The grid-cell-culture technique: the direct examination of virus-infected cells and progeny viruses

The association of epizootic hemorrhagic disease virus with the cytoskeleton

The cells of eukaryotes are characterized by a filamentous network referred to as the cytoskeleton. It is believed that most animal viruses use the cytoplasmic or nuclear skeletal matrix during at least part of their replication cycle.

Transmission electron microscopic studies of thin sections of cells infected with epizootic hemorrhagic disease virus(EHDV), a double-stranded RNA virus belonging to the Reoviridae family, have demonstrated the presence of virus-like particles, virus-specific fibrils and tubules, and viral inclusion bodies. Studies of bluetongue virus (a closely related orbivirus) by Eaton et al. and Hyatt et al. confirmed that these virus-specific structures bind to the cytoskeleton of infected cells, and facilitated study of their viral protein content using monoclonal antibodies in immunogold labeling procedures, This study describes cytoskeletal involvement in the replication of EHDV.

The grid-cell-culture technique, preparation of cytoskeletons, and immunolabeling procedure were those described by Hyatt et al. Grids were dehydrated in a graded alcohol series, critical point dried in amyl acetate and CO2, coated with carbon and examined with a Philips LS 410 transmission electron microscope operating at 60 kv.

Genomic characterisation of Wongabel virus reveals novel genes within the Rhabdoviridae

Viruses belonging to the family Rhabdoviridae infect a variety of different hosts, including insects, vertebrates and plants. Currently, there are approximately 200 ICTV-recognised rhabdoviruses isolated around the world. However, the majority remain poorly characterised and only a fraction have been definitively assigned to genera. The genomic and transcriptional complexity displayed by several of the characterised rhabdoviruses indicates large diversity and complexity within this family. To enable an improved taxonomic understanding of this family, it is necessary to gain further information about the poorly characterised members of this family. Here we present the complete genome sequence and predicted transcription strategy of Wongabel virus (WONV), a previously uncharacterised rhabdovirus isolated from biting midges (Culicoides austropalpalis) collected in northern Queensland, Australia. The 13,196 nucleotide genome of WONV encodes five typical rhabdovirus genes N, P, M, G and L. In addition, the WONV genome contains three genes located between the P and M genes (U1, U2, U3) and two open reading frames overlapping with the N and G genes (U4, U5). These five additional genes and their putative protein products appear to be novel, and their functions are unknown. Predictive analysis of the U5 gene product revealed characteristics typical of viroporins, and indicated structural similarities with the alpha-1 protein (putative viroporin) of viruses in the genus Ephemerovirus. Phylogenetic analyses of the N and G proteins of WONV indicated closest similarity with the avian-associated Flanders virus; however, the genomes of these two viruses are significantly diverged. WONV displays a novel and unique genome structure that has not previously been described for any animal rhabdovirus.

Imaging of the varicella zoster virion in the viral highways: comparison with herpes simplex viruses 1 and 2, cytomegalovirus, pseudorabies virus, and human herpes viruses 6 and 7

Imaging by scanning electron microscopy (SEM) can provide insight into viral egress. At a low magnification level, varicella zoster virions (VZV) emerge from an infected cell surface in a distinctive pattern previously described as "viral highways." Viral highways consist of thousands of particles arranged in linear pathways across the syncytial surface. This egress pattern has not been described with other herpesviruses, but a systematic analysis has not been performed. Therefore, the characteristic arrangement of VZV egress was compared with that of six other members of the herpes virus family, including herpes simplex virus (HSV) types 1 and 2, human cytomegalovirus (CMV), pseudorabies virus (PRV), and human herpesvirus types 6 and 7 (HHV-6 and HHV-7). Only VZV-infected cells exhibited viral highways. Subsequent SEM examination of VZ virions at an ultra high-resolution revealed that more than 70% were aberrant. Further imaging of the other herpesviruses demonstrated that VZV structure was more closely related to PRV than HSV-1 or HSV-2. Finally, it is noted that the individual members of the herpesvirus family have distinguishable SEM profiles.

