inside the capsid compared to many dsDNA viruses whose nucleic acid is arranged in a liquid-crystalline state.

The bacteriophage kh receptor of Lactococcus lactis subsp. cremoris KH is the rhamnose of the extracellular wall polysaccharide

A receptor for bacteriophages of lactic acid bacteria, including Lactococcus lactis subsp. cremoris KH, was found on the cell wall and not on the cell membrane, as determined by a phage-binding assay of sodium dodecyl sulfate- and mutanolysin-treated cell walls. The cell wall carbohydrates of L. lactis subsp. cremoris KH were analyzed by gas chromatography and mass spectrometry and found to contain rhamnose, galactose, glucose and N-acetylglucosamine. Similar analysis of mutants that were reduced in the ability to bind phages kh, 643, c2, ml3, and 1 indicated that galactose was essential for binding all phages. In addition, rhamnose was required for binding phages kh and ml3. Inhibition studies of phage binding by using two different lectins with a specificity for galactose indicated that phage kh may not bind directly to galactose. Rather, galactose may be an essential structural component located in the vicinity of the receptor. Incubation of any of the five phages with rhamnose or of phage kh with purified cell walls inactivated the phages. Inactivation required divalent cations and was irreversible. Inactivation of phages was stereospecific for rhamnose, as neither L-(+)- nor D-(-)-fucose (the stereoisomers of rhamnose) inhibited the phage. Furthermore, phage infection of a culture was completely inhibited by the addition of rhamnose to the medium. Therefore, the receptor for phage kh appears to be a rhamnose component of the extracellular wall polysaccharide.

Preliminary investigation of the phage phi X174 crystal structure

Crystals of the single-stranded DNA bacteriophage phi X174 have been grown. They have a monoclinic unit cell with space group P2(1), unit cell dimensions of a = 306.0 (+/- 0.2) A, b = 361.1 (+/- 0.2) A, c = 299.7 (+/- 0.2 degrees) A, beta = 92.91 degrees (+/- 0.02 degrees) and diffract to at least 2.7 A resolution. There are two virus particles per unit cell. Packing considerations show that the mean diameter of the virus particles is 280 A. The virus separates into two bands in a sucrose gradient. The ratio between the absorbance at 260 nm and 280 nm is 1.45 to 1.65 for the faster and 1.15 to 1.35 for the slower bands, but both bands contain intact particles. Crystals derived from these bands are isomorphous and there is no detectable difference in their structure amplitudes.

Eclipse kinetics as a probe of quaternary structure in bacteriophage phi X174

The extracellular form of bacteriophage phi X174 consists of single-stranded DNA within an icosahedral capsid, which has short spikes at each of its vertices. Each spike is composed of gene G and H proteins, while the capsid itself consists of gene F protein. Since several molecules of gene H protein are injected into the cell along with the DNA, specific protein--protein and DNA--protein interactions must be broken when the genome exits and leaves an intact capsid structure at the receptor site. To demonstrate this we examined the eclipse (DNA ejection) reaction with two types of phi X174 mutants. The first contains missense mutations in a capsid or spike protein gene, and the second involves insertions or deletions in non-coding regions of the DNA. Using an improved procedure, the eclipse rate in vivo of the eclipse mutants Fcs70 has been redetermined over a larger temperature range than in previous studies. The three- to fivefold decrease in rate between 37 degrees C and 25 degrees C is due to an increase in both the enthalpy and entropy of activation when compared to the wild-type values of these kinetic parameters. This missence mutation also confers an increase in virus stability in 2 to 3 M-urea. In contrast to this, inserting 163 bases into the length of DNA packaged within the phi X174 capsid does not lead to a detectable change in eclipse rate over the same temperature range. yet this insertion into the J--F intercistronic region imparts a significant decrease in virus stability in urea. These results suggest that a specific set of non-covalent interactions is involved in phi X174 DNA ejection. This is supported by the small (50%), but significant, increase in eclipse rate that occurs when 27 bases are deleted from the J--F intercistronic region. The latter effect must be base-sequence-specific since no change in rate is observed when only seven of the 27 bases are deleted. Thus, the kinetics of the phi X174 eclipse reaction can be used as a sensitive probe of quaternary structure by correlating the change in reaction rate with alterations in amino acid and base sequences in the structural components of the virus.

The role of bivalent ions in the inactivation of bacteriophage phi X174 by lipopolysaccharide from Escherichia coli C

The need for Ca2+ in the inactivation of bacteriophage phi X174 by lipopolysaccharide from Escherichia coli C was confirmed. Ca2+ could be replaced almost completely by Na+, but the concentration of Na+ needed was greater by more than an order of magnitude. Other bivalent ions caused inactivation in the same way as Ca2+, and the degree of inactivation varied according to the ion. At 50% inactivation of bacteriophage, the relation between the concentrations of NaCl and of bivalent or tervalent ions (Mx+) fitted the conception that NaCl was neutralizing electrostatic repulsion between virus and lipopolysaccharide by an ionic-strength effect: that is, log[Mx+] varies inversely with square root[NaCl]. The variation in effect of bi- and ter-valent ions and the low concentration needed show that this is not an ionic-strength effect but likely to involve binding to more than one site.

