Stepwise reversible nanomechanical buckling in a viral capsid

Viruses are nanoscale infectious agents constructed of a proteinaceous capsid that protects the packaged genomic material. Nanoindentation experiments using atomic force microscopy have, in recent years, provided unprecedented insight into the elastic properties, structural stability and maturation-dependent mechanical changes in viruses. However, the dynamics of capsid behavior are still unresolved. Here we used high-resolution nanoindentation experiments on mature, DNA-filled T7 bacteriophage particles. The elastic regime of the nanoindentation force trace contained discrete, stepwise transitions that cause buckling of the T7 capsid with magnitudes that are integer multiples of ∼0.6 nm. Remarkably, the transitions are reversible and contribute to the rapid consolidation of the capsid structure against a force during cantilever retraction. The stepwise transitions were present even following the removal of the genomic DNA by heat treatment, indicating that they are related to the structure and dynamics of the capsomeric proteins. Dynamic force spectroscopy experiments revealed that the thermally activated consolidation step is ∼10⁴ times faster than spontaneous buckling, suggesting that the capsid stability is under strong dynamic control. Capsid structural dynamics may play an important role in protecting the genomic material from harsh environmental impacts. The nanomechanics approach employed here may be used to investigate the structural dynamics of other viruses and nanoscale containers as well.

Bacteriophage-based nanoprobes for rapid bacteria separation

The lack of practical methods for bacterial separation remains a hindrance for the low-cost and successful development of rapid detection methods from complex samples. Antibody-tagged magnetic particles are commonly used to pull analytes from a liquid sample. While this method is well-established, improvements in capture efficiencies would result in an increase of the overall detection assay performance. Bacteriophages represent a low-cost and more consistent biorecognition element as compared to antibodies. We have developed nanoscale bacteriophage-tagged magnetic probes, where T7 bacteriophages were bound to magnetic nanoparticles. The nanoprobe allowed the specific recognition and attachment to E. coli cells. The phage magnetic nanprobes were directly compared to antibody-conjugated magnetic nanoprobes. The capture efficiencies of bacteriophages and antibodies on nanoparticles for the separation of E. coli K12 at varying concentrations were determined. The results indicated a similar bacteria capture efficiency between the two nanoprobes.

Electrospun water-soluble polymer nanofibers for the dehydration and storage of sensitive reagents

The ability to preserve and deliver reagents remains an obstacle for the successful deployment of self-contained diagnostic microdevices. In this study we investigated the ability of bacteriophage T7 to be encapsulated and preserved in water soluble nanofibers. The bacteriophage T7 was added to mixtures of polyvinylpyrrolidone and water and electrospun onto a grounded plate. Trehalose and magnesium salts were added to the mixtures to determine their effect on the infectivity of the bacteriophage following electrospinning and during storage. The loss of T7 infectivity was determined immediately following electrospinning and during storage using agar overlay plating and plaque counting. The results indicate that the addition of magnesium salts protects the bacteriophage during the relatively violent and high voltage electrospinning process, but is not as effective as a protectant during storage of the dried T7. Conversely, the addition of trehalose into the electrospinning mix has little effect on the electrospinning, but a more significant role as a protectant during storage.

Single-step antibody-based affinity cryo-electron microscopy for imaging and structural analysis of macromolecular assemblies

