Archives of Virology

Campadelli-Fiume, Gabriella

doi: 10.1007/bf01315530pmid: 100081

Summary and ConclusionsThe advances in virus research made possible by the use of amanitins are reported; they include i) determination of the genetic source (i.e. cellular or viral) of the RNA polymerase transcribing the viral genome, and ii) mechanism of virus-induced shut-off of host RNA synthesis.In the studies on the genetic origin of the RNA polymerase transcribing the viral genome, α-amanitin has been used mainly in cell-free systems because of its slow penetration intoin vitro cultured cells. Recently, amanitin penetration has been accelerated either by the use of derivatives of the toxin or by a short pretreatment of the cultures with DEAE-dextran. With the latter procedure it has been possible to test the action of amanitin on herpesvirus RNA synthesis in intact cells.α-amanitin has been used on the general assumption that the viral transcription inhibited by the toxin is carried out by the host polymerase B, although the existence of a virus-specific amanitin-sensitive transcriptase could not be excluded. Involvement of RNA polymerase B in herpesvirus and papovavirus transcription has been clearly demonstrated by comparative experiments with normal cells and mutant cells possessing amanitin-resistant RNA polymerase B; virus-coded transcriptase could be dismissed by the observation that amanitin did not inhibit viral RNA synthesis in the mutant cells.In the experiments concerning the mechanism of inhibition of host cell RNA synthesis, α-amanitin has been used to determine which RNA polymerase activity was inhibited during virus infection. Finally, in frog virus 3-infected cells direct titration of the number of RNA polymerase B molecules was performed by means of labeled amanitin. With this procedure it was confirmed that the drop in RNA polymerase B activity was due to a decreased number of enzyme molecules.

Takayama, N.; Kirn, A.

doi: 10.1007/bf01315532pmid: 211989

SummaryThein vitro virus yield of MHV3 reached 107 PFU/ml in mouse DBT cells infected with a virus suspension in HEPES-buffered medium containing DEAE-dextran. The virus titer was 106 PFU/ml in the presence of 10 µg actinomycin D/ml. MHV3 grown in DBT cells gave three peaks of density (1.10–1.14 g/cm3, 1.18–1.20 g/cm3, and 1.25–1.31 g/cm3) in sucrose gradients. All these peaks retained infectivity.

Meloen, R. H.

doi: 10.1007/bf01315533pmid: 211990

SummaryThe precipitating and neutralizing activities of normal bovine sera with FMDV were studied and compared.Twenty-two out of 79 normal bovine sera gave a positive reaction in micro neutralization tests with FMDV type O, while six did so with type A. In RID tests 32 sera were positive with type O and 28 with type A virus. Almost all of the 79 sera gave a positive reaction in the RID with trypsin treated virus of both types. After three to four fold concentration most sera also gave visible reactions in ID tests when tested against complete virus.When O virus was used the ID patterns produced by most normal sera clearly differed from those obtained with early and late convalescent sera from FMDV infected steers. When type A materials were employed this was also the case but to a lesser extent. The patterns obtained with concentrated normal sera showed, in general a strong line with trypsin treated virus and no line or a weaker one with complete virus. The substances in normal bovine sera precipitating trypsin treated O virus were different from those reacting with trypsinized virus of type A.

Pedersen, N. C.; Ward, J.; Mengeling, W. L.

doi: 10.1007/bf01315534pmid: 81044

SummaryUtilizing the direct and indirect fluorescent antibody procedure, the antigenic relationship of the feline infectious peritonitis virus (FIPV) to 7 other human and animal coronaviruses was studied. FIPV was found to be closely related to transmissible gastroenteritis virus (TGEV) of swine. Transmissible gastroenteritis virus and FIPV were in turn antigenically related to human coronavirus 229E (HCV-229E) and canine coronavirus (CCV). An interesting finding in the study was that the 8 coronaviruses selected for this study fell into one of two antigenically distinct groups. Viruses in each group were antigenically related to each other to varying degrees, but were antigenically unrelated to coronaviruses of the second group. The first antigenically related group was comprised of mouse hepatitis virus, type 3 (MHV-3), hemeagglutinating encephalomyelitis virus 67N (HEV-67N) of swine, calf diarrhea coronavirus (CDCV), and human coronavirus OC43 (HCV-OC43). The second antigenically related group was comprised of FIPV, TGEV, HCV-229E and CCV.