Icosahedral bacteriophage ΦX174 forms a tail for DNA transport during infection.

Prokaryotic viruses have evolved various mechanisms to transport their genomes across bacterial cell walls. Many bacteriophages use a tail to perform this function, whereas tail-less phages rely on host organelles. However, the tail-less, icosahedral, single-stranded DNA ΦX174-like coliphages do not fall into these well-defined infection processes. For these phages, DNA delivery requires a DNA pilot protein. Here we show that the ΦX174 pilot protein H oligomerizes to form a tube whose function is most probably to deliver the DNA genome across the host's periplasmic space to the cytoplasm. The 2.4 Å resolution crystal structure of the in vitro assembled H protein's central domain consists of a 170 Å-long α-helical barrel. The tube is constructed of ten α-helices with their amino termini arrayed in a right-handed super-helical coiled-coil and their carboxy termini arrayed in a left-handed super-helical coiled-coil. Genetic and biochemical studies demonstrate that the tube is essential for infectivity but does not affect in vivo virus assembly. Cryo-electron tomograms show that tubes span the periplasmic space and are present while the genome is being delivered into the host cell's cytoplasm. Both ends of the H protein contain transmembrane domains, which anchor the assembled tubes into the inner and outer cell membranes. The central channel of the H-protein tube is lined with amide and guanidinium side chains. This may be a general property of viral DNA conduits and is likely to be critical for efficient genome translocation into the host.

Enhancement of tomogram interpretability using the locked self-rotation function.

The interpretation of cryo-electron tomograms of macromolecular complexes can be difficult because of the large amount of noise and because of the missing wedge effect. Here it is shown how the presence of rotational symmetry in a sample can be utilized to enhance the quality of a tomographic analysis. The orientation of symmetry axes in a sub-tomogram can be determined using a locked self-rotation function. Given this knowledge, the sub-tomogram density can then be averaged to improve its interpretability. Sub-tomograms of the icosahedral bacteriophage phiX174 are used to demonstrate the procedure.

Plaque Size Tool: An automated plaque analysis tool for simplifying and standardising bacteriophage plaque morphology measurements.

Bacteriophage plaque size measurement is essential for phage characterisation, but manual size estimation requires a considerable amount of time and effort. In order to ease the work of phage researchers, we have developed an automated command-line application called Plaque Size Tool (PST) that can detect plaques of different morphology on the images of Petri dishes and measure plaque area and diameter. Plaque size measurements using PST showed no difference to those obtained with manual plaque size measurement in Fiji, indicating future results using PST are backwards compatible with prior measurements in the literature. PST can be applied to a range of lytic bacteriophages producing oval-shaped plaques, including bull's-eye and turbid morphology. The application can also be used for titer calculation if most of the plaques are stand-alone. As laboratory automation becomes more commonplace, standardised and flexible open-source analytical tools like PST will be important parts of biofoundry and cloud lab bacteriophage workflows.

Structures of virus and virus-like particles.

Virus structures continue to be the basis for mechanistic virology and serve as a paradigm for solutions to problems concerning macromolecular assembly and function in general. The use of X-ray crystallography, electron cryomicroscopy and computational and biochemical methods has provided not only details of the structural folds of individual viral components, but also insights into the structural basis of assembly, nucleic acid packaging, particle dynamics and interactions with cellular molecules.

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.

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.

Calcium ion-induced structural changes in bacteriophage phi X174.

Monoclinic P2(1) crystals of the bacteriophage phi X174 have been incubated with calcium ions (Ca2+) and the induced structural conformational changes studied to 3 A resolution with X-ray crystallographic methods. Three different types of Ca2+ binding sites have been located within the asymmetric unit of the virion. Two sets of sites are associated with the F capsid protein. One set of sites associated with the F protein is in a general position near the icosahedral 3-fold axes of the virus, with the main-chain carbonyl oxygen atoms of residues Gly1321, Asp1421, Met1424 and Ser1426, and the side-chains of Gln1004 and Asp1421 as ligands. The other set of sites associated with the F protein is on the icosahedral 3-fold axes, with the symmetry-related main-chain carbonyl oxygen atoms of Ser1001 and the side-chains of Asn1002 as ligands. The bound Ca2+ induce a conformational change of the amino-terminal residues of the F proteins. A third set of sites, consisting of a pair of Ca2+ on the icosahedral 5-fold axes, are associated with the G spike protein and are concurrently liganded by the symmetry-related carbonyl oxygen side-chains of Asp2117. Concomitant with the binding of Ca2+ to the phage is the rotation of the Asp1209 side-chain of the F protein towards some additional electron density that was not observed in the absence of Ca2+. This density is situated in a shallow depression near the icosahedral 2-fold axes of the virus, and has been tentatively interpreted as a bound glucose molecule that is ordered only in the presence of Ca2+. The putative glucose binding site may be related to the attachment of the virus to cell surface lipopolysaccharides in the initial stages of Escherichia coli infection.

