The mode of transmission of Tipula iridescent virus: I. Source of infection

A virus was isolated from a diseased tipulid larva and identified as Tipula iridescent virus (TIV) on the basis of the size and morphology of the virion, the production of iridescence in vitro and in infected tipulid larvae, and a serological reaction between antiserum against the virus and an isolate of TIV.A stock of Tipula oleracea was bred in the laboratory. Subjection of larvae to several stress factors did not result in any evidence for activation of a latent virus. Healthy T. oleracea larvae did not develop iridescence when confined in petri dishes with either live TIV-infected larvae or with large amounts of their feces, although these feces were found to contain infective virus by injecting extracts into healthy larvae. It appears that the concentration of virus in the feces of infected larvae is not high enough for them to serve as a source of infection. It was shown that the cadavers of TIV-infected larvae can serve as a source of infection for healthy first- and fourth-instar larvae.     

Tipula iridescent virus infection in the developmental stages of Tipula oleracea

Tipula iridescent virus (TIV) is infective to all four larval instars, pupae, and adults of both sexes of Tipula oleracea, and iridescence has been observed in infected insects at all these stages. Third- and fourth-instar larvae were more resistant to ingested TIV than first and second instars. When TIV was injected into the hemocoel, the results suggested a possible decrease in resistance from the third larval instar to the pupa. Incubation periods (times from injection of TIV to appearance of iridescence) were significantly shorter in older fourth-instar larvae than in younger fourth-instar or thirdinstar larvae, but variability in incubation period was significantly greater in younger fourth-instar larvae than in the other two stages. Many insects which were inoculated with TIV in one stage developed iridescence and died in later stages. The amounts of infective TIV in two infected adults were estimated.     

Parasitoid-mediated transmission of an iridescent virus

We examined the interaction between an invertebrate iridescent virus (IIV) isolated from Spodoptera frugiperda (J.E. Smith) and the solitary ichneumonid endoparasitoid Eiphosoma vitticolle Cresson. In choice tests, parasitoids examined and stung significantly more virus infected than healthy larvae, apparently due to a lack of defense reaction in virus infected hosts. Parasitoid-mediated virus transmission was observed in 100% of the female parasitoids that stung a virus infected host in the laboratory. Each female parasitoid transmitted the virus to an average (+/-SE) of 3.7+/-0.3 larvae immediately after stinging an infected larva. Caged field experiments supported this result; virus transmission to healthy larvae only occurred in cages containing infected hosts (as inoculum) and parasitoids (as vectors). The virus was highly detrimental to parasitoid development because of premature host death and lethal infection of the developing endoparasitoid. Female parasitoids that emerged from virus infected hosts did not transmit the virus to healthy hosts. We suggest that the polyphagous habits of many noctuid parasitoids combined with the catholic host range of most IIVs may represent a mechanism for the transmission of IIVs between different host species in the field.     

The effect of sodium butyrate on Tipula iridescent virus synthesis in insect suspension cell cultures

The effect of sodium butyrate on Tipula iridescent virus (TIV) synthesis in suspension-cultured cells of Estigmene acrea was investigated. Sodium butyrate reduces viral-induced cell fusion but this is reversible with the removal of butyrate. At 7 mM sodium butyrate, TIV replicates in cells within 8 hr, but does not replicate in this time with 10–20 mm butyrate in the cell medium; cells so treated contain large vesicles with inoculum. Upon removal of the inhibitor, TIV replication appears normal, but large inoculum vesicles can still be found in the cytoplasm, and many infected cells have highly condensed chromatin in their nuclei. Sodium butyrate causes a lag of at least 2 hr in viral DNA synthesis as detected by [³H]thymidine incorporation into viroplasmic centres and at 7 mm butyrate viral DNA synthesis is reduced by 50–60%. In comparison, butyrate at 7 and 10 mm concentration does not inhibit host DNA synthesis, but at 15 and 20 mm, nuclear DNA synthesis is markedly reduced.     

