ICTV virus taxonomy profile: Sarthroviridae.

The family Sarthroviridae includes a single genus, Macronovirus, which in turn includes a single species, Macrobrachium satellite virus 1. Members of this species, named extra small virus, are satellite viruses of Macrobrachium rosenbergii nodavirus, an unclassified virus related to members of the family Nodaviridae. Both viruses have isometric, spherical virions, infect giant freshwater prawns and together cause white tail disease, which is responsible for mass mortalities and severe economic losses in hatcheries and farms. Infection is caused by both vertical and horizontal transmission of virus. Aquatic insects act as a carrier to transmit the disease in prawns. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Sarthroviridae, which is available at www.ictv.global/report/sarthroviridae.

A capsidless ssRNA virus hosted by an unrelated dsRNA virus.

Viruses typically encode the capsid that encases their genome, while satellite viruses do not encode a replicase and depend on a helper virus for their replication(1). Here, we report interplay between two RNA viruses, yado-nushi virus 1 (YnV1) and yado-kari virus 1 (YkV1), in a phytopathogenic fungus, Rosellinia necatrix(2). YkV1 has a close phylogenetic affinity to positive-sense, single-stranded (+)ssRNA viruses such as animal caliciviruses(3), while YnV1 has an undivided double-stranded (ds) RNA genome with a resemblance to fungal totiviruses(4). Virion transfection and infectious full-length cDNA transformation has shown that YkV1 depends on YnV1 for viability, although it probably encodes functional RNA-dependent RNA polymerase (RdRp). Immunological and molecular analyses have revealed trans-encapsidation of not only YkV1 RNA but also RdRp by the capsid protein of the other virus (YnV1), and enhancement of YnV1 accumulation by YkV1. This study demonstrates interplay in which the capsidless (+)ssRNA virus (YkV1), hijacks the capsid protein of the dsRNA virus (YnV1), and replicates as if it were a dsRNA virus.

Structural studies of the Sputnik virophage.

The virophage Sputnik is a satellite virus of the giant mimivirus and is the only satellite virus reported to date whose propagation adversely affects its host virus' production. Genome sequence analysis showed that Sputnik has genes related to viruses infecting all three domains of life. Here, we report structural studies of Sputnik, which show that it is about 740 A in diameter, has a T=27 icosahedral capsid, and has a lipid membrane inside the protein shell. Structural analyses suggest that the major capsid protein of Sputnik is likely to have a double jelly-roll fold, although sequence alignments do not show any detectable similarity with other viral double jelly-roll capsid proteins. Hence, the origin of Sputnik's capsid might have been derived from other viruses prior to its association with mimivirus.

Characterization of a novel satellite virus and a strain of Himetobi P virus (Dicistroviridae) from the brown planthopper, Nilaparvata lugens.

Two distinct spherical virus-like particles were purified from the brown planthopper, Nilaparvata lugens. One was a geographical isolate of Himetobi P virus (Cripavirus, Dicistroviridae). The other was 30 nm in diameter and contained positive-stranded RNA. The RNA was 1647 nucleotides in length and encoded only its own capsid protein, indicating that this particle is a satellite virus. Transmission tests showed that the satellite was transmitted vertically; however, its helper virus was unknown. We named this satellite Nilaparvata lugens commensal X virus (NLCXV).

Bacteriophage P2 and P4 morphogenesis: assembly precedes proteolytic processing of the capsid proteins.

Several of the structural proteins of phage P2 and its satellite P4 undergo proteolytic processing during development of mature phage particles. Here, we report that uncleaved shell protein, gpN, is present in immature capsids of both P2 and P4, showing that assembly precedes processing. This excludes the possibility that processing of gpN is involved in capsid size determination. We also find that N*, the fully processed version of gpN, produced from a plasmid, can assemble into both P2- and P4-sized particles, implying that the amino-terminal end of gpN is not required for assembly initiation nor for the formation of a T = 4 shell. As may be expected for a scaffolding protein, we find that gpO coexists with gpN in immature P2, as well as P4, capsids. This result supports the conclusion that gpO is required for both phages and strongly suggests that the O derivative, h7 (found in mature capsids), results from proteolytic cleavage after gpN/gpO coassembly.

Bacteriophage P2 and P4 morphogenesis: identification and characterization of the portal protein.