Analysis of the single-stranded DNA bacteriophage phi X174, refined at a resolution of 3.0 A.

The structure of the bacteriophage phi X174 was examined in a 2.7 A resolution map and refined, using 6.0 A to 3.0 A resolution data with F > or = 5 sigma (F). The final R-factor was 20.9% and the root-mean-square deviation from idealized bond lengths was 0.021 A. The Hendrickson-Konnert refinement was restrained by the phases derived from the molecular replacement icosahedral averaging procedure. The mature phage capsid consists of 60 copies of the F protein with 426 amino acids, the G protein with 175 amino acids and the J protein with 37 amino acids, as well as 12 copies of the H protein with 328 amino acids. The entire polypeptide chain of the F and G protein, all but the first N-terminal residue of the J protein, and 178 solvent molecules were included in the refinement calculations. The secondary structural features of the F, G and J proteins and their interactions with each other are described. The majority of the protein-protein interactions are between the icosahedral 5-fold related interfaces of the F and of the G proteins. These pentameric units of the F and G proteins form the 9S and 6S assembly intermediates, respectively. The J protein lacks any secondary structure and acts as a linking arm between the icosahedral 5-fold related F proteins. Water molecules were introduced only after phase extension to 2.7 A resolution had been completed. The F protein is associated with lower "thermal" parameters and exhibits greater water order in its environment than the G and J proteins. The largest thermal parameters occur in residues on the viral surface. The solvent contributes to the interactions between the proteins. There is an interface of solvent molecules between the F and the G pentamers which stabilizes the pentameric G protein spikes in a crater centered at each of the icosahedral 5-fold vertices of the F protein capsid. Sequence alignments of the F, G and J amino acid sequences for the homologous bacteriophages G4, alpha 3, phi K and phi X174 with respect to the phi X174 structure demonstrated the conservation of functionally important residues on the viral surface.

Host and phi X 174 mutations affecting the morphogenesis or stabilization of the 50S complex, a single-stranded DNA synthesizing intermediate.

The morphogenetic pathway of bacteriophage phi X 174 was investigated in rep mutant hosts that specifically block stage III single-stranded DNA synthesis. The defects conferred by the mutant rep protein most likely affect the formation or stabilization of the 50S complex, a single-stranded DNA synthesizing intermediate, which consists of a viral prohead and a DNA replicating intermediate (preinitiation complex). phi X 174 mutants, ogr (rep), which restore the ability to propagate in the mutant rep hosts, were isolated. The org (rep) mutations confer amino acid substitutions in the viral coat protein, a constituent of the prohead, and the viral A protein, a constituent of the preinitiation complex. Four of the six coat protein substitutions are localized on or near the twofold axis of symmetry in the atomic structure of the mature virion.

Electron microscopic studies of bacteriophage phi X174 intact and "eclipsing' particles, and the genome by the staining, and shadowing method.

Bacteriophage phi X174 particles were observed with a new method, a combination of staining and shadowing. Previously we used this technique to obtain clear visualization of the shape of cytoplasmic-polyhedrosis virus, especially the spikes of this particle. The phi X174 particle was observed to be an icosahedral particle of 25 nm in diameter carrying a spike at each vertex. The spike was a pentagonal frustum with a base of 9 nm and a height of 6 nm. When the phage was treated with calcium on the supporting film, the genome extruded from the particle. With the staining and shadowing method, it was clearly observed that the spike was the extruding channel of the genome. The genome extrusion occurred not only a single spike of the particle but also at two or more spikes. This implied that all 12 spikes of the particle had the same abilities to act as the channel of genome extrusion. The released genomes showed various thicknesses and shapes such as bending, looping, or branching, which were thought to reflect to compact form of DNA in a virus particle. The similarly between the spikes of bacteriophage phi X174 and those of cytoplasmic-polyhedrosis virus from silk worm was also discussed.

