Frog virus 3 replication: induction and intracellular distribution of polypeptides in infected cells

Generation and application of a monoclonal antibody specific for the ORF121 of cyprinid herpesvirus 2

Cyprinid herpesvirus 2 (CyHV-2) is a viral pathogen worldwide and causing high mortality on goldfish and silver crucian carp (Carassius auratus gibelio). In order to establish a stable and sensitive immunological diagnostic approach, the recombinant ORF121 protein encoded by the CyHV-2 ORF121 gene, was selected as a capture antigen to identify cells and tissues infected with CyHV-2 by immunological methods in this study. Firstly, the open reading frame of CyHV-2 ORF121 was cloned into the PGEX-4T-3 vector and expressed in Escherichia coli. Purified recombinant ORF121 protein was then used as an antigen to prepare monoclonal antibodies, and an efficient hybridoma cell line was selected by dot-blot assay. The resulting mAb-3D9 was applied to detect CyHV-2 in infected caudal fin of Carassius auratus gibelio (GiCF) cells and fish tissues by western blotting, immunofluorescence assays and immunohistological asays. The monoclonal antibody could specifically identify CyHV-2 in infected GiCF cells and the gills, the kidney and the spleen tissues, and it could attenuate CPE by CyHV-2 in vitro, suggesting it can be applied for CyHV-2 detection in the crucian carp and ORF121 may be a candidate vaccine against CyHV-2.

Frog Virus 3 Replication: Analysis of Structural and Nonstructural Polypeptides in Infected BHK Cells by Acidic and Basic Two-Dimensional Gel Electrophoresis

Analysis of frog virus 3-infected BHK cells by two-dimensional, acidic and basic gel electrophoresis showed that at least 90 infected cell-specific polypeptides could be detected. These polypeptides represent between 70 and 85% of the coding capacity of the viral genome. The polypeptides were sequentially induced in at least three phases. The virus gradually suppressed host cell polypeptide synthesis during infection, although the synthesis of a few cell polypeptides may be "switched off" early in infection.

Phosphonoacetic Acid inhibition of frog virus 3 replication

Phosphonoacetic acid at concentrations above 200 mug/ml inhibited the replication of frog virus 3 in BHK cells. The inhibition of viral DNA replication observed in these cells was reversible and correlated with the inhibition of the virus-induced DNA polymerase activity in an in vitro assay. The synthesis of frog virus 3-induced late or gamma polypeptides was also inhibited by phosphonoacetic acid, although the early (alpha and beta) polypeptides were unaffected.

Induction of a nonoccluded baculovirus persistently infecting Heliothis zea cells by Heliothis armigera and Trichoplusia ni nuclear polyhedrosis viruses

A nonoccluded singly enveloped baculovirus (baculovirus X) persistently infects Heliothis zea (IMC-HZ-1) cells in culture. Singly enveloped nuclear polyhedrosis viruses from H. zea and Heliothis armigera, and multiply enveloped nuclear polyhedrosis viruses from Trichoplusia ni, Spodoptera frugiperda, and Spodoptera littoralis were all found to induce baculovirus X. Experiments are reported which use metabolic inhibitors and inactivated inducing virus to show that it is probable that a structural component of the virus, most likely a protein, is responsible for inducing baculovirus X. The persistent virus is induced to replicate by uv-inactivated virus but not by heat-inactivated inducing virus. The virus is not induced to replicate by a number of metabolic inhibitors in the absence of an inducing virus. Inhibition of transcription and translation prevents the induction of the persistent virus by an inducing virus. Inhibition of DNA replication has no effect on the induction of the virus. This suggests that the persistent virus genome is present in abundance in all cells.