Single particle cryo-electron microscopy (cryo-EM) is an emerging powerful tool for structural studies of macromolecular assemblies (i.e., protein complexes and viruses). Although single particle cryo-EM requires less concentrated and smaller amounts of samples than X-ray crystallography, it remains challenging to study specimens that are low-abundance, low-yield, or short-lived. The recent development of affinity grid techniques can potentially further extend single particle cryo-EM to these challenging samples by combining sample purification and cryo-EM grid preparation into a single step. Here we report a new design of affinity cryo-EM approach, cryo-SPIEM, that applies a traditional pathogen diagnosis tool Solid Phase Immune Electron Microscopy (SPIEM) to the single particle cryo-EM method. This approach provides an alternative, largely simplified and easier to use affinity grid that directly works with most native macromolecular complexes with established antibodies, and enables cryo-EM studies of native samples directly from cell cultures. In the present work, we extensively tested the feasibility of cryo-SPIEM with multiple samples including those of high or low molecular weight, macromolecules with low or high symmetry, His-tagged or native particles, and high- or low-yield macromolecules. Results for all these samples (non-purified His-tagged bacteriophage T7, His-tagged Escherichiacoli ribosomes, native Sindbis virus, and purified but low-concentration native Tulane virus) demonstrated the capability of cryo-SPIEM approach in specifically trapping and concentrating target particles on TEM grids with minimal view constraints for cryo-EM imaging and determination of 3D structures.

Nanotip analysis for dielectrophoretic concentration of nanosized viral particles

Rapid and sensitive detection of low-abundance viral particles is strongly demanded in health care, environmental control, military defense, and homeland security. Current detection methods, however, lack either assay speed or sensitivity, mainly due to the nanosized viral particles. In this paper, we compare a dendritic, multi-terminal nanotip ('dendritic nanotip') with a single terminal nanotip ('single nanotip') for dielectrophoretic (DEP) concentration of viral particles. The numerical computation studies the concentration efficiency of viral particles ranging from 25 to 100 nm in radius for both nanotips. With DEP and Brownian motion considered, when the particle radius decreases by two times, the concentration time for both nanotips increases by 4-5 times. In the computational study, a dendritic nanotip shows about 1.5 times faster concentration than a single nanotip for the viral particles because the dendritic structure increases the DEP-effective area to overcome the Brownian motion. For the qualitative support of the numerical results, the comparison experiment of a dendritic nanotip and a single nanotip is conducted. Under 1 min of concentration time, a dendritic nanotip shows a higher sensitivity than a single nanotip. When the concentration time is 5 min, the sensitivity of a dendritic nanotip for T7 phage is 10(4) particles ml(-1). The dendritic nanotip-based concentrator has the potential for rapid identification of viral particles.

[Study of elongation complexes for T7 RNA polymerase]

Complexes of bacteriophage T7 RNA polymerase with a DNA template for transcription elongation were visualized by atomic force microscopy. Images for complexes of T7 RNA polymerase with terminal fragments of DNA template were obtained for single molecules. Complexes of a single DNA template molecule with several T7 RNA polymerase molecules corresponding to stages of initiation, elongation and termination of transcription were visualized under the elimination of unspecific DNA-protein binding. Immobilized on the amino mica RNA transcripts form rod-like condensed structures. Detailes of specific and unspecific complex formation for the T7 RNA polymerase-DNA system during initiation and transcription elongation are discussed.

[Visualization of elongation complexes for t7 Rna polymerase by atomic force microscopy]

Complexes of bacteriophage T7 RNA polymerase (RNAP) with a DNA template for transcription elongation were visualized by atomic force microscopy (AFM). Fragment of pGEMEX linear DNA with length of 1414 bp carrying promot- er and terminator of bacteriophage T7 was DNA template for transcription. Promoter and terminator are located unsymmetrically on the ends of DNA template. Images of stable complexes of T7 RNAP with terminal fragments of DNA template were obtained for single molecules. Complexes of a single DNA template molecule with 2-3 T7 RNAP molecules corresponding to stages of initiation, elongation and termination of transcription were visualized under the elimination of non-specific DNA-protein binding. Also complexes of DNA, RNAP and RNA transcripts were imaged. Our results suggest that the initial stage is the formation of complex between T7 RNAP and terminal fragment of DNA template. Because promoter is localized near DNA terminus, it makes impossible an ommision of the promoter site.