A study of phi X-174 DNA torus and lambda DNA torus tertiary structure and the implications for DNA self-assembly.

Hydrated torus shaped complexes were examined by transmission electron microscopy in both spermidine-condensed linear and nicked circular phi X-174 DNA and lambda DNA preparations. Freeze-etch replicas of both these torus samples, produced with very low Pt metal deposition levels (9APt/C), were found to have circumferentially wound single DNA double helix size surface fibers in the range of 30A width. Measurements of torus inner and outer circumference as well as ring thickness were performed. Observed differences in the torus dimension distributions from circular phi X-174 DNA and linear phi X-174 DNA may be related to the different topological constraints on DNA folding in these two samples (1). On the basis of annulus thickness measurements phi X-174 DNA toruses, in contrast to lambda DNA toruses, were observed to fall into two classes identified as being formed from monomer DNA condensation and multimer DNA condensation. All of the torus substructure and population dimensions observed here are consistent with the continuous circumferential DNA winding model of torus organization proposed by Marx and Reynolds (1) to explain the micrococcal nuclease cleavage properties of the toruses. End-on view measurements of the torus thickness were made from micrographs obtained by extensive tilting of the object replica. These direct measurements confirmed quaternary structure interpretations made from simple strand packing models. We compared the measured torus properties in this linear DNA size series (5386-48000 bp). With increasing DNA length the pattern of DNA strand self-assembly was found to be more varied producing lambda DNA toruses of varying shape. The relevance of our study to the problem of lambda bacteriophage DNA head packaging was discussed.

The locked rotation function.

It frequently occurs that a biological assembly in a crystallographic asymmetric unit has more than one noncrystallographic symmetry operator. For instance, a tetramer might have the point group 222 or a spherical virus will have the point group 532. A self-rotation function searches for the direction and angle of rotation of the individual noncrystallographic symmetry operations, while a cross-rotation function searches for the relationship of a structure in one unit cell with similar structures in another cell. The power of the rotation function can be greatly enhanced by searching for all noncrystallographic symmetry operators simultaneously. The procedure described previously [Rossmann, Ford, Watson & Banaszak (1972). J. Mol. Biol. 64, 237-249] has been generalized. The increased power of this 'locked' rotation function permits a good determination of the orientation of an icosahedral virus in the presence of less than 1% of the possible diffraction data to 7 A resolution. In addition, the peak-to-noise ratio is substantially improved.

Recent advances in atomic force microscopy of DNA.

Three advances involving DNA in atomic force microscopy (AFM) are reported here. First a HEPES-Mg buffer has been used that improves the spreading of DNA and provides good DNA coverage with as little as 200-500 picograms per sample. Second, the new "tapping" mode has been used to improve the ease and resolution of AFM-imaging of DNA in air. Finally, AFM images are presented of single-stranded phi X-174 virion DNA with the gene 32 single-stranded binding protein. A summary of the current state of the field and of the methods for preparing and imaging DNA in the AFM is also presented.

A sensitive method for evaluating condoms as virus barriers.

A standard test is needed to evaluate condoms as barriers against sexually transmitted diseases, particularly those caused by viruses. The proposed method presented here consists of a previously published simple method using physiologic-based conditions plus improvements to increase test sensitivity and decrease confounding factors such as contamination. Limitations of the method were determined by measuring virus penetration through small, well-defined holes. The method can detect penetration of 2 nL (2 x 10(-6) mL) of challenge virus suspension as well as a hole of 2 microns diameter in a latex condom. The data also indicated that virus penetration of latex condoms occurred quickly, and the hole was then apparently closed or blocked.