The biology of Chilo iridescent virus

Chilo iridescent virus (CIV) is the type species for genus Iridovirus, and belongs to the family Iridoviridae. Since the discovery of CIV in 1966, many attempts were made to elucidate the viral genome structure. The virions contain a single linear ds DNA molecule that is circularly permuted and terminally redundant. The genome of CIV has been entirely sequenced. The CIV virion consists of an unusual three-layer structure containing an outer proteinaceous capsid, an intermediate lipid membrane, and a core DNA-protein complex containing the genome. CIV has a broad host spectrum and has, in general, a limited mortality effect on its hosts. Up to now there have been several studies about CIV describing its structure, ecology, and molecular biology. In this review study we present all these studies together to describe the CIV.     

Per os transmission of iridescent virus of Heliothis zea (Lepidoptera: Noctuidae)

In per os transmission of iridescent virus (IV), the first signs of infection are small iridescent patches in the prolegs, clypeus, labrum, and intersegmental membranes. Per os exposure of neonatal larvae to IV produced 18–40% infection. Per os exposure of 5- and 9-day-old larvae produced 11–47% and 10–30% infection, respectively. A few larvae with a patent infection pupated; however, none reached the adult stage. Infected larvae remained in the larval stage up to 89 days, compared to 12–21 days for normal larvae. Transovum or transovarian transmission was not detected. Examination of fat body, silk glands, and muscles of infected larvae by electron microscopy confirmed the presence of numerous intracytoplasmic virus particles. The mean particle diameter of hexagonal profiles within viral paracrystals was 118±3.5 nm.     

Metabolic changes in diseased insects. IV. Radioautographic studies on protein changes in nuclear polyhedrosis, densonucleosis, and Tipula iridescent virus infections

Changes in glutamic acid, leucine, arginine, and tyrosine in Lepidoptera and Hymenoptera tissues infected with nuclear polyhedrosis (NPV), densonucleosis (DNV), or Tipula iridescent (TIV) viruses were studied by radioautography with a view to determining the effect of the viruses on protein metabolism.     

Genome of invertebrate iridescent virus type 3 (mosquito iridescent virus)

Iridoviruses (IVs) are classified into five genera: Iridovirus and Chloriridovirus, whose members infect invertebrates, and Ranavirus, Lymphocystivirus, and Megalocytivirus, whose members infect vertebrates. Until now, Chloriridovirus was the only IV genus for which a representative and complete genomic sequence was not available. Here, we report the genome sequence and comparative analysis of a field isolate of Invertebrate iridescent virus type 3 (IIV-3), also known as mosquito iridescent virus, currently the sole member of the genus Chloriridovirus. Approximately 20% of the 190-kbp IIV-3 genome was repetitive DNA, with DNA repeats localized in 15 apparently noncoding regions. Of the 126 predicted IIV-3 genes, 27 had homologues in all currently sequenced IVs, suggesting a genetic core for the family Iridoviridae. Fifty-two IIV-3 genes, including those encoding DNA topoisomerase II, NAD-dependent DNA ligase, SF1 helicase, IAP, and BRO protein, are present in IIV-6 (Chilo iridescent virus, prototype species of the genus Iridovirus) but not in vertebrate IVs, likely reflecting distinct evolutionary histories for vertebrate and invertebrate IVs and potentially indicative of genes that function in aspects of virus-invertebrate host interactions. Thirty-three IIV-3 genes lack homologues in other IVs. Most of these encode proteins of unknown function but also encode IIV3-053L, a protein with similarity to DNA-dependent RNA polymerase subunit 7; IIV3-044L, a putative serine/threonine protein kinase; and IIV3-080R, a protein with similarity to poxvirus MutT-like proteins. The absence of genes present in other IVs, including IIV-6; the lack of obvious colinearity with any sequenced IV; the low levels of amino acid identity of predicted proteins to IV homologues; and phylogenetic analyses of conserved proteins indicate that IIV-3 is distantly related to other IV genera.