DNA packaging and delivery machines in tailed bacteriophages

Several symmetric and asymmetric reconstructions of bacteriophage particles have recently been determined using electron cryo-microscopy and image reconstruction, and X-ray crystal structures of phage particles and particle-associated gene products have also been solved. In the past two years, the asymmetric structures of four different phages, T7, epsilon15, P22 and phi29, were determined at resolutions sufficient to visualize details of the machinery for DNA packaging and delivery, as well as the organization of the double-stranded DNA within the particles. Invariably, the portals, through which DNA enters and leaves the particle, have 12-fold symmetry, occupy a pentavalent site in the capsid and, along with tail machine accessory proteins attached to it, are fixed in a specific orientation relative to the rest of the capsid.

[Visualization of bacteriophage T7 RNA-polymerase complexes with DNA template in the process of transcription elongation]

Complexes of bacteriophage T7 RNA polymerase (T7 RNAP) with a DNA template (which contains a promoter and internal terminator of T7 RNAP) in transcription elongation were visualized by atomic force microscopy (AFM). Images of specific stable complexes of T7 RNAP with a terminal fragment of DNA template located at a distance of 200 bp from the T7 RNAP promoter were obtained for single molecules. Complexes of a single DNA template molecule with 2-3 T7 RNAP molecules corresponding to stages of initiation, elongation and termination of transcription were visualized under the elimination of nonspecific DNA-protein binding. Detailes of specific and nonspecific complex formation for the T7 RNAP--DNA system during initiation and transcription elongation are discussed.

A novel fluorescent probe: europium complex hybridized T7 phage

We report on the creation of a novel fluorescent probe of europium-complex hybridized T7 phage. It was made by filling a ligand-displayed T7 ghost phage with a fluorescent europium complex particle. The structure of the hybridized phage, which contains a fluorescent inorganic core surrounded by a ligand-displayed capsid shell, was confirmed by electron microscope, energy-dispersive X-ray analysis (EDX), bioassays, and fluorescence spectrometer. More importantly, as a benefit of the phage display technology, the hybridized phage has the capability to integrate an affinity reagent against virtually any target molecules. The approach provides an original method to fluorescently "tag" a bioligand and/or to "biofunctionalize" a fluorophore particle. By using other types of materials such as radioactive or magnetic particles to fill the ghost phage, we envision that the hybridized phages represent a new class of fluorescent, magnetic, or radioprobes for imaging and bioassays and could be used both in vitro and in vivo.

Changes in bacteriophage T7 virion structure at the initiation of infection

Five proteins are ejected from the bacteriophage T7 virion at the initiation of infection. The three known proteins of the internal core enter the infected cell; all three must both disaggregate from their structure in the mature virion and also almost completely unfold in order to leave the head and pass through the head-tail connector. Two small proteins, the products of genes 6.7 and 7.3, also are ejected from the infecting virion. Gp6.7 and gp7.3 were not previously described as structural virion components, leading to a re-appraisal of the stoichiometry of virion proteins. Gp6.7 is found in tail-less particles and is defined as a head protein, whereas gp7.3 is localized in the tail. Gene 6.7 may be important in morphogenesis; mutants defective in this late gene yield a reduced burst of progeny. Gene 7.3 is essential for virion assembly but, although normally present, its product gp7.3 is not required in a mature particle. Particles assembled in the absence of gp7.3 contain tail fibers but fail to adsorb to cells.

Maturation of phage T7 involves structural modification of both shell and inner core components

The double-stranded DNA bacteriophages are good model systems to understand basic biological processes such as the macromolecular interactions that take place during the virus assembly and maturation, or the behavior of molecular motors that function during the DNA packaging process. Using cryoelectron microscopy and single-particle methodology, we have determined the structures of two phage T7 assemblies produced during its morphogenetic process, the DNA-free prohead and the mature virion. The first structure reveals a complex assembly in the interior of the capsid, which involves the scaffolding, and the core complex, which plays an important role in DNA packaging and is located in one of the phage vertices. The reconstruction of the mature virion reveals important changes in the shell, now much larger and thinner, the disappearance of the scaffolding structure, and important rearrangements of the core complex, which now protrudes the shell and interacts with the tail. Some of these changes must originate by the pressure exerted by the DNA in the interior of the head.