Comparative genomic analyses of frog virus 3, type species of the genus Ranavirus (family Iridoviridae)

Frog virus 3 (FV3) is the type species member of the genus Ranavirus (family Iridoviridae). To better understand the molecular mechanisms involved in the replication of FV3, including transcription of its highly methylated DNA genome, we have determined the complete nucleotide sequence of the FV3 genome. The FV3 genome is 105903 bp long excluding the terminal redundancy. The G + C content of FV3 genome is 55% and it encodes 98 nonoverlapping potential open reading frames (ORFs) containing 50-1293 amino acids. Eighty-four ORFs have significant homology to known proteins of other iridoviruses, whereas twelve of these unique FV3 proteins do not share homology to any known protein. A microsatellite containing a stretch of 34 tandemly repeated CA dinucleotide in a noncoding region was detected. To date, no such sequence has been reported in any animal virus.

Comparison of the eIF-2alpha homologous proteins of seven ranaviruses (Iridoviridae)

The alpha-subunit of the eukaryotic initiation factor 2 (eIF-2alpha) is a key component of the translation machinery of the cell. In response to cellular stress such as viral infections, eIF-2alpha is phosphorylated by double-stranded RNA-dependent protein kinase (PKR) leading to the inhibition of cellular protein synthesis. The importance of eIF-2alpha as a regulatory mechanism for protein synthesis is illustrated by the wide variety of strategies employed by viruses to down-regulate PKR. Thus, Vaccinia virus encodes K3L protein, which resembles eIF-2alpha and acts as a pseudo-substrate inhibitor of PKR. Nucleotide sequencing of the genome of epizootic haematopoietic necrosis virus (EHNV), a member of the genus ranavirus of Iridoviridae, has revealed an eIF-2alpha equivalent gene. We have cloned and sequenced eIF-2alpha genes of several iridoviruses of fishes and frogs. The eIF-2alpha open reading frames and deduced proteins of the iridoviruses investigated exhibit a high degree of homology of both nucleotide and amino acid sequences. At the N-terminus, the iridoviral eIF-2alpha shows significant homology to the N-termini of cellular initiation factor 2-alpha of various species, to full-length poxviral eIF-2alpha proteins, and to the S1 domain of ribosomal proteins. Comparison of amino acid sequences of corresponding iridoviral proteins with eIF-2alpha homologous proteins of poxviruses and eukaryotes has revealed a high conservation of motifs. A phylogenetic analysis of eukaryotic eIF-2alpha and poxvirus and iridovirus eIF-2alpha sequences has demonstrated the relationship of these iridoviruses. In order to investigate the role of the eIF-2alpha equivalent, respective genes have been expressed in prokaryotic and eukaryotic (insect, fish and chicken cell) systems. The iridoviral eIF-2alpha protein has a molecular weight of 31 kDa and is cytoplasmic. The cellular and viral protein synthesis of iridoviruses is probably regulated by a mechanism similar to that of Vaccinia virus. Frog-virus 3, the type species of the genus ranavirus of Iridoviridae, has a unique translational efficiency and, moreover, down-regulates the cellular protein synthesis of infected cells.

Viruses of lower vertebrates

Viruses of lower vertebrates recently became a field of interest to the public due to increasing epizootics and economic losses of poikilothermic animals. These were reported worldwide from both wildlife and collections of aquatic poikilothermic animals. Several RNA and DNA viruses infecting fish, amphibians and reptiles have been studied intensively during the last 20 years. Many of these viruses induce diseases resulting in important economic losses of lower vertebrates, especially in fish aquaculture. In addition, some of the DNA viruses seem to be emerging pathogens involved in the worldwide decline in wildlife. Irido-, herpes- and polyomavirus infections may be involved in the reduction in the numbers of endangered amphibian and reptile species. In this context the knowledge of several important RNA viruses such as orthomyxo-, paramyxo-, rhabdo-, retro-, corona-, calici-, toga-, picorna-, noda-, reo- and birnaviruses, and DNA viruses such as parvo-, irido-, herpes-, adeno-, polyoma- and poxviruses, is described in this review.

Is the major capsid protein of iridoviruses a suitable target for the study of viral evolution?