Immunocytochemical characterization of viruses and antigenic macromolecules in viral vaccines

Gold immunolabeling combined with negative staining (GINS) provides a valuable immunocytochemical approach that allows a direct ultrastructural definition of all viral vaccine constituents that share common antigenic features with pathogenic viral particles. These results have implications for the development of viral vaccines since it has been demonstrated that incomplete viral particles such as natural empty capsides and Rotavirus-like particles lacking the infective genome are potential candidates for the production of neutralizing antibodies. Furthermore comparative results of the application of GINS to either inactivated vaccines or unfixed samples provide direct evidence that even after inactivation specific antigenic sites are still available for gold immunolabeling.

Ultrastructure of Hendra virus and Nipah virus within cultured cells and host animals

The ultrastructure of Hendra and Nipah viruses is described in cultured cells, pigs, horses and humans. Differences in ultrastructure between the viruses are evident within infected cell cultures and lungs from infected amplifier hosts. These differences are important in viral identification and differentiation and understanding the pathogenesis of disease.

The life-cycle of human immunodeficiency virus type 1

The life-cycle of human immunodeficiency virus type 1 (HIV-1) has been studied using several techniques including immunoelectron microscopy and cryomicroscopy. The HIV-1 particle consists of an envelope, a core and the region between the core and the envelope (matrix). Virus particles in the extracellular space are observed as having various profiles: a central or an eccentric round electron-dense core, a bar-shaped electron-dense core, and immature doughnut-shaped particle. HIV-1 particles in the hydrated state were observed by high-resolution electron cryomicroscopy to be spherical and the lipid membrane was clearly resolved as a bilayer. Projections around the circumference were seen to be knob-like. The shapes and sizes of the projections, especially the head parts, were found to vary with each projection. HIV-1 cores were isolated with a mixture of Nonidet P40 and glutaraldehyde, and were confirmed to consist of HIV-1 Gag p24 protein by immunogold labelling. On infection, the HIV-1 virus was found to enter the cell in two ways: membrane fusion and endocytosis. After viral entry, no structures resembling virus particles could be seen in the cytoplasm. In the infected cells, positive reactions by immunolabelling suggest that HIV-1 Gag is produced in membrane-bound structures and transported to the cell surface by the cytoskeletons. A crescent electron-dense layer is then formed underneath the cell membrane. Finally, the virus particle is released from the cell surface and found extracellularly to be a complete virus particle with an electron-dense core. However, several cell clones producing defective mature, doughnut-shaped (immature) or teardrop-shaped particles were found to be produced in the extracellular space. In the doughnut-shaped particles, Gag p17 and p24 proteins exist facing each other against an inner electron-dense ring, suggesting that the inner ring consists of a precursor Gag protein showing a defect at the viral proteinase.

Characterisation of a novel lyssavirus isolated from Pteropid bats in Australia

A novel lyssavirus isolated from Pteropid bats in Australia (Australian Bat Lyssavirus, ABLV) has been characterised using gene sequence analyses, electron microscopy and a panel of monoclonal antibodies. Electron microscopic examination of Pteropid bat and mouse brain material as well as virus isolated from tissue culture medium, showed the presence of bullet-shaped rhabdovirus particles and structures characteristic of lyssavirus. Analysis using nucleocapsid (N) specific monoclonal antibodies, showed a strong relationship between this new lyssavirus and serotype 1 rabies. The nucleotide sequence of the prototype strain of ABLV was determined from the initiator methionine codon for the nucleocapsid protein (N protein) to the amino terminus of the polymerase gene (L protein), a distance of 5344 nucleotides. Comparisons of the deduced N, phosphoprotein (P), matrix protein (M), and glycoprotein (G) proteins showed that ABLV was more closely related to serotype 1 classic rabies viruses than to other members of the Lyssavirus genus. The percent relatedness of the ABLV proteins when compared to the cognate proteins of PV (Pasteur vaccine strain) rabies was 92, 75, 87 and 75% for the N, P, M and G proteins, respectively. Phylogenetic studies of N protein sequences showed clearly that ABLV is an unrecognised member of the Lyssavirus genus and represents a new genotype, genotype 7.