Structure of the connector of bacteriophage T7 at 8A resolution: structural homologies of a basic component of a DNA translocating machinery

The three-dimensional structure of the bacteriophage T7 head-to-tail connector has been obtained at 8A resolution using cryo-electron microscopy and single-particle analysis from purified recombinant connectors. The general morphology of the T7 connector is that of a 12-folded toroidal homopolymer with a channel that runs along the longitudinal axis of the particle. The structure of the T7 connector reveals many structural similarities with the connectors from other bacteriophages. Docking of the atomic structure of the varphi29 connector into the three-dimensional reconstruction of T7 connector reveals that the narrow, distal region of the two oligomers are almost identical. This region of the varphi29 connector has been suggested to be involved in DNA translocation, and is composed of an alpha-beta-alpha-beta-beta-alpha motif. A search for alpha-helices in the same region of the T7 three-dimensional map has located three alpha-helices in approximately the same position as those of the varphi29 connector. A comparison of the predicted secondary structure of several bacteriophage connectors, including among others T7, varphi29, P22 and SPP1, reveals that, despite the lack of sequence homology, they seem to contain the same alpha-beta-alpha-beta-beta-alpha motif as that present in the varphi29 connector. These results allow us to suggest a common architecture related to a basic component of the DNA translocating machinery for several viruses.

Genome function--a virus-world view

By studying viruses one may begin to understand how static genomes can define dynamic processes of development. This talk will describe some of the approaches we are taking, using computer simulations and laboratory experiments, to account for the many molecular-level processes and interactions that occur when a common bacterium, E. coli, is infected by one of its viruses, phage T7. We accounted for processes of phage genome entry, transcription, translation, and DNA replication, including protein-DNA and protein-protein regulatory interactions, and we predicted the dynamics of phage progeny formation. The simulations have enabled us to identify limiting host-cell resources in phage growth, discover novel anti-viral strategies, and suggest frameworks for mining data from global mRNA and protein studies.

A second symmetry mismatch at the portal vertex of bacteriophage T7: 8-fold symmetry in the procapsid core

Like other bacteriophages, T7 has a singular vertex that is the site of a symmetry mismatch involving the portal/connector protein, a 12-fold ring at the vertex site which is also a 5-fold axis for the icosahedral capsid. In the mature virion, a 6-fold-symmetric tail extends outwards from the connector. T7 also has a cylindrical "core" that assembles on the inner surface of the connector during procapsid formation, is retained in the mature virion, and is required for infectivity. We have investigated the core structure by cryo-electron microscopy and image analysis of procapsids and find that it observes 8-fold symmetry. Stoichiometry data indicate that its major constituent is an octamer of gp15.

Molecular Mechanisms In Bacteriophage T7 Procapsid Assembly, Maturation, And Dna Containment

Bacteriophage T7 is a double-stranded DNA bacteriophage that has attracted particular interest in studies of gene expression and regulation and of morphogenesis, as well as in biotechnological applications of expression vectors and phage display. We report here studies of T7 capsid assembly by cryoelectron microscopy and image analysis. T7 follows the canonical pathway of first forming a procapsid that converts into the mature capsid, but with some novel variations. The procapsid is a round particle with an icosahedral triangulation number of 7 levo, composed of regular pentamers and elongated hexamers. A singular vertex in the procapsid is occupied by the connector/portal protein, which forms 12-fold and 13-fold rings when overexpressed, of which the 12-mer appears to be the assembly-competent form. This vertex is the site of two symmetry mismatches: between the connector and the surrounding five gp 10 hexamers; and between the connector and the 8-fold cylindrical core mounted on its inner surface. The scaffolding protein, gp9, which is required for assembly, forms nubbin-like protrusions underlying the hexamers but not the pentamers, with no contacts between neighboring gp9 monomers. We propose that gp9 facilitates assembly by binding to gp10 hexamers, locking them into a morphogenically correct conformation. gp9 is expelled as the procapsid matures into the larger, thinner walled, polyhedral capsid. Several lines of evidence implicate the connector vertex as the site at which the maturation transformation is initiated: in vivo, maturation appears to be triggered by DNA packaging whereby the signal may involve interaction of the connector with DNA. In the mature T7 head, the DNA is organized as a tightly wound coaxial spool, with the DNA coiled around the core in at least four and perhaps as many as six concentric shells.

