Michael P. Kiley

Descriptive analysis of Ebola virus proteins.

The virion proteins of two strains of Ebola virus were compared by SDS-polyacrylamide gel electrophoresis (PAGE) and radioimmunoprecipitation (RIP). Seven virion proteins were described; an L (180K), GP (125K), NP (104K), VP40 (40K), VP35 (35K), VP30 (30K), and VP24 (24K). The RNP complex of the virus contained the L, the NP, and VP30, with VP35 in loose association with them. The GP was the major spike protein, with VP40 and VP24 making up the remaining protein content of the multilayered envelope.

Junin Virus Monoclonal Antibodies: Characterization and Cross-reactivity with Other Arenaviruses

Twenty-one monoclonal antibodies reactive with Junin virus structural proteins were produced and characterized. Using radioimmunoprecipitation and Western blot assays, 13 were found to react with the nucleoprotein, seven with the surface glycoprotein and one failed to react, but showed a fluorescent antibody staining pattern consistent with other glycoprotein-specific antibodies. In radioimmunoprecipitation assays, glycoprotein-specific monoclonal antibodies reacted not only with the 35K structural glycoprotein, but also with what is presumed to be the glycoprotein precursor. Four of seven glycoprotein-specific antibodies neutralized Junin virus to high titres. Cross-reactivity with other arenaviruses was found to be restricted to nucleoprotein-specific monoclonal antibodies and occurred only with New World arenaviruses. Cross-reactivity also shows the Junin virus to be most closely related to Machupo and Tacaribe viruses.

Identification and analysis of Ebola virus messenger RNA.

Six messenger RNA species of Ebola virus were identified in infected Vero E6 cells. Virion RNA hybridizes to each of the mRNAs, confirming that Ebola virus possesses a negative-stranded RNA genome. The mRNAs are monocristronic transcripts, are synthesized in the presence of actinomycin D, and are polyadenylated. In vitro translation of mRNA preparations results in the synthesis of five authentic viral proteins and a putative unglycosylated form of the glycoprotein, demonstrated by immunoprecipitation with virus-specific antisera and SDS-PAGE. No mRNA species was detected for the polymerase (L protein) gene.

Physicochemical Properties of Marburg Virus: Evidence for Three Distinct Virus Strains and Their Relationship to Ebola Virus

The physicochemical and antigenic properties of three groups of Marburg (MBG) virus isolates, separated temporally and geographically, were compared to each other and to another member of the same family, Ebola (EBO) virus. Each MBG isolate contained seven virion proteins, one of which was a glycosylated surface protein. Peptide mapping of glycoproteins, nucleoproteins (NP) and viral structural protein (VP40) demonstrated extensive sequence conservation in the proteins of viruses isolated over a 13-year period, but homology was not evident in VP24. Some homology between the NPs of MBG and EBO was observed. A close antigenic relationship between MBG strains was found by radioimmunoassay but no evidence was found of antigenic cross-reactivity with EBO viruses. MBG virion proteins are produced from virus-specific monocistronic mRNA species. Five of the seven viral proteins were produced by in vitro translation of these RNAs. MBG virions contained one RNA species with an Mr of 4.2 x 10(6) and virions had a density of 1.14 g/ml in potassium tartrate. Virus isolates from different outbreaks had distinct T1 oligonucleotide maps, but had approximately 95% homology in base sequence. No two geographically distinct virus pairs were more closely related to each other than to a third virus isolate. MBG viruses are thus similar to EBO viruses in morphology and other physicochemical properties and are very similar to each other in RNA and protein composition. Each of the three geographically and temporally distinct MBG virus outbreaks appears to have been due to a genetically distinguishable, but antigenically closely related virus strain. In addition, these studies confirm the belief that MBG and EBO viruses are members of the new virus family, the Filoviridae.

Antigenic relatedness between arenaviruses defined at the epitope level by monoclonal antibodies

Monoclonal antibodies (MAbs) were produced against two African arenaviruses, Lassa virus and Mopeia virus. Competitive binding analysis of MAbs identified four antigenic sites on the nucleoprotein (NP), two on glycoprotein 1 (GP1) and six on glycoprotein 2 (GP2) of the Josiah strain of Lassa virus. 64 virus isolates from western, central and southern Africa were all consistently distinguishable by MAbs to certain epitopic sites on GP1, GP2 and NP viral proteins. Furthermore, MAbs to Lassa virus GP1 and NP uniformly distinguished viruses from the West African countries of Sierra Leone, Liberia and Guinea from those of Nigeria. GP2-directed MAbs to two African arenaviruses reacted broadly with South American arenaviruses demonstrating that an epitopic site on GP2 may be the most highly conserved antigen in the arenavirus group.