EHDV-1, a new Australian serotype of epizootic haemorrhagic disease virus isolated from sentinel cattle in the Northern Territory

In 1992, a virus (DPP2209) isolated from sentinel cattle located at Coastal Plains Research Station, latitude 12 degrees 39'S, longitude 131 degrees 20'E, approximately 60 km east of Darwin, Northern Territory. This virus was identified as a serotype of epizootic haemorrhagic disease (EHD) of deer virus previously undescribed in Australia. An additional 17 isolation of this virus were made from eight animals during the period February to May. Electron microscopic studies showed the presence of orbivirus-like structures. Serogrouping ELISA, indirect immunofluorescence assay and the serogrouping plaque reduction neutralisation test indicated the virus was a member of the epizootic haemorrhagic disease serogroup. Serotype specific plaque reduction neutralisation tests, indicated the virus was a member of the epizootic haemorrhagic disease serogroup not previously isolated in Australia. Analysis of the VP3 gene confirmed this observation. Cross neutralisation testing of the isolate with known epizootic haemorrhagic disease serotype viruses including endemic Australian and exotic strains identified isolate DPP2209 as epizootic haemorrhagic disease virus serotype 1.

Ultrastructure of equine morbillivirus

The ultrastructure of the equine morbillivirus (EMV) which was implicated in the death of one human and fourteen horses in Queensland, Australia during September 1994 and a 36 year old man from Queensland in October 1995 is described. The ultrastructure of the virus and the intracellular virus-specific structures are characteristic for the family Paramyxoviridae. Cytoplasmic nucleocapsids were observed within the infected cells monolayers, endothelial cells (lung) of infected horses and the neurons within the brain of the 36 year old Queensland man. Aggregates of smaller nucleocapsid-like structures were also observed within the brain of the same man; these did not react with sera from recovered EMV-infected horses or from a recovered EMV-infected human. Co-examination of rinderpest virus (RPV), bovine parainfluenza-3 (BPIV-3), human respiratory virus (HRSV) and Sendai virus revealed that their envelope-associated surface projections are equivalent in length to the 15 nm spikes of EMV. EMV differed from these other viruses in that the majority of virions possessed surface projections of two distinct lengths (18 and 15 nm). Further ultrastructural examinations of plaque purified EMV revealed a small percentage of EM viruses possessed a mixed array of surface projections indicating that the 'double-fringed' (DF) particles may be the result of a post-translational modification(s).

Topography and immunogenicity of bluetongue virus VP7 epitopes

The core of bluetongue virus (BTV) consists of ten dsRNA viral genome segments and five proteins, including two major (VP7 and VP3) and three minor (VP1, VP4 and VP6) components. The major core protein VP7 is believed to be an important structural constituent because it interacts, not only with the underlying core protein VP3, but also with two outer capsid proteins (VP2 and VP5). In this communication we summarise data on the mapping of at least six different epitopes of VP7 distributed along the molecule. Two of the six epitopes have not been mapped previously. The accessibility of these epitopes in intact virions and core particles was analysed using immunoelectron microscopy. The epitope located near the N-terminus of VP7 was accessible at the surface of intact virions and core particles. Epitopes in other parts of the VP7 molecule were detected weakly in core particles but not in intact virions. These results support the proposal that VP7 molecules are orientated with their N-terminus accessible on the surface of either the particle or at least one of the three different channels observed by cryoelectron microscopy in the outer capsid layer. Analysis of the immune response to BTV-infected or -immunised sheep and rabbits to three selected epitopes, which are located in different regions of the VP7 molecule, demonstrated that all of them were recognised by the animals tested. These results provided further molecular evidence suggesting that VP7 is indeed a major immunogenic antigen ideal for BTV antibody detection.