Fluorescence microscopy of single viral capsids

To build a foundation for the single-molecule fluorescence microscopy of protein complexes, the present study achieved fluorescence microscopy of single, nucleic acid-free protein capsids of bacteriophage T7. The capsids were stained with Alexa 488 (green emission). Manipulation of the capsids' thermal motion was achieved in three dimensions. The procedure for manipulation included embedding the capsids in an agarose gel. The data indicate that the thermal motion of capsids is reduced by the sieving of the gel. The thermal motion can be reduced to any desired level. A semilogarithmic plot of an effective diffusion constant as a function of gel concentration is linear. Single, diffusing T7 capsids were also visualized in the presence of single DNA molecules that had been both stretched and immobilized by gel-embedding. The DNA molecules were stained with ethidium (orange emission). This study shows that single-molecule (protein and DNA) analysis is possible for both packaging of DNA in a bacteriophage capsid and other events of DNA metabolism. The major problem is the maintenance of biochemical activity.

Bacteriophage phiYeO3-12, specific for Yersinia enterocolitica serotype O:3, is related to coliphages T3 and T7

Bacteriophage phiYeO3-12 is a lytic phage of Yersinia enterocolitica serotype O:3. The phage receptor is the lipopolysaccharide O chain of this serotype that consists of the rare sugar 6-deoxy-L-altropyranose. A one-step growth curve of phiYeO3-12 revealed eclipse and latent periods of 15 and 25 min, respectively, with a burst size of about 120 PFU per infected cell. In electron microscopy phiYeO3-12 virions showed pentagonal outlines, indicating their icosahedral nature. The phage capsid was shown to be composed of at least 10 structural proteins, of which a protein of 43 kDa was predominant. N-terminal sequences of three structural proteins were determined, two of them showing strong homology to structural proteins of coliphages T3 and T7. The phage genome was found to consist of a double-stranded DNA molecule of 40 kb without cohesive ends. A physical map of the phage DNA was constructed using five restriction enzymes. The phage infection could be effectively neutralized using serum from a rabbit immunized with whole phiYeO3-12 particles. The antiserum also neutralized T3 infection, although not as efficiently as that of phiYeO3-12. phiYeO3-12 was found to share, in addition to the N-terminal sequence homology, several common features with T3, including morphology and nonsubjectibility to F exclusion. The evidence conclusively indicated that phiYeO3-12 is the first close relative of phage T3 to be described.

Encapsidated conformation of bacteriophage T7 DNA

The structural organization of encapsidated T7 DNA was investigated by cryo-electron microscopy and image processing. A tail-deletion mutant was found to present two preferred views of phage heads: views along the axis through the capsid vertex where the connector protein resides and via which DNA is packaged; and side views perpendicular to this axis. The resulting images reveal striking patterns of concentric rings in axial views, and punctate arrays in side views. As corroborated by computer modeling, these data establish that the T7 chromosome is spooled around this axis in approximately six coaxial shells in a quasi-crystalline packing, possibly guided by the core complex on the inner surface of the connector.

