A monoclonal antibody, 3/22, to rabbit CD11c which induces homotypic T cell aggregation: evidence that ICAM-1 is a ligand for CD11c/CD18

The rabbit CD11c molecule has been characterized by use of new monoclonal antibody, mAb 3/22. Expression of the p150,95 integrin (CD11c/CD18) has been shown by flow cytometry and immunohistochemistry to be restricted to monocytes, macrophages, dendritic cells and a small population of lymphocytes in peripheral blood. No expression on neutrophils could be demonstrated. Incubation of the newly derived CD8+ T cell line, BJ/873, with mAb 3/22 causes homotypic aggregation, which has been shown to be cell surface event that is not dependent on intracellular signaling or on receptor cross-linking. Inhibition studies show that the ligands responsible for this aggregation are CD11c/CD18 and ICAM-1, both of which are expressed on BJ/873. One other rabbit T cell line, K34, that also expresses p150,95 and ICAM-1, shows a similar aggregation response when stimulated with 3/22. Cell lines that express p150,95 but not ICAM-1 do not aggregate. These observations suggest that ICAM-1 is a ligand for activated p150,95.

Tissue culture-propagated orf virus vaccine protects lambs from orf virus challenge

Twenty, eight-day-old specific pathogen-free (SPF) lambs were vaccinated by a single scarification approximately 4 cm in length on the inner right thigh with a double-pronged applicator. The titre of live virus in the vaccine was 10(7.2) TCID50/ml and the estimated dose per lamb was 0.04 ml. Three months and six months later 10 of the vaccinated lambs and five age-matched unvaccinated control specific pathogen free lambs were challenged by a single scarification with virulent virus on the inner left thigh in the same way. After the vaccination all 20 lambs developed lesions characteristic of orf virus infection that had largely resolved four weeks later, when they all had reciprocal ELISA antibody titres > or = 3200 that persisted in all but one of them until they were challenged. After the challenge, the development of lesions in the vaccinated and unvaccinated sheep was compared daily for four weeks by means of a clinical scoring system. Both groups of vaccinated lambs had significantly lower (P < 0.01) total clinical scores after challenge at three months and six months than the unvaccinated lambs.

Antigenic similarity of central European encephalitis and louping-ill viruses

Twenty isolates of Central European encephalitis (CEE) virus were compared with 20 isolates of louping-ill (LI) virus in indirect immunofluorescence test (IIFT), using a panel of 17 monoclonal antibodies (MoAbs) prepared against the prototype LI virus. Three Asian members of the tick-borne encephalitis (TBE) complex were also included in the comparison: Turkish sheep encephalitis (TSE), Russian spring-summer encephalitis (RSSE) and Langat (LGT) viruses. Antigenic relationships of the viruses were evaluated by Dice similarity coefficient and cluster analysis. The results revealed antigenic heterogeneity of LI isolates, antigenic homogeneity of CEE isolates, and indicated that CEE and LI are related varieties of Eurasian TBE flavivirus that also includes TSE and RSSE strains.

Isolation of a parapoxvirus from a grey seal (Halichoerus grypus)

A grey seal (Halichoerus grypus) developed cutaneous pocks which progressed to involve the skin extensively, necessitating euthanasia. Macroscopically and histologically the lesions resembled previous descriptions of parapoxvirus infections of seals and virus particles were observed in preparations of a scab and a skin lesion. Suspensions of the scab and skin lesion were prepared and inoculated on to monolayer cultures of grey seal kidney cells. After 25 days in culture and three passages, cytopathic effects were observed and parapoxvirus particles were detected by electron microscopy in the supernatant fluid. Both isolates were adapted to cultures of fetal lamb muscle cells and shown to be antigenically related to orf virus.