Use of a gene-targeted phage display random epitope library to map an antigenic determinant on the bluetongue virus outer capsid protein VP5

We describe the use of a gene-targeted random epitope library for the mapping of antigenic determinants. A DNA clone encoding the target antigen was digested randomly with DNase I to generate a population of DNA fragments of different sizes and sequences. After size fractionation, small DNA fragments (100-200 bp) were isolated and cloned into the phage expression vector fUSE2 to form an expression library displaying random polypeptide sequences as fusion proteins at the N terminus of the phage gene III protein. This library, termed a gene-targeted random epitope library to distinguish it from totally random synthetic epitope libraries, was then screened by affinity selection for recombinant phages which were specifically bound by the antibody of interest. Using this approach, we have mapped a monoclonal antibody (mAb)-defined epitope on the bluetongue virus outer capsid protein VP5. This epitope is not accessible on the intact virus surface, but is recognised by the immune system of sheep and cattle during virus infection. Although the example given here utilised a DNA fragment of known sequence and the library was screened for a mAb-defined epitope, the strategy described should be equally applicable to genes of unknown sequence and for screening of epitopes using polyclonal antibodies. The approach can also be extended to identify immunodominant epitope from much more complex genome-targeted random epitope library for virus, bacteria and eukaryotic organisms. Other applications of recombinant phages expressing defined immunodominant epitopes include serodiagnosis and vaccine development.

The orbivirus genus. Diversity, structure, replication and phylogenetic relationships

The general properties of the orbiviruses have been examined at the physical, structural and molecular level. At the structural level, the orbiviruses (with the exception of the Kemerovo serogroup) appear similar. The replicative events are also similar, however differences in the ultrastructure of virus-specific structures and their association with components of the host cell have been observed. Further research in this area may be used to differentiate between the serogroups and even some serotypes, of orbiviruses. At the molecular level the properties of the genome can be used to determine relationships between members of the orbivirus genus. These relationships are revealed using a variety of techniques including serology and gene sequence analysis. Not only are the different serological responses to gene products present in the mature virus particle used for differential diagnosis, but the gene sequences themselves can also be utilized. Understanding of the relationships between these viruses is progressing to the point that insights into orbivirus molecular epidemiology is now possible.

The use of immuno-gold silver staining in bluetongue virus adsorption and neutralisation studies

The immuno-gold-silver staining (IGSS) technique was used in scanning electron microscopy for the detection and semi-quantitation of low copy antigens on the surface of cells. The methodology was exploited in experiments designed to examine the interaction of small numbers of virus particles with the surface of susceptible host cells. Using bluetongue virus (BTV) as an example, IGSS procedures confirmed that maximum adsorption occurred within 60 min and that adsorbed virus particles were distributed randomly on the surface of the cell. Neutralising antibody did not prevent binding of BTV to the plasma membrane, but abrogated virus uptake. The use of IGSS in the study of virus-cell interactions was validated by transmission electron microscopy and classical biochemical experiments utilising radioactively-labelled virus.

The detection of intracellular bluetongue virus particles within ovine erythrocytes

1. We report here a simplified method for detecting viruses and other antigenic agents in red blood cells (RBCs). Using a nonionic detergent to prepare cytoskeletons, the interior of RBCs can be scanned rapidly using immunoelectron microscopy. 2. In this study, RBCs from bluetongue (BLU) virus-infected sheep were adsorbed directly onto Formvar-coated, gold electron microscope grids. 3. Cytoskeletons were prepared and then probed using a monoclonal antibody to VP 7, a structural BLU-virus protein and Protein-A gold. 4. Of the ca 32,000 RBCs that were examined from BLU virus-infected sheep, 34 (0.106%) contained labelled BLU virus particles. 5. No labelled particles were observed in any of ca 8000 RBCs taken prior to BLU virus inoculation of sheep. 6. If the antigenic BLU virus particles (which may be viral cores) are in fact infectious, this method of sequestration of virus within RBCs could contribute to the prolonged viremia typical of this arboviral disease, which is known to occur concurrently with circulating neutralizing antibody.

A bluetongue serogroup-reactive epitope in the amino terminal half of the major core protein VP7 is accessible on the surface of bluetongue virus particles