The conformation of packaged bacteriophage T7 DNA: informative images of negatively stained T7

Within the icosahedral protein outer shell of bacteriophage T7, a 40-kbp DNA genome occupies a cavity also occupied by a protein cylinder that projects into the DNA from the outer shell. However, neither the internal cylinder nor separately resolved DNA segments are revealed in the conventional negatively stained specimens of intact bacteriophage T7. In the present study, a procedure of negative staining is used that reveals both internal proteins and separately resolved segments of packaged DNA during electron microscopy of intact particles of a hybrid T7 bacteriophage; the hybrid is genetically T7, except for a tail fiber gene that has a segment from the T7-related bacteriophage, T3. The negatively stained packaged DNA segments of this hybrid bacteriophage are found to be wrapped around the axis of the internal cylinder. To obtain additional information about the conformation of packaged T7 DNA, electron microscopy is performed of negatively stained capsids that are incompletely filled with DNA (ipDNA-capsids); a procedure is described for improved isolation of ipDNA-capsids from lysates of hybrid bacteriophage T7-infected cells. The packaged DNA segments of ipDNA-capsids are found not to be wrapped around any axis. Images of ipDNA-capsids are explained by the hypothesis that DNA does not achieve its wrapped condition until the capsid is more than 40% full of DNA. Wrapping via folding is, therefore, proposed to explain the images of DNA packaged in bacteriophage T7.

Relative apparent synapomorphy analysis (RASA). I: The statistical measurement of phylogenetic signal

We have developed a new approach to the measurement of phylogenetic signal in character state matrices called relative apparent synapomorphy analysis (RASA). RASA provides a deterministic, statistical measure of natural cladistic hierarchy (phylogenetic signal) in character state matrices. The method works by determining whether a measure of the rate of increase of cladistic similarity among pairs of taxa as a function of phenetic similarity is greater than a null equiprobable rate of increase. Our investigation of the utility and limitations of RASA using simulated and bacteriophage T7 data sets indicates that the method has numerous advantages over existing measures of signal. A first advantage is computational efficiency. A second advantage is that RASA employs known methods of statistical inference, providing measurable sensitivity and power. The performance of RASA is examined under various conditions of branching evolution as the number of characters, character states per character, and mutations per branch length are varied. RASA appears to provide an unbiased and reliable measure of phylogenetic signal, and the general approach promises to be useful in the development of new techniques that should increase the rigor and reliability of phylogenetic estimates.

Assembly of T7 capsids from independently expressed and purified head protein and scaffolding protein

Prohead-like capsid shells containing the scaffolding and head proteins of bacteriophage T7 were isolated after both proteins were expressed from the cloned genes in the same cell. When the head-tail connector protein was also expressed, the isolated capsids contained neither connector nor scaffolding protein and resembled mature phage capsids rather than proheads. However, only a small fraction of the head protein was converted to stable capsid structures in either case. Purified scaffolding protein (expressed individually from the cloned gene) appeared to be a monomer in solution; purified head protein appeared to be a tetramer. The purified proteins reacted in the presence of polyethylene glycol or dextran to produce prohead-like capsid shells and also polycapsids consisting primarily of head protein, similar to the polycapsids observed after infection by T7 mutants lacking connector or core proteins. Neither capsids nor polycapsids were produced in the absence of scaffolding protein. Polycapsids were usually the predominant product even when scaffolding protein was in excess, and a small fraction of scaffolding protein catalyzed the conversion of an excess of head protein to polycapsids. Our results suggest that the first step in the natural pathway to prohead formation is the assembly of incomplete prohead shells, which are normally closed by insertion of a connector-core complex. In the absence of a functional connector-core complex, incomplete capsid shells apparently react further to form polycapsids or completely closed capsid shells.

A protein linkage map of Escherichia coli bacteriophage T7

Genome sequencing projects are predicting large numbers of novel proteins, whose interactions with other proteins must mediate the function of cellular processes. To analyse these networks, we used the yeast two-hybrid system on a genome-wide scale to identify 25 interactions among the proteins of Escherichia coli bacteriophage T7. Among these is a set of six interactions connecting proteins that function in DNA replication and DNA packaging. Remarkably, two genes, arranged such that one entirely overlaps the other and uses a different reading frame, encode interacting proteins. Several of the interactions reflect intramolecular associations of different domains of the same polypeptide, suggesting that the two-hybrid assay may be useful in the analysis of protein folding. This global approach to protein-protein interactions may be applicable to the analysis of more complex genomes whose sequences are becoming available.