The portal structure has been implicated in several aspects of the bacteriophage life cycle, including capsid assembly initiation and DNA packaging. Here we present evidence that P2 gene Q codes for the P2 and P4 portal protein. First, microsequencing shows that capsid protein h6 is derived from gpQ, most probably by proteolytic cleavage. Second, antibodies against gpQ bind to the portal structure in disrupted P2 phage virions, as observed by electron microscopy. Third, gpQ partially purified from an overexpressing plasmid assembles into portal-like structures. We also show by microsequencing that capsid protein h7 is encoded by the P2 scaffold gene, O, and is probably derived from gpO by proteolytic cleavage. Previous work has demonstrated processing of the major capsid protein. Thus, all essential capsid proteins of P2 and P4 are proteolytically cleaved during the morphogenetic process.

Characterization of the capsid associating activity of bacteriophage P4's Psu protein.

The Psu (Polarity suppression) protein of satellite bacteriophage P4 was first characterized as an anti-terminator of transcription termination in Escherichia coli. Psu is also a structural component of mature P4 capsids, where it is present as a decoration protein. Psu is located externally on the capsid surface, and it appears to protect the capsid from loss of DNA through the capsid shell. The ability of Psu to specifically bind to the P4 capsid appears not to be dependent on any P4 specific components such as the capsid protein cleavage products h1 and h2, or P4 DNA. We suggest that Psu binds to the P4 capsid as a result of the special structure of the hexamers in the P4 capsid.

Sequential removal of Ca2+ from satellite tobacco necrosis virus. Crystal structure of two EDTA-treated forms.

Two forms of EDTA-treated satellite tobacco necrosis virus (STNV) have been studied with X-ray crystallography methods. The crystals of both forms were isomorphous with native STNV crystals, and (FEDTA-Fnat) maps as well as (2FEDTA-Fnat) maps were calculated with phases from the native structure. The maps were based on partial data sets to 2.8 A resolution, and averaged using the 60-fold non-crystallographic symmetry. In the first crystal form, calcium ions were absent from one of the three sites in the icosahedral protein shell. The crystals were produced at pH 5.0 from a virus solution treated with EDTA at pH 6.5. The virions were not expanded, and no essential changes were seen in the protein shell. In the second crystal form, all calcium ions in the protein shell were absent. The virus material in these crystals had been subjected to treatment with EDTA at pH 8.0 before crystallization at pH 6.5. The high pH treatment caused degradation of the viral RNA. No expansion of the virion had occurred and all protein--protein contacts were retained. These results are compared with the previously presented low-resolution structure of slightly expanded STNV with intact RNA, where calcium ions from two sites were absent. The relevance of Ca2(+)-depleted virions for infection in vivo is discussed as well as the possibility that the Ca2(+)-binding sites may be parts of ion channels in the viral capsid. One possible RNA-binding site was found in the maps of both crystal types, and the same site could also be localized in the high-resolution map of native STNV.

Effect of environmental pH on adenovirus-associated virus.

The influence of environmental pH on AAV was studied in infectious virus titrations, induction of CF antigens production of infectious virus, induction of immunofluorescent stainable antigen, and aggregation of the viral particles. The pH of the medium was found to influence the titer of virus stocks in that less virus was registered at acid pH's, giving differences of up to 105 TCID50 in HEK and HEp-2 cells. Less infectious virus was produced in KB cells, and decreased amounts of CF antigen appeared at acid pH's. However, increased levels of detectable intracellular FA antigen appeared at acid pH's. Electron microscopic examination of AAV particles negatively stained at various pH's showed increasingly large aggregates of particles as the pH was lowered. Under the acid conditions studied, the adenovirus helper and cell activities were only slightly suppressed, with the greatest effect due to aggregation of the virus particles.

Isolation and characterization of an adenovirus and isolation of its adenovirus-associated virus in cell culture from foals with respiratory tract disease.

An adenovirus was isolated from a foal with respiratory tract disease. The virus produced cytopathic effects (CPE) in equine embryo kidney (EEK) cell culture, contained deoxyribonucleic acid (DNA), was resistant to chloroform and pH 3, and was moderately resistant to heat. The virus caused hemagglutination of human (type O) erythrocytes. Viral density was 1.34 g/cm,3 and diameter was 75 nm. An adenovirus-associated virus (AAV) isolated from the infected cell culture was 22 nm in diameter. These viruses are classified as equine adenovirus and equine AAV.

Detection and serological identification of adeno-associated virus in avian adenovirus stocks.

Eleven avian adenovirus strains were tested for the presence of avian adeno-associated viruses (AAAV). Six strains contained AAAV. Electron microscopy using rabbit anti-AAAV serum was useful in detecting the satellite virus. The AAAV previously isolated from guail bronchitis virus was related to each of the six new isolates by immunoagglutination, complement fixation, immunodiffusion, and neutralization tests.