Immunoelectron microscopy has been used to confirm that the core protein VP7 is accessible on the surface of bluetongue virus (BTV) particles. Monospecific antibodies generated to vaccinia virus-expressed VP7 and an anti-VP7 monoclonal antibody (MAb 20E9) bound to native virus particles and were localized by protein A-gold. In contrast, MAb 20E9 labeled directly with gold failed to gain access and bind, suggesting that VP7 is neither adventitiously adsorbed to the virion surface nor exposed in a manner such as protrusion through the outer capsid. Thus the surface layer of BTV may be considered as a net which only partially obscures the underlying core particle. Sequencing of VP7 revealed it to be an extremely hydrophobic protein, 350 amino acids in length with cysteine residues at positions 15, 65, and 154. Examination of VP7 in the cytosol of cells infected with either BTV or a vaccinia virus recombinant expressing VP7 indicated that the protein may exist as an oligomer, whose constituent monomers are not linked by intermolecular disulfide bonds. The cysteine residues in sodium dodecyl sulfate (SDS)-denatured, dithiothreitol (DTT)-treated VP7 were labeled with the fluorescent iodoacetamide AEDANS and the protein was cleaved by V8 protease. The size of the labeled peptides and knowledge of the location of potential V8 cleavage sites suggested that the enzyme cleaved VP7 at three locations (glutamic acid residues at positions 61, 104 (or 108), and 132 (or 134 or 135). Analysis of the fluorescent peptides generated by V8 protease cleavage of VP7 labeled with AEDANS in the absence of DTT (i.e., with any putative intramolecular disulfide bonds intact) suggested that the cysteine at position 154 was the only one accessible to AEDANS. The cysteines at positions 15 and 65 may therefore be linked via a disulfide bond. Denaturation of VP7 with SDS did not eliminate the capacity of the protein to bind MAb 20E9. However, the sensitivity of the epitope to reduction and acetylation and its resistance to either of these processes alone suggest that it may be located near a disulfide bond linking cysteines at positions 15 and 65. Confirmation that the epitope lay in the amino-terminal half of the VP7 came from immunoelectron microscopy experiments in which thin sections of bacteria expressing the complete VP7 and the amino-terminal half were probed with MAb 20E9 and protein A-gold.

Virological applications of the grid-cell-culture technique

Whole mounts of intact virus-infected cells have been used for several decades to examine virus-cell relationships and virus structure. The general concept of studying virus structure in association with the host cell has recently been expanded to reveal interactions between viruses and the cytoskeleton. The procedure permits utilization of immuno-gold protocols using both the transmission and scanning electron microscopes. The grid-cell-culture technique is reviewed to explain how it can be exploited to provide valuable information about virus structure and replication in both diagnostic and research laboratories. The use of the technique at the research level is discussed using bluetongue virus as a model. The procedure can provide basic structural information about intact virions and additional data on the intracellular location of viruses and virus-specific structures and about the mode of virus release from infected cells. Application of immunoelectron microscopy reveals information on the protein composition of not only released virus particles but also cell surface and cytoskeletal-associated viruses and virus-specific structures. Collectively, this simple and physically gentle technique has provided information which would otherwise be difficult to obtain.

The release of bluetongue virus from infected cells and their superinfection by progeny virus

Immunoelectron microscopy using an anti-VP2 monoclonal antibody complexed to colloidal gold has been used to study the mechanism of bluetongue virus (BTV) release from infected cells. Examination of the BTV-infected cell surface revealed that viruses are released both as enveloped particles, by budding through the plasma membrane, and as nonenveloped particles by "extrusion" through the membrane. Particles being released and those remaining on the cell surface retain an association with the cortical layer of the cytoskeleton. Analyses of virus particles released from infected cells and the intracellular viruses in the cytosol and attached to the cytoskeleton indicate that although the three populations have similar particle to infectivity ratios they differ in their ability to bind gold-labeled anti-VP2 antibody. The fact that released viruses bind less antibody than intracellular viruses suggests that virus release from infected cells may be associated with either a loss of VP2 or a rearrangement of the virus outer coat which obscures a proportion of the reactive epitopes on the virus surface. Electron microscopic observations also indicated that, in addition to virus release, events at the plasma membrane resulted in the uptake of progeny virus by endocytosis. Elevation of intraendosomal/lysosomal pH by lysomotropic bases and an acidic ionophore inhibited BTV replication when added to cells concurrently with the virus. Addition of such agents to infected cells at 4 hr p.i. decreased both the maximum titer of released virus and the rate at which virus antigen was synthesized in infected cells. Addition of anti-BTV antiserum 4 hr p.i. also resulted in a decreased rate of intracellular virus antigen accumulation. These results suggest that superinfection of BTV-infected cells by progeny virions effectively increases the multiplicity of infection and enhances the kinetics of BTV replication.