Hantaan virus: identification of virion proteins

SDS-PAGE and immunoprecipitation analyses were carried out on the virion and cell-associated proteins of Hantaan virus, the causative agent of haemorrhagic fever with renal syndrome (HFRS). Purified virions have a density of 1.17 g/ml in sucrose, and contain four proteins with molecular weights of 45 000 (45K), 56K, 72K and 200K, confirming recent evidence that the virus is a member of the family Bunyaviridae. Detergent treatment of virions indicates that the 45K protein is the virus nucleoprotein. Both the 72K and the 56K proteins were labelled with [3H]glucosamine and were removed from virions by bromelain treatment, indicating that they are envelope glycoproteins. The 200K protein was found only in [35S]methionine-labelled preparations. By analogy to prototype viruses of the family Bunyaviridae, these proteins were designated N, G1, G2, and L respectively. Three virus-specific proteins (N, G1, G2) were detected in virus-infected cells. These proteins were precipitable by human convalescent serum and by serum of a Rattus norvegicus trapped in the United States. No additional virus proteins were detected in infected cells. These results confirm recent morphological and RNA studies that Hantaan virus is a member of the family Bunyaviridae. Our results also support the suggestion that Hantaan virus be placed in a new genus of Bunyaviridae.

Ebola virus: identification of virion structural proteins.

Polyacrylamide gel electrophoresis of purified Ebola virus revealed the presence of four major virion structural proteins which we have designated VP1, VP2, VP3 and VP4. Vesicular stomatitis virus (VSV) proteins were used as mol. wt. markers, and the virion proteins were found to have mol. wt. of 125000 (VP1), 104000 (VP2), 40000 (VP3) and 26000 (VP4). VP1 was labelled with glucosamine and is probably a glycoprotein. The density of the Ebola virion was approx. 1.14g/ml in potassium tartrate. Virus nucleocapsids with a density of 1.32g/ml in caesium chloride were released when virions were treated with detergents. Proteins VP2 and VP3 were consistently associated with released nucleocapsids and are probably the major structural nucleocapsid proteins analogous to the N protein of VSV. Protein VP4 was reduced or absent in released nucleocapsids and is probably analogous to the membrane (M) protein of VSV and similar viruses. The glycoprotein (VP1) is larger than the glycoprotein of any known negative-strand RNA virus and is not labelled well with 35S-methionine. VP1 is solubilized by detergent treatment, suggesting that it is a component of the virion spikes and analogous to the G protein of VSV. Our results, in conjunction with analysis of Ebola virion RNA (Regnery et al. 1980), strongly suggest that the virus is a negative-strand RNA virus and, along with marburg virus, may constitute a new taxon within this group.

COMPARATIVE ANALYSIS OF LASSA AND LASSA-LIKE ARENAVIRUS ISOLATES FROM AFRICA

Publisher Summary Lassa fever is a hemorrhagic disease that causes significant morbidity and mortality in Western Africa. The Sierra Leone strain of Lassa virus (LAS) has been described previously. As of the convention of naming virus strains after local geographic landmarks, the virus from Mozambique is designated as Mopeia (MOP) virus. The Central African Republic (CAR) virus has previously been designated as Mobala (MOB) virus from the local name of the rodent host. This chapter presents some of the physicochemical and antigenic characteristics of the three viruses including a comparison of virus protein and RNA. It also discusses their differentiation by the use of monoclonal antibodies produced against LAS and MOZ viruses. For the study described in the chapter, each virus strain was plaque purified three times in Vero E6 cells before use. The chapter illustrates the polyacrylamide gel analysis of the virion proteins of the three viruses.

Genetic variation among Lassa and Lassa-related arenaviruses analysed by T1-oligonucleotide mapping

Total RNA and small RNA species of several African arenavirus strains have been studied by T1-oligonucleotide mapping. Genetic heterogeneity is observed and discussed on the basis of evolutionary biology of the Lassa complex.