Identification of a region of the alcelaphine herpesvirus-1 genome associated with virulence for rabbits

The gammaherpesvirus Alcelaphine Herpesvirus 1 (AHV-1) causes the fatal lymphoproliferative disease known as malignant catarrhal fever (MCF), in susceptible hosts. The virulent C500 isolate of AHV-1 became attenuated for the laboratory model, the rabbit, as a result of serial passage in cells of bovine origin. This work describes the identification of a region of the central unique sequence of the C500 genome, located close to the terminal repeat units of the molecule, which is altered on attenuation. The virulent C500 genome contains two copies of a sequence of approximately 2 kbp, contained within a 7 kbp region of the unique DNA located adjacent to the terminal repeats at the left end of the molecule. In the genome of the attenuated virus, there are also two copies of the 2 kbp sequence but they are located at the ends of the attenuated genome unique region, adjacent to the terminally repeated sequences. One open reading frame (ORF), designated putative polypeptide 5, was altered on attenuation such that the 3' sequence was lost. The location of this ORF, coupled with the loss of its 3' sequence, suggests that this ORF may encode a gene involved in the virulent mechanisms of this virus, in a manner similar to that of the transforming proteins of Herpesvirus saimiri (HSV).

An arbovirus cline across the northern hemisphere

The mode and tempo of arbovirus evolution and dispersal can help to explain the dynamics of pandemics, viral outbreaks, and emerging viruses. By comparing nucleotide and deduced amino acid sequences of their envelope proteins, we describe the continuous distribution of the tick-borne encephalitis (TBE) complex viruses, the most important flaviviruses in Europe, across major geographical areas and the conditions under which mutations occur. The analyses reveal a correlation between the geographical and genetic distances of these viruses. The arthropod host appears to be a key factor for the formation and maintenance of this cline by constraining TBE dispersal and evolution. This is also illustrated by comparisons with mosquito-borne flaviviruses.

Ultrastructural Studies of Orf Virus Infection and Replication in Fetal Lamb Fibrocytes

Résumé- Le cycle de réplication du virus de l'ecthyma contagieux a été identifié dans des études in vitro et un modèle hypothétique a été développé. Pendant la premiére phase, qui dure à peu près 5 heures, le virus pénètre la cellule par le biais d'un processus de phagocytose, et perd ses enveloppes. La phase d'éclipse, pendant laquelle le virus est apparemment intégréà l'ADN de l'hôte, dure environ 8 à 10 heures. Pendant la phase finale, les virions se développent dans des zones biens définies du viroplasme à partir desquelles les viriojns matures vont migrer jusqu'aux bords de la cellule. Là, ils sortent soit par exocytose, soit à l'intérieur de projections microvilleuses qui sont pincées à leur base, soit encore par désintégration de la cellule hôte. [Onwuka, S.K., Jenkinson, D. Mc, Inglis, L., Pow, I., GRAY, E.W., Reid, H.W. Ultrastructural studies of orf virus infection and replication in fetal lamb fibrocytes (Etudes ultrasturcturales de l'infection par le virus de l'ecthyma contagieux et de sa réplication dans les fibrocytes de foetus d'agneau). Resumen- Se identificó el ciclo de replicación del virus del ectima contagioso en estudios temporales in vitro y se desarroló un posible modelo experimental. Durante la primera fase, que dura unas 5 h, el virus penetra en la células por fagocitosis y se libera de la cubierta. La fase de "eclipse", con el virus presentándose como hebras de DNA, dura aproximadamente de 8 a 10 h. En la fase final los viriones se desarrollan dentro de zonas bien definidas en el viroplasma desde las cuales los viriones maduros migran hasta los limites celulares. A partir de alii parecen salir por exocitosis o en proyecciones de microvellosidades "pinzadas" hacia el exterior; también pueden ser liberados como consecuencia de la desintegración de la célula huésped. [Onwuka, S.K., Jenkinson, D. Mc, Inglis, L., Pow, I., GRAY, E.W., Reid, H.W. Ultrastructural studies of orf virus infection and replication in fetal lamb fibrocytes (Estudios ultraestructurales de la infección por el virus del ectima contagioso y replicación en fibrocitos fetales de carnero). Abstract- The cycle of replication of orf virus was identified in temporal in vitro studies and a putative model was developed. During the first phase, which lasts about 5 h, the virus enters the cells by a phagocytic process and uncoats. The "eclipse" phase, with the virus apparently present as strands of DNA, lasts for approximately the next 8-10 h. In the final phase virions develop within well-defined zones of viroplasm from which mature virions migrate to the margins of the cell. There they apparently exit either by exocytosis or within microvillous projections which are "pinched off"; they can also be released by disintegration of the host cell.