Iridoviruses are large cytoplasmic DNA viruses that are specific for different insect or vertebrate hosts. The major structural component of the non-enveloped icosahedral virus particles is the major capsid protein (MCP) which appears to be highly conserved among members of the family Iridoviridae, Phycodnaviridae, and African swine fever virus. The amino acid sequences of the known MCPs were used in comparative analyses to elucidate the phylogenic relationships between different cytoplasmic DNA viruses including three insect iridoviruses (Tipula iridescent virus, Simulium iridescent virus, Chilo iridescent virus), seven vertebrate iridoviruses isolated either from fish (lymphocystis disease virus, rainbow trout virus, European catfish virus, doctor fish virus), amphibians (frog virus 3), or reptiles (turtle virus 3, turtle virus 5), one member of the family Phycodnaviridae (Paramecium bursaria Chlorella virus type 1), and African swine fever virus. These analyses revealed that the amino acid sequence of the MCP is a suitable target for the study of viral evolution since it contains highly conserved domains, but is sufficiently diverse to distinguish closely related iridovirus isolates. Furthermore the results suggest that a substantial revision of the taxonomy of iridoviruses based on molecular phylogeny is required.

RNA transcript mapping of the Wiseana iridescent virus genome

The replication of Wiseana iridescent virus (WIV) was studied in Lymantria dispar tissue culture cells. Using a combination of [35S]methionine pulse-labeling and Northern blotting with WIV DNA probes, a transcriptional map of the genome was constructed. WIV has a wide dispersal of immediate-early genes with seven different regions identified. WIV has been reported to have extensive repetitive DNA sequences but no early transcription was observed in these regions. Although fine-mapping is required, some early regions (Bam L and Eco O) have been identified which are transcriptionally active at 6- and 12-h but are shut down by 24 h. These regions could provide probes for early genes and the hypothesized switch from nuclear to cytoplasmic replication for iridoviruses.

Morphogenesis of African swine fever virus in monkey kidney cells after reversible inhibition of replication by cycloheximide

The late cytoplasmic phases of African swine fever virus (ASFV) morphogenesis in monkey kidney cells have been studied by transmission electron microscopy, focusing attention on the synthesis of viral envelopes. Morphogenesis was studied after reversible cycloheximide blockage of monkey kidney cells infected with ASFV. ASFV appears to synthesize its external and internal envelopes within the cellular cytoplasm, at the same time as the capsid is formed, with intracellular and extracellular virions showing similar structure and polypeptide composition.

Metabolism of host and viral mRNAs in frog virus 3-infected cells

Treatment of purified frog virus 3 (FV3) with nonionic detergent and high salt released an endoribonucleolytic activity and confirmed earlier findings of a virion-associated endonuclease. This observation, coupled with evidence implicating host and viral message destabilization in herpesvirus and poxvirus biogenesis, raised the question of what role, if any, mRNA degradation plays in FV3 replication. To answer this question, Northern analyses of mock- and virus-infected cells were performed using probes for representative host and viral messages. These studies demonstrated that the steady state level of host messages progressively declined during the course of productive FV3 infection, whereas the steady state level of viral messages was not affected. To determine whether the decline in the steady state level of host mRNA was due to virus-induced degradation or to normal turnover coupled to virus-mediated transcriptional shut-off, actin mRNA levels were examined in mock- and virus-infected cells in the presence and absence of actinomycin D. Under these conditions, actin mRNA levels declined more quickly in actinomycin D-treated, virus-infected cells, than in mock-infected cells incubated in the presence of actinomycin D suggesting that the decline in the steady state level of actin mRNA was due to degradation. However, although it appears as if host message degradation is responsible for virus-mediated translational shut-off, the ability of heat-inactivated FV3 to block cellular translation without destabilizing cellular messages indicates that message degradation is not required for translational inhibition. As noted above, the degradation of early FV3 messages was not involved in controlling the transition from early to late gene expression. Furthermore, the presence of abundant, but nontranslated, early messages late in infection, coupled with the inefficient translation of late messages in vitro supported earlier suggestions that FV3 gene expression is controlled, at least in part, at the translational level. Taken together, these results suggest that FV3 regulates gene expression in a unique manner and may be a good model to examine the mechanics of translational control.

Glycosylated components induced in African swine fever (ASF) virus-infected Vero cells

African swine fever (ASF) virus production was inhibited more than 100 fold by 5 mM glucosamine, 2 mM 2-deoxyglucose and 3 microM tunicamycin. ASF virus induced in Vero cells the synthesis of 19 glycosylated components of molecular weights ranging from 9K to 220K, the major ones being those of 9K, 13K, 14K, 74K and 220K. At least five of the induced glycosylated components, of molecular weights 13K, 33K, 34K, 38K and 220K, were probably virus-coded glycoproteins, as suggested by a comparative analysis of the time course of synthesis and the antigenicity of these components in extracts from [35S]methionine or [14C]glucosamine-labeled infected cells. The non-protein glycosylated components present in extracellular ASF virus particles had a cellular origin.

Identification of the glycoproteins of lymphocystis disease virus (LDV) of fish

Analysis of highly purified fish Lymphocystis Disease Virus (LDV), strain Leetown NFH, by three different methods, namely periodic Acid Schiff reaction, radiolabelling with tritiated fucose and N-acetyl-D-glucosamine and staining with three lectins, indicated that ten glycoproteins were associated with the virus structure. Six of them were detected by all of the three methods, three by both radiolabelling and lectin staining but only one by the lectin technique. Localization of these glycoproteins at the surface or inside the virion is discussed.

Thermosensitivity of frog virus 3 genome expression: defect in early transcription

The influence of temperature on the transcription of the frog virus 3 genome was studied in CHO cells infected both at 29 and at 37 degrees, the nonpermissive temperature for virus multiplication. It was definitely established that late genes were not transcribed at 37 degrees. Although immediate early genes were expressed at 37 degrees, their transcription was altered but there was no sequestration of mRNAs in the nucleus which could impair their translation; these viral mRNAs were also efficiently translated in vitro. These results indicate that an immediate early viral protein involved in the transcription of delayed early genes is likely to be thermosensitive. Furthermore, one event taking place at the very beginning of the infection, possibly related to the activity of a viral structural component, facilitates the transcription of immediate early genes at 29 degrees and this step is partially impaired at 37 degrees.

Restriction of frog virus 3 polypeptide synthesis to immediate early and delayed early species by supraoptimal temperatures

Multiplication of frog virus 3 (FV 3) occurs in mammalian cells provided they are incubated at temperatures lower than 33 degrees. The expression of the viral genome at supraoptimal temperatures was followed by analyzing the polypeptides produced in CHO-infected cells and comparing with those obtained under restrictive conditions provoked by amino acid analogs or metabolic inhibitors. Late polypeptides were not detected at 33 degrees and the number of delayed early species decreased gradually with increasing temperatures consequently the synthesis of all delayed early proteins was not turned on in response to a unique event. At 37 degrees the synthesis was limited to the immediate early species, i.e., the proteins synthesized after cycloheximide reversal. Temperature shift experiments suggested that delayed early genes remained untranscribed at 37 degrees. Thus, incubation of FV 3-infected mammalian cells at 37 degrees provides a unique way of limiting viral synthesis to immediate early proteins without the side-effect provoked by inhibitors.

Temperature-sensitive mutants of frog virus 3: biochemical and genetic characterization

Nineteen frog virus 3 temperature-sensitive mutants were isolated after mutagenesis with nitrosoguanidine and assayed for viral DNA, RNA, and protein synthesis, as well as assembly site formation at permissive (25 degrees C) and nonpermissive (30 degrees C) temperatures. In addition, mutants were characterized for complementation by both quantitative and qualitative assays. Based on the genetic and biochemical data, the 19 mutants, along with 9 mutants isolated earlier, were ordered into four phenotypic classes which define defects in virion morphogenesis (class I), late mRNA synthesis (class II), viral assembly site formation (class III), and viral DNA synthesis (class IV). In addition, we used two-factor crosses to order 11 mutants, comprising 7 complementation groups, onto a linkage map spanning 77 recombination units.

Protein synthesis in cells infected by chilo iridescent virus (iridovirus, type 6)

Synthesis of the polypeptides induced in CIV-infected cells was studied using radiolabelled methionine in a permissive cell line of Choristoneura fumiferana. Analysis of labelled cell extracts by high resolution polyacrylamide gel electrophoresis (PAGE) revealed the sequential appearance of at least 28 structural and non-structural polypeptides in permissive conditions. This was confirmed by analysis of protein synthesis in non-permissive cell lines of Lymantria dispar, Aedes albopictus or by the use of protein, RNA and DNA synthesis inhibitors in the permissive cell line.

Isolation and characterization of a frog virus 3 variant resistant to phosphonoacetate: genetic evidence for a virus-specific DNA polymerase

A variant of frog virus 3 (FV3) resistant to 200 micrograms/ml phosphonoacetate was isolated, and used to establish that the DNA polymerase induced in FV3-infected cells was virus coded. In addition, inhibitor studies showed that the FV3 polymerase is similar to eukaryotic polymerase alpha in its sensitivity to aphidicolin, and that resistance to phosphonoacetate does not confer cross-resistance to thymidine arabinoside or acycloguanosine.

Localization of frog virus 3 proteins using monoclonal antibodies

Thirty-seven monoclonal antibodies to seven frog virus 3 (FV3) structural proteins were isolated and used to examine the distribution of viral proteins within virions and infected cells. Three monoclonal antibodies, one to the major capsid protein, VP55, and two to VP38 had detectable neutralizing activity suggesting that these proteins are located on the surface of virions. Immunofluorescent studies showed that VP108, VP57, VP55, and VP16 were localized mainly within virus assembly sites, while VP17 was detected in both assembly sites and the surrounding cytoplasm. The abundance of viral structural proteins within assembly sites is consistent with the idea that virion maturation occurs exclusively within assembly sites.

Protein synthesis in Rift Valley fever virus-infected cells

Rift Valley fever virus-induced protein synthesis was examined by polyacrylamide gel electrophoresis and fluorography. Five virus-induced polypeptides were detected, the nucleocapsid protein N, the nucleus-associated nonstructural protein NS1, the glycoproteins G1 and G2, and a protein of molecular weight 80K. The N, G1, G2, and 80K proteins were present in virion preparations. Sequential studies showed that NS1 accumulated in the nucleus as soon as it was formed and readily associated with nuclei partitioned from noninfected cells. The G1 and G2 proteins labelled with [3H]glucosamine and [3H]mannose. NS1 was shown to be the only virus-induced protein which was phosphorylated.

Proteins specified by African Swine Fever virus. IV. Glycoproteins and phosphoproteins

African Swine Fever virus infected MS cells labeled with radioactive 14C-amino acids, 32Pi or [3H]-glucosamine were examined by high resolution sodium dodecylsulfate polyacrylamide gel electrophoresis and showed 43 infected cell polypeptides. Twenty-one of these proteins were present in the nuclear fraction of infected cells. At least 22 of the infected cell polypeptides induced antibodies during natural infections in swine. The pattern of infected cell polypeptides modified by incorporation of showed prosthetic groups that at least 8 polypeptides were phosphorylated and at least three specific viral glycoproteins (A, B and C) were detected by immunoprecipitation. The most highly glycosylated polypeptide corresponds to the structural viral protein VP51.

