Cytology and autoradiography of Tipula iridescent virus infection of insect suspension cell cultures

Family Iridoviridae: poor viral relations no longer

Members of the family Iridoviridae infect a diverse array of invertebrate and cold-blooded vertebrate hosts and are currently viewed as emerging pathogens of fish and amphibians. Iridovirid replication is unique and involves both nuclear and cytoplasmic compartments, a circularly permuted, terminally redundant genome that, in the case of vertebrate iridoviruses, is also highly methylated, and the efficient shutoff of host macromolecular synthesis. Although initially neglected largely due to the perceived lack of health, environmental, and economic concerns, members of the genus Ranavirus, and the newly recognized genus Megalocytivirus, are rapidly attracting growing interest due to their involvement in amphibian population declines and their adverse impacts on aquaculture. Herein we describe the molecular and genetic basis of viral replication, pathogenesis, and immunity, and discuss viral ecology with reference to members from each of the invertebrate and vertebrate genera.

Deep-etch EM reveals that the early poxvirus envelope is a single membrane bilayer stabilized by a geodetic "honeycomb" surface coat

Three-dimensional "deep-etch" electron microscopy (DEEM) resolves a longstanding controversy concerning poxvirus morphogenesis. By avoiding fixative-induced membrane distortions that confounded earlier studies, DEEM shows that the primary poxvirus envelope is a single membrane bilayer coated on its external surface by a continuous honeycomb lattice. Freeze fracture of quick-frozen poxvirus-infected cells further shows that there is only one fracture plane through this primary envelope, confirming that it consists of a single lipid bilayer. DEEM also illustrates that the honeycomb coating on this envelope is completely replaced by a different paracrystalline coat as the poxvirus matures. Correlative thin section images of infected cells freeze substituted after quick-freezing, plus DEEM imaging of Tokuyasu-type cryo-thin sections of infected cells (a new application introduced here) all indicate that the honeycomb network on immature poxvirus virions is sufficiently continuous and organized, and tightly associated with the envelope throughout development, to explain how its single lipid bilayer could remain stable in the cytoplasm even before it closes into a complete sphere.

Characterization of iridovirus IV1 polypeptides: mapping by surface labelling

A comprehensive index of IV1(Tipula iridescent virus, or TIV)-associated polypeptides has been established using enrichments of "empty" and "filled" virions that are considered to be maturation-phase-related. The mapping strategy which involved one- and two-dimensional polyacrylamide gel electrophoresis, silver staining, disulphide bond reduction and 125I iodination of putative surface proteins revealed 103 and 116 polypeptides for empty and filled capsids, respectively. These estimates could be reduced to < or = 70 by reclassing multicharged polypeptides of approximately identical masses as single entitles. At least 10 polypeptides from empty and filled virions were involved in intermolecular sulphhydryl linkages and another 11 species were identified as putative outer shell (surface) polypeptides. These data provide useful criteria for iridovirus classification and identification of candidate polypeptides involved in capsid formation and maturation.

Plaque assay and replication of Tipula iridescent virus in Spodoptera frugiperda ovarian cells

A plaque assay was developed for the study of Tipula iridescent virus (TIV) replication using a cell line derived from the fall army worm Spodoptera frugiperda (Sf9). Infection and plaque formation were monitored with time by phase contrast microscopy, video and fluorescent light microscopy. Structure of virions, viroplasmic centres and organelles of infected cells were examined by transmission electron microscopy (TEM). After 4 h postinfection, plaques were visibly detected within the cell monolayer by the presence of localized cell damage and production of numerous vesicular-like cytoplasmic structures. Quantitation of virions present per A260 unit of TIV preparation was determined by TEM. The number of visible plaques corresponded to virus concentration and 1 A260 produced approximately 10(5) plaques. DNA hybridization analysis revealed no gross differences in genomic DNA from TIV propagated in either Sf9 cells or wax moth Galleria mellonella larvae. These findings indicate that Sf9 is permissive for replication of TIV and superior by some parameters to other cell lines currently in use for the study of host cell/TIV interactions.

Semipermissive replication of Tipula iridescent virus in Aedes albopictus C6/36 cells

Comparative studies were carried out using two different insect cell lines, Aedes albopictus and Estigmene acrea, for Tipula iridescent virus (TIV) propagation. Light microscope autoradiography showed viral DNA present in viroplasmic centers (VCs) and an inhibition of nuclear DNA synthesis. These VCs appeared to be morphologically similar in both cell lines when examined by light and electron microscopy. Radiolabeled cDNA was synthesized from RNA samples obtained from infected cells at different times after infection and hybridized to TIV DNA digested with various restriction endonucleases. The results indicated that the pattern of transcription and the kinetics of TIV infection were qualitatively similar in both cell lines. The major TIV DNA components, L (greater than 174 kbp) and S1 (10.8 kbp) that are found in virions in approximately equivalent amounts, were made in both infected cell lines. However, the infected cell lines produced S1 DNA at higher levels relative to L than in virions. The cDNA hybridization studies also revealed that the S1 DNA has sequences that are transcribed and are TIV specific. While VC morphology, levels of L and S1 DNA synthesis, transcription, and capsid protein synthesis were similar in both cell lines, time course electron microscope studies revealed that progeny virions were detected only in the VCs of E. acrea cells and not in the VCs of A. albopictus cells, even by 96 hr p.i. These data suggest that the A. albopictus C6/36 cell line is semipermissive for TIV replication.

Molecular cloning, characterization, and expression of the Tipula iridescent virus capsid gene

The capsid protein is the major structural component of the icosahedral Tipula iridescent virus (TIV) that replicates in cytoplasmic inclusion bodies of insect cells. TIV capsid protein purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis was digested with trypsin and fractionated by reverse-phase high-pressure liquid chromatography. A mixed oligonucleotide constructed from the amino acid sequence of a capsid tryptic peptide was used for the identification and cloning of the corresponding gene. The single-copy capsid gene, located on a 2.47-kilobase-pair HindIII TIV genomic fragment, codes for a 464-amino-acid protein (50,831 daltons) with a predicted pI of 6.34. Analysis of total RNA from infected Estigmene acrea cells indicated that the 1.8-kilobase capsid transcript was maximally produced between 14 and 24 h after infection. Transcript mapping by primer extension indicated that the RNA start site was in the A+T-rich TGCTACTAAT sequence, 19 nucleotides upstream from the first ATG codon of the capsid open reading frame. Expression of the TIV capsid protein in infected E. acrea cells was demonstrated by in vivo labeling of total proteins with [35S]methionine, using anti-capsid antiserum as the probe. Capsid protein was also expressed in Escherichia coli cells by using a pUC19 plasmid containing a lacZ-capsid gene fusion.