Improved hemagglutination of simbu group arboviruses with higher sodium chloride molarity diluent

Sensitive plaque assay and propagation of Chuzan (Kasba) virus, a Palyam serogroup orbivirus, in BHK-21 cells

Various factors influencing plaque formation of Chuzan virus in BHK-21 cell monolayers were studied and a practical method for plaque assay was developed. On addition of trypsin (5 micrograms/ml) and/or diethylaminoethyl (DEAE)-dextran (50 micrograms/ml) to the virus diluent as the virus adsorption medium and agar overlay medium, the number of plaques increased. When 100 micrograms/ ml DEAE-dextran was added to the diluent and overlay medium, plaques were produced in about 10-fold higher numbers than without trypsin and DEAE-dextran. Based on these results, a practical plaque assay method for Chuzan virus was established. Using this method, one-step growth of Chuzan virus was performed at an input multiplicity of 25 plaque-forming units (PFU) per cell. Cytopathic effects were first observed at 7.5 h post-inoculation (p.i.), and were complete at 12 h p.i. The titre of cell-associated virus, after gradual decline during the first 3 h of incubation, showed a rise within 4.5 h p.i. and a rise to a plateau of 10(6.3)PFU/0.2 ml at 12 h p.i. By indirect immunofluorescence, virus-specific antigen was detected in the cytoplasm of the cells at 4.5 h p.i., and all the cells fluoresced at 6 h p.i. Haemagglutination activity was first detected in infected whole cultures at 7.5 h p.i. reaching a plateau of 1:64 at 15 h p.i. Plaque formation and haemagglutination by the virus were specifically inhibited by antisera against the original and the plaque-cloned virus.

Effect of heparin on hemagglutination by Akabane and Aino viruses belonging to the Simbu group of bunyaviruses

Heparin inhibited the hemagglutinin activity of Akabane and Aino viruses. The minimal inhibitory concentration of heparin required to inhibit 8 hemagglutination (HA) U of Akabane and Aino viruses was 10 U/ml. Goose erythrocytes failed to combine with the HA inhibitory factor of heparin. On the other hand, goose erythrocytes treated with heparinase had greatly reduced agglutinability by Akabane virus. Virus-heparin complex formation was observed by sedimenting heparin with the virus particles.

Akabane virus

Akabane virus, an arthropod-borne Bunyavirus, is the major cause of epizootics of congenital malformations in ruminants in Australia, Japan, Korea, and Israel, and is suspected to be a cause of sporadic outbreaks elsewhere. Blood-sucking insects, such as biting midges, transmit the virus horizontally to vertebrates. Climatic factors influence the seasonal activity and geographic range of the vector population and, therefore, occurrence of related disease. Inoculated ruminants seroconvert rapidly after a short subclinical viremia. Infection is of consequence only if ruminants are pregnant and not protected by adequate specific neutralizing antibodies. In naive pregnant animals, virus may spread hematogenously to replicate and persist in trophoblastic cells of placental cotyledons and subsequently invade the fetus. A distinct tropism for immature rapidly dividing cells of the fetal central nervous system and skeletal muscle results in direct virus-induced necrotizing encephalomyelitis and polymyositis. If fetuses survive, such injury may manifest as arthrogryposis, hydranencephaly, porencephaly, microencephaly, hydrocephalus, or encephalomyelitis at term. The earlier in gestation that fetal infection occurs, the more severe the lesions, reflecting the large population of vulnerable cells and lack of fetal immunocompetency at earlier stages of pregnancy. Injury during the period of critical cell migration and differentiation in organogenesis may substantially disrupt structural development in target organs. Late gestational infections cause nonsuppurative inflammation in the brain and spinal cord, premature birth, or fetal death with stillbirth or abortion. Affected neonates are nonviable. Control is by vaccination but is not always justified economically. Akabane viral infections must be differentiated from infections with other teratogenic viruses (including related Bunyaviruses), inherited conditions, and maternal intoxications. Diagnosis is made by serology and viral isolation.

Isolation of Getah virus from dead fetuses extracted from a naturally infected sow in Japan

Three viruses producing a cytopathic effect in cell culture were isolated from dead fetuses extracted from a naturally infected sow, and were found to be serologically identical by neutralization tests. One of the viruses was cloned and named the Sakura strain. The Sakura strain was identified as Getah virus by cross-neutralization tests.

Detection of antibodies against Akabane virus in bovine sera by enzyme-linked immunosorbent assay

An enzyme-linked immunonosorbent assay was established for detection of antibodies to Akabane virus in bovine sera. The assay was shown to be a useful serological tool for studies on Akabane virus infection.

Appearance of slow-reacting and complement-requiring neutralizing antibody in cattle infected with Akabane virus

Slow-reacting complement-requiring neutralizing (NT) antibody was detected in sera from cattle 2 weeks after infection with Akabane virus. Bovine sera obtained 3 or 4 weeks after infection contained slow-reacting noncomplement-requiring NT antibody. The slow-reacting complement-requiring NT antibody was sensitive to 2-mercaptoethanol (2-ME), whereas the slow-reacting noncomplement-requiring NT antibody was resistant to 2-ME. The initial phase may represent the IgM response and the later phase a change to IgG. A NT test was developed in which virus-serum mixtures were incubated at 4 degrees C for 48 h and then with complement at 37 degrees C for 60 min; this gave an improved sensitivity over the previous incubation at 37 degrees C for 60 min.

Hemagglutination with rhabdoviruses related to bovine ephemeral fever virus

Three different bovine ephemeral fever group viruses were tested for hemagglutination (HA). One of them, Tortilla Flat virus (CSIRO 368), agglutinated erythrocytes from geese, pigeons, horses, hamsters, mice and guinea-pigs when the concentrated infectious culture fluid was used as a hemagglutinin. The HA was dependent on the pH of phosphate buffered saline used as the erythrocyte diluent when using borate buffered saline (pH 9.0) with 0.4% bovine serum albumin as the antigen diluent. The optimal pH of the phosphate buffer was from 5.2 to 5.8. The HA, however, was not dependent on salt concentration. The incubation temperature did not affect the HA titer significantly. This HA reaction was inhibited by serotype specific antiserum.