Maurice Clarence Kemp

Antigen dependent adjuvant activity of a polydispersed β-(1,4)-linked acetylated mannan (acemannan)

The adjuvant properties of a polydispersed beta-(1,4)-linked acetylated mannan, acemannan (ACE-M), were evaluated. Day-old broiler chicks were randomly selected and allocated to four flocks (Vac 1-4). The Vac 1 flock was sham vaccinated with saline. The Vac 2 flock was vaccinated with an oil-based vaccine (Breedervac III; Newcastle disease virus (NDV), infectious bursal disease virus (IBDV) and infectious bronchitis virus). The Vac 3 flock was vaccinated with a vaccine-ACE-M mixture, and the Vac 4 flock was vaccinated with vaccine and ACE-M at separate anatomical sites. ELISA titres to NDV and IBDV were determined. The immune response to NDV at 21 days postvaccination (PV) was significantly enhanced (P less than or equal to 0.05) by the addition of ACE-M to the vaccine, compared with vaccination without ACE-M. Subsequently, the vaccine-ACE-M mixture appeared to suppress the immune response to NDV. However, at day 35 PV, 95% of the Vac 3 chicks compared with 90% of the Vac 2 and 89% of the Vac 4 chicks exhibited protective titres. The response to IBDV differed from that to NDV. At day 21 PV the immune response to IBDV was essentially the same for all flocks that received vaccine, i.e. addition of ACE-M to the vaccine did not significantly enhance the immune response; however, it did significantly (P less than or equal to 0.05) sustain the immune response at days 28 and 35. In addition to the observed effect on titres to NDV and IBDV, ACE-M also had an effect on flock immunity.(ABSTRACT TRUNCATED AT 250 WORDS)

A Comparative Study of Avian Reovirus Pathogenicity: Virus Spread and Replication and Induction of Lesions

This study examined the relationship of avian reovirus spread and replication to induction of lesions and the relevant role of the S1 segment encoding a virus-neutralizing antigen. One-day-old broiler chickens were infected via footpad or orally with two virus strains (883 and 176) that differ greatly in virulence and a reassortant (R44) that has the S1 segment from 176 and the remaining genome segments from 883. Virus replication and histological lesions in various tissues (heart, liver, spleen, kidney, bursa, hock joint, and bone marrow) were measured at 2-day intervals until day 8 postinoculation. The virulent strain 176 spread to and replicated efficiently in all tissues examined and caused extensive and severe lesions, whereas the mild strain 883 was detected only in tissues near inoculation sites and caused only minimal lesions. The appearance of lesions correlated with the presence of viral replication in each tissue tested. Together, these results indicate that induction of lesions, or pathogenicity, is directly related to virus spread and replication. Reassortant R44 behaved like strain 176 in chicken embryo fibroblasts (CEFs), i.e., both replicated much faster and produced larger plaques than strain 883. In broiler chickens, however, R44 behaved like strain 883, replicating and inducing lesions to an extent that was fat lower than that of strain 176. These results suggest that the S1 segment alone is capable of determining viral replication and plaque formation in cultured CEFs but is not sufficient to determine the virus spread and replication and the pathological change in broiler chickens.

Strain-specific selection of genome segments in avian reovirus coinfections.

To determine whether selection of genome segments in coinfections is strain-specific, chicken embryo fibroblasts were coinfected with avian reovirus strain 883 and one of three other avian reovirus strains (176, S1133 and 81-5). Viral progeny from each coinfection (883 x 176, 883 x S1133 or 883 x 81-5) was serially passaged at a low m.o.i. The electropherotypes of the coinfection progeny and those of the plaque-derived clones obtained from passages 1 and 20 were analysed. Two 883 segments (M2 and S2) were found to be selected in the 883 x 176 coinfection, three 883 segments (M2, M3 and S2) in the 883 x S1133 coinfection, and only one 883 segment (M3) in the 883 x 81-5 coinfection, i.e. different 883 genome segments were selected in the three coinfections. It was, therefore, concluded that selection of genome segments in a coinfection of a given cell line is virus strain-specific. The selection of genome segments in coinfections was shown to be due to enhanced infectivity of the reassortants that were formed in the coinfections. In addition, defective interfering particles that lack the S1 segment were identified in the 883 x 81-5 coinfection progeny following serial passage. Selection of genome segment(s) in coinfections as described herein may have potential importance on the effect and production of divalent or multivalent vaccines.

Subgenomic S1 segments are packaged by avian reovirus defective interfering particles having an S1 segment deletion

Two subgenomic segments derived from the S1 genome segment (SGS1-1 and SGS1-2) were identified in avian reovirus defective interfering (DI) particle preparations having an S1 segment deletion. Both SGS1-1 and SGS1-2 were composed of double-stranded RNA (dsRNA) with an estimated size of 400 and 380 bp, respectively. Their segment of origin was identified as the S1 by hybridization analysis. The subgenomic segments were associated with the virus fraction following CsCl density gradient centrifugation, indicating that they are packaged. The subgenomic segments were also shown to be replicated. Therefore, sequence(s) required for replication and packaging are retained. The relative amounts of subgenomic segments were shown to be inversely proportional to that of the S1 segment. The presence of subgenomic segments and concurrent reduction in the relative amount of the S1 segment were found to be directly associated with the decrease in infectious titers. These results suggest that subgenomic segments are responsible for induction of interference by specifically competing with the S1 segment during replication and/or packaging. The competitive relationship between the subgenomic segments and the S1 segment implies that segment-specific sequence(s) or factor(s) are involved in the replication and/or packaging of each individual genome segment.

Selection of genome segments following coinfection of chicken fibroblasts with avian reoviruses.

Two avian reoviruses (883 and 176) shown to have distinct growth kinetics were used to coinfect chicken embryonic fibroblasts asynchronously to generate reassortants. More than 300 plaque-derived clones were obtained from passage 3 of two separate coinfections made at different m.o.i. and time intervals between infection and superinfection. The genome electropherotype of each plaque-derived clone was determined, and a diverse group of reassortants were detected. Genome segments 883 M2 and 176 S1 were shown to be preferentially selected. The preferential selection of the 176 S1 segment was shown to be a virus growth-determined nonrandom event conferred by the function of 176 S1 segment, whereas the data suggest that a factor(s) other than viral growth properties was involved in the preferential selection of 883 M2 segment.

Genotypic transitions among bluetongue viral isolates from domestic ruminants in Colorado during 1981-1984

Two predominant electropherotypes of bluetongue virus (BTV) serotype 11 isolates from cattle during a 1981–1984 field study in eastern Colorado were characterized. The genomes of strains isolated from the first 2 years of the study had 1 predominant electropherotype (CO81), with the exception of 1 isolate that differed only in the migration of segment 3. A second electropherotype (CO83), with differences in the migration of 4 segments, coexisted in the same region during 1983 and 1984 with strains having the CO81 RNA profile. The genomes of CO81 and CO83 were also distinguishable from those of the US prototype of BTV 11. Analysis of the polypeptides of representative strains of each electropherotype by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the proteins were very similar. The occurrence of the CO81 electropherotype was apparently the result of multiple viral infections since the positions of 7 segments had faint second bands and single-banded variants were isolated after serial plaque purifications. In addition, protein 7 of 1 of the CO81 isolates and protein 7 of the single-banded variant differed as shown by reverse phase-high performance liquid chromatography of 35S-methionine-labeled tryptic peptides.