A kinetic model for virus binding which involves release of cell-bound virus-receptor complexes

A general kinetic mechanism is presented for reversible binding of viruses to cells followed by an irreversible step that initiates the delivery of the viral genome. A novel feature is additional pathways for the release of both virus-occupied and unoccupied receptors from cells. Due to one simplifying assumption, it does not apply at low receptor densities. However, it is sufficiently general to be applicable to ligand binding and internalization for those systems in which ligand diffusion is rate limiting. Three different versions of the model fit the usual kinetic data for the binding of an eclipse mutant of bacteriophage phi X174 to Escherichia coli. However, in each case binding to cell-bound receptors is irreversible. Therefore, this explains the apparent failure of this system to obey the Law of Mass Action. One version of the model also predicts that the release rate of lipopolysaccharide receptors from the outer membrane may be significantly lowered when virus is bound to these receptors.

In vitro conversion of S13 viral DNA in phage particles to the double-stranded DNA

The conversion of single-stranded DNA in S13 intact phage particles to the double-stranded replicative form DNA was observed in cell extracts prepared from Escherichia coli H560 (S13s, polA, endA) cells lysed with lysozyme and the non-ionic detergent, Brij 58. The DNA product, which associated with a rapidly sedimenting component, was identified as RFII-DNA with a gap by sedimentation analysis. The conversion was inhibited by N-ethylmaleimide, but not by rifampicin, nicotinamide mononucleotide or polymyxin B. The dnaB gene product was involved in the replicative system. Similar extracts prepared from a S13-resistant E. coli strain K12W6 also catalyzed this synthesis.

A new locus of Escherichia coli that determines sensitivity to bacteriophage phi X174

A new gene designated phxB, necessary for adsorption of phiX174 to the cell surface of Escherichia coli, is located between gal and aroG on the E. coli chromosome.

In Vitro system for the study of bacteriophage phi chi 174 adsorption and eclipse

An in vitro system was developed for the study of the initial stages of bacteriophage phi chi 174 infection. Escherichia coli C cells were incubated with 20% sucrose and then subjected to cold osmotic shock in 5 mM MgSO4. The concentrated supernatant shock fluid inactivated phi chi 174 with the same kinetics and requirements as for normal infection. Shock fluids prepared from phi chi 174-resistant strains of E. coli did not show this effect. The 114S phage were initially converted into 70S particles, the process termed "eclipse". These structurally altered phages then attached to a component of the shock fluid, producing fast-sedimenting complexes, and eventually released at least a part of their DNA into the medium. The fast-sedimenting complex could be radioactively labeled with oleic acid. Radioactivity was found to co-chromatograph with both biological activity and the majority of the high-molecular-weight carbohydrates present in the shock fluid. It is concluded that E. coli C osmotic shock fluid contains isolated phi chi 174-specific receptor sites composed of lipopolysaccharides. This system conveniently separates the early stages of phage phi chi 174 infection from the intracellular events.

Mechanism of adsorption and eclipse of bacteriophage phi chi 174. 3. Comparison of the activation parameters for the in vitro and in vivo eclipse reactions with mutant and wild-type virus

In a starvation buffer containing 10(-3) M divalent cations, phiX174 undergoes viral eclipse above 20 C when attached to intact host cells. An in vitro structural transition that is similar to that observed in this in vivo eclipse reaction occurs over the same temperature range in 0.1 M CaCl(2) (pH 7.2). Since both reactions result in a loss of infectivity, their kinetics have been compared in this report. Both exhibit a biphasic first-order loss in PFU that is a result of two competing first-order processes. However, a single type of heterogeneity in the population of virions is not the basis for both competing slower reactions. The Arrhenius plots of the faster components show that the in vitro eclipse reaction has the same activation energy of 35 kcal/mol (ca. 1.47 x 10(5) J/mol) as the in vivo reaction but a 10-fold lower Arrhenius preexponential factor. This is further evidence that certain features of the in vivo mechanism are retained in the in vitro reaction. In the case of the slower components, the in vitro reaction has an activation energy of 37 kcal/mol (1.55 x 10(5) J/mol), whereas that of the in vivo reaction is only 5 kcal/mol (2.1 x 10(4) J/mol). A similar analysis has been performed on a cold-sensitive eclipse mutant of phiX174. In vivo, the mutation is expressed by a two- to three-fold lower Arrhenius preexponential factor for both components of the eclipse reaction when compared to wt virus. The activation energies for both components are the same as wt virus. These results suggest that the mechanism of the eclipse reaction can be operationally divided into two aspects, each subject to mutational alteration.