Frog virus 3 DNA replication occurs in two stages

Viral DNA synthesis in frog virus 3 (FV3)-infected cells occurs both in the nucleus and in the cytoplasm (Goorha et al., Virology 84:32-51, 1978). Relationships between viral DNA molecules synthesized in these two compartments and their role in the virus replication were examined. The data presented here suggest that (i) FV3 DNA replicated in two stages and (ii) nucleus and cytoplasm were the sites of stages 1 and 2 of DNA replication, respectively. Stages 1 and 2 were further distinguished by their temporal appearance during infection and by the sizes of the replicating DNA as determined by sedimentation in neutral sucrose gradients. In stage 1, replicating molecules, between the size of unit and twice the unit length, were produced early in infection (2 h postinfection). In contrast, stage 2 of DNA replication occurred only after 3 h postinfection, and replicating molecules were large concatemers. Results of pulse-chase experiments showed that the concatemeric DNA served as the precursor for the production of mature FV3 DNA. Denaturation of concatemeric DNA with alkali or digestion with S1 nuclease reduced it to less than genome size molecules, indicating the presence of extensive single-stranded regions. Analysis of replicating DNA by equilibrium centrifugation in CsCl gradients after a pulse-chase suggested that these single-stranded regions were subsequently repaired. Based on these and previous data, a scheme of FV3 replication is presented. According to this scheme, FV3 utilizes the nucleus for early transcription and stage 1 of DNA replication. The viral DNA is then transported to the cytoplasm, where it participates in stage 2 DNA replication to form a concatemeric replication complex. The processing of concatemers to produce mature viral DNA and virus assembly also occurs in the cytoplasm. This mode of replication is strikingly different from any other known DNA virus.

Comparison of capsid polypeptides of group B coxsackie-viruses and polypeptide synthesis in infected cells

Capsid polypeptides of all six types (B1-6) of group B coxsackieviruses were compared by high-resolution gel electrophoresis, and synthesis of protein and RNA in B4- or B5-infected HeLA cells was analyzed. Four polypeptides, VP1-4, were detected in each type. Another polypeptide, VP0, slightly larger than VP1, was also detected in trace amounts in some types. VP1-3 showed different but characteristic molecular weights (VP1, 34,500 to 37,000; VP2, 31,000 to 36,000; VP3, 26,000 to 32,500), and presented well-defined and reproducible differences in electrophoretic mobility. The molecular weight of VP4 ranged from 5,000 to 5,500. VP1 was largest in B2 and B4, smallest in B1, and of intermediate size in the other types. VP2 was largest in B4 and smallest in B2; VP3 was largest in B5 and B6 and smallest in B4. In B4- or B5-infected HeLa cells, host protein synthesis began to decline after 2 hours postinfection and was less than 20 percent of the control by 6 hours postinfection. Actinomycin D-resistant viral RNA synthesis started at about 2 hours postinfection, peaked by 5 hours, and then declined rapidly. Virus-specific protein synthesis began while host protein synthesis was declining, increased during the ensuing period, and declined in late infection. A number of virus-specific proteins with molecular weights from 23,500 to greater than 92,500 were detected in the host cytoplasm. At least three of these proteins were also present in the nucleus. The kinetics pf processing of virus-specific proteins were examined by pulse-chase experiments in B5-infected cells. The relative intensities of [35S]-methionine-labeled polypeptides suggest that a number of smaller, stable chains (MW 23,500 to 38,000) are generated by cleavage of a precursor polypeptide (MW 92,500 to 100,000).

Induction of intranuclear microtubules in chick embryo fibroblasts by frog virus 3

Intranuclear microtubules appear in chick embryo fibroblasts upon infection with Frog Virus 3 (FV 3). Both the diameter and the annular shape of the microtubule profiles, established from electron microscopic observations using a goniometer, suggest that they are identical to naturally occurring cytoplasmic microtubules. Furthermore, the use of vinblastine allowed demonstration of the tubulin composition of the intranuclear microtubules.