Morphogenesis of a bluetongue virus variant with an amino acid alteration at a neutralization site in the outer coat protein, VP2

Neutralization-resistant variants of bluetongue virus, selected with a monoclonal antibody to the outer coat protein VP2, have been used to delineate a neutralization epitope on the VP2 protein. Comparison of the RNA 2 sequence of four variants with that of the wild-type virus indicated that each variant contained a single nucleotide substitution which in turn resulted in a single amino acid alteration in VP2. The changes were clustered within a span of eight amino acids at positions 328 to 335 in the VP2 protein. In addition, analyses of cells infected with wild-type and a variant virus V35B2 have provided information on the site of VP2 addition to virus particles during morphogenesis. Electron microscopic examination revealed few virus-like particles around virus inclusion bodies (VIB) in wild-type virus-infected cells and cytoskeletons. In contrast, VIB in cells infected with the neutralization-resistant variant V35B2 were surrounded by particles identified as virus cores on the basis of their size and morphology. Probing of cytoskeletons with gold-labeled anti-VP2 monoclonal antibody revealed that in wild-type virus-infected cells the antibodies reacted weakly with VIB and only at locations where virus particles appeared to be leaving. The core-like particles surrounding VIB in V35B2-infected cells labeled very weakly with the anti-VP2 antibody. In contrast, wild-type and V35B2 virus particles which bound to the cytoskeleton at locations distal to VIB and those outside the infected cell bound significant amounts of antibody. These results suggest that although some VP2 may be added to developing virus particles at the periphery of VIB, the remainder of the VP2 protein is added outside the VIB either in the cytosol or following attachment of the particles to the cytoskeleton.

Localization of the nonstructural protein NS1 in bluetongue virus-infected cells and its presence in virus particles

Seven monoclonal antibodies to the nonstructural protein NS1 of an Australian isolate of bluetongue virus (BTV) have been used in immunofluoresence and immunogold procedures to locate NS1 in virus-infected cells and cytoskeletons. The antibodies fall into three groups indicating that NS1 contains at least three antigenic sites. One group consists of four antibodies which react solely with cytoskeleton-associated virus-specific tubules. A second group contains one antibody which reacts with cytoskeleton-associated virus particles, released viruses, and purified virus and core particles. Two antibodies constituting a third group react with both tubules and cytoskeleton-associated and released virus particles. NS1 was found in [35S]methionine-labeled, purified virus and core particles. Immunofluorescence tests reveal that those antibodies which react with virus particles also bind to cytoskeleton-associated virus inclusion bodies (VIB). The nature of this association was examined by probing cytoskeletons of BTV-infected cells with antibodies to NS1 and protein A-gold. VIB observed in thin sections were not uniformly labeled. Gold was associated with fibrillar arrays found around virus particles either leaving or in close proximity to the VIB. Fibrillar material was not found in association with all virus particles elsewhere in the cell and this suggests that fibril-virus complexes may be intermediate in virus morphogenesis.

Antibody competition studies with gold-labelling immunoelectron microscopy

Competitive studies, involving neutralizing monoclonal antibodies (NTmAbs) to outercoat proteins of Akabane virus were performed by immunoelectron microscopy. The experiments were designed to determine whether the NTmAbs were directed against the same or spatially different epitopes. Characteristics of NTmAbs in direct and indirect gold-labelling studies were determined. It was found that the protein A method gave cross-contamination of the immuno-gold complexes whereas direct conjugation of the NTmAbs to gold probes gave clean, specific and intense labelling. Analysis of dilution curves confirmed that saturation of antigenic sites did not occur and secondly determined the optimum working dilutions for the conjugated probes. The data generated in the preliminary studies enabled reliable results to be obtained from the double-labelling competitive experiment. We found that the 2 NTmAbs were directed to either the same epitope or to 2 separate but neighbouring epitopes where the binding of one NTmAb inhibited the binding of the second. The results demonstrate that if reliable data is to be obtained in double-labelling immunoelectron microscopical studies then experiments must be meticulously designed.