PIP: Condoms can act as barriers to the passage of sexually transmitted diseases (STDs). However, a claim that condoms are effective against STDs must be confirmed by appropriate laboratory tests. Various tests have therefore been developed to evaluate the barrier effectiveness of latex and natural membrane condoms. The authors describe and evaluate a test which involves filling the condom with virus-containing buffer and determining whether any virus penetrates the barrier during submersion in a collection buffer. Virus penetration is measured and reported as the equivalent volume of challenge virus suspension needed to account for the amount of virus penetration. The limitations of this approach were determined by measuring virus penetration through small, well-defined holes. It was found that the method can detect penetration of 2 nl of challenge virus suspension as well as a hole of 2 mcm diameter in a latex condom. The data also indicate that virus penetration of latex condoms occurs quickly, then the hole apparently closes or is blocked.

The role of surface functionalization of colloidal alumina particles on their controlled interactions with viruses.

Materials that interact in a controlled manner with viruses attract increasing interest in biotechnology, medicine, and environmental technology. Here, we show that virus-material interactions can be guided by intrinsic material surface chemistries, introduced by tailored surface functionalizations. For this purpose, colloidal alumina particles are surface functionalized with amino, carboxyl, phosphate, chloropropyl, and sulfonate groups in different surface concentrations and characterized in terms of elemental composition, electrokinetic, hydrophobic properties, and morphology. The interaction of the functionalized particles with hepatitis A virus and phages MS2 and PhiX174 is assessed by virus titer reduction after incubation with particles, activity of viruses conjugated to particles, and imaged by electron microscopy. Type and surface density of particle functional groups control the virus titer reduction between 0 and 99.999% (5 log values). For instance, high sulfonate surface concentrations (4.7 groups/nm(2)) inhibit attractive virus-material interactions and lead to complete virus recovery. Low sulfonate surface concentrations (1.2 groups/nm(2)), native alumina, and chloropropyl-functionalized particles induce strong virus-particle adsorption. The virus conformation and capsid amino acid composition further influence the virus-material interaction. Fundamental interrelations between material properties, virus properties, and the complex virus-material interaction are discussed and a versatile pool of surface functionalization strategies controlling virus-material interactions is presented.

Uncoupling the functions of a multifunctional protein: the isolation of a DNA pilot protein mutant that affects particle morphogenesis.

Defective øX174 H protein-mediated DNA piloting indirectly influences the entire viral lifecycle. Faulty piloting can mask the H protein's other functions or inefficient penetration may be used to explain defects in post-piloting phenomena. For example, optimal synthesis of other viral proteins requires de novo H protein biosynthesis. As low protein concentrations affect morphogenesis, protein H's assembly functions remain obscure. An H protein mutant was isolated that allowed morphogenetic effects to be characterized independent of its other functions. The mutant protein aggregates assembly intermediates. Although excess internal scaffolding protein restores capsid assembly, the resulting mutant H protein-containing particles are less infectious. In addition, nonviable phenotypes of am(H) mutants in Su+ hosts, which insert non-wild-type amino acids, do not always correlate with a lack of missense protein function. Phenotypes are highly influenced by host and phage physiology. This phenomenon was unique to am(H) mutants, not observed with amber mutants in other genes.

Normal-flow virus filtration: detection and assessment of the endpoint in bio-processing.

The breakthrough of a model virus, bacteriophage PhiX-174, through normal-flow virus filters was studied using both commercial process fluids and model feed streams. The results indicate that (i) PhiX-174 is a reasonable model for a mammalian parvovirus [MMV (murine minute virus)] in virus filtration studies; (ii) PhiX-174 LRV [log(reduction value)] shows a better correlation with percentage flow decline compared with volume processed under a variety of conditions; (iii) although the extent of decline in virus LRV is dependent on the mechanism of filter fouling, the fouling mechanisms operative in a viral validation study are representative of those likely to be found under actual production conditions. The mechanism of LRV decline by many process streams was proposed to be due to selective plugging of small pores. A theoretical model as well as a predictive equation for LRV decline versus flow decay was derived; experimental results from filtration studies using pore-plugging feed stocks were consistent with the equation. As protein solutions may vary in their adsorptive versus plugging behaviour during filtration, an evaluation of the LRV-versus-flow-decay relationship on a biopharmaceutical-product-specific basis may be warranted.