Johne's disease in a herd of farmed red deer

An outbreak of Johne's disease in a herd of farmed red deer was studied for four years. Serological, histopathological and cultural techniques were used to monitor the progress of the disease, and delayed type hypersensitivity skin tests were also applied. The results of the serological tests showed that they were poor predictors of future clinical cases and did not consistently identify animals harbouring mycobacteria. The histopathological methods provided a sensitive and specific means of confirming the infection. The skin tests had a low sensitivity and the results were poorly correlated with the serological results in seropositive animals. A vaccination policy was instituted which was accompanied by a change in the pattern of disease. Although the histopathological evidence suggested that the infection was still occurring, there was a marked reduction in the incidence of clinical disease. Vaccinated animals showed a good response to the skin test.

The virus causing encephalomyelitis in sheep in Spain: a new member of the tick-borne encephalitis group

The nucleotide and deduced primary amino acid sequence of the envelope gene of two virus isolates from the brains of Spanish sheep with encephalomyelitis, were determined and compared with those of other flaviviruses. The amino acid alignments showed that the Spanish viruses shared 95 to 96 per cent homology with the envelope protein of louping ill virus and western European tick-borne encephalitis virus. In comparison, the maximum variation in amino acid identities among strains of louping ill virus from the British Isles is 1.8 per cent. The Spanish isolates were distinguishable from all other known flaviviruses by the presence of a unique tripeptide sequence (AQR) at amino acid positions 232 to 234 in the E protein, the position at which a genetic marker for distinct flavivirus species has been identified. Other genetic markers, viz DSGHD (amino acids 320 to 324) and EHLPTA (amino acids 207 to 212), which identify the tick-borne encephalitis group within the genus Flavivirus, were present in the amino acid sequences of the Spanish virus. It is concluded that the cause of sheep encephalomyelitis in Spain is a distinct species in the tick-borne encephalitis virus group.

Detection of louping ill virus in formalin-fixed, paraffin wax-embedded tissues of mice, sheep and a pig by the avidin-biotin-complex immunoperoxidase technique

An immunohistochemical method for the detection of louping ill virus antigen in formalin-fixed, paraffin wax-embedded tissues by an avidin-biotin-complex (ABC) immunoperoxidase technique was established. The tissues examined were from the brains of 10 mice, five sheep and one pig. The mice were experimentally infected with louping ill virus whereas the sheep and the pig were field cases of louping ill confirmed by clinical examination, and by histological and serological methods.

PCR detection of ovine herpesvirus-2 DNA in Indonesian ruminants--normal sheep and clinical cases of malignant catarrhal fever

Malignant catarrhal fever (MCF), a fatal viral disease of cattle and other large ruminants, has a worldwide distribution. There are two forms of the disease, one of which, is caused by Alcelaphine herpesvirus-1 (AHV-1) and is derived from wildebeest. The other form is associated with domestic sheep and is caused by ovine herpesvirus-2 (OHV-2). The disease in Indonesia is sheep-associated with the preferred livestock of this area, Balinese cattle (Bos javanicus) and water buffalo (Bubalus bubalis), both highly susceptible to SA-MCF. The incidence in these species is thought to be high but the prevalence and economic losses attributable to SA-MCF have been difficult to assess. a polymerase chain reaction (PCR) test, based on a cloned OHV-2 gene sequence, was successfully applied to the detection of OHV-2 DNA in normal sheep and animals affected with SA-MCF. OHV-2 DNA was detected in eleven confirmed cases of SA-MCF and in the peripheral blood leucocyte (PBL) fraction of six latently infected sheep. These findings have confirmed that the PCR can be of value in establishing a diagnosis of MCF and that the aetiological agent of MCF in Indonesia is OHV-2. The amplification of DNA from the PBL of goats suggests that they are infected with a similar or identical herpesvirus.

Lack of cross-protection between vaccinia virus and orf virus in hysterectomy-procured, barrier-maintained lambs

Hysterectomy-procured, barrier maintained lambs were immunised with either of virus or vaccinia virus and subsequently challenged with both viruses. Under these conditions lambs were protected from challenge with the homologous virus but no cross-protection was observed. The feeding of colostrum that contained antibodies to orf virus had no effect on the duration of viral lesions. Immunoblotting analysis and ELISA of serum samples taken during the course of the experiment indicated that the animals mounted antibody responses to both viruses. The cross recognition of 3 vaccinia virus antigens by the hyperimmune anti-orf virus serum was revealed by immunoblotting.

Identification of naturally occurring monoclonal antibody escape variants of louping ill virus

Louping ill virus isolates from Great Britain, Ireland and Norway were compared antigenically by indirect immunofluorescence, haemagglutination-inhibition and neutralization tests using a panel of five envelope-specific and five non-structural protein NS1-specific monoclonal antibodies raised against louping ill virus. The viruses were grouped according to their reactivities with the antibodies. Group 1, members of which were isolated between 1931 and 1987, consisted of 13 viruses that reacted with all antibodies, whereas group 2, members of which were isolated after 1980, consisted of five viruses that were positive with only eight of the 10 monoclonal antibodies. The two monoclonal antibodies that did not react with the group 2 viruses are known to be neutralizing antibodies and the amino acids that they recognize in the viral envelope protein have been identified. We therefore refer to the group 2 viruses as naturally occurring monoclonal antibody escape variants. When compared with group 1 viruses, the escape variants showed reduced virulence for mice in terms of the time taken to kill and/or the proportion that died, following intraperitoneal inoculation. The nucleotide and deduced amino acid sequences of the envelope gene of one escape variant were compared with those of several group 1 viruses. A single amino acid substitution at residue 308 was detected in the envelope protein of the escape variant which corresponds precisely to the position in experimentally selected attenuated monoclonal antibody escape mutants. The importance and potential implications of these naturally occurring variants in louping ill epizootiology and vaccine-based control are discussed.

Tick-borne flavivirus NS1 gene: identification of conserved peptides and antigenic analysis of recombinant louping ill virus NS1 protein

The nucleotide sequence of the NS1 gene of louping ill (LI) virus has been determined. The sequence shows a high degree of homology with other members of the tick-borne serocomplex of flaviviruses and a lower homology with the mosquito-borne flaviviruses. Alignment of the deduced NS1 amino acid sequences with all tick-borne flavivirus NS1 sequences, identified four peptide regions which were conserved for all tick-borne flaviviruses, but were variable amongst mosquito-borne flaviviruses. A dendrogram, derived from the alignment of the NS1 protein sequences, indicated an evolutionary relationship that quite closely reflects the recognised serological classification. The LI virus NS1 protein expressed in Escherichia coli and baculoviruses showed similar antigenic reactivity to the authentic virus-coded protein when tested with NS1-specific monoclonal antibodies, but did not form high molecular weight complexes and was not secreted from cells.

Classification of a new member of the TBE flavivirus subgroup by its immunological, pathogenetic and molecular characteristics: identification of subgroup-specific pentapeptides

The antigenic, pathogenic and molecular characteristics of Turkish sheep encephalitis (TSE) virus, strain TTE80, were compared with other members of the tick-borne encephalitis (TBE) virus complex. Monoclonal antibodies with defined specificity for the flavivirus envelope glycoprotein distinguished TSE virus from louping ill (LI), western or far eastern TBE, Langat and Powassan virus in indirect immunofluorescence, haemagglutination-inhibition and neutralization tests. On the other hand, TSE virus, which produces an LI-like disease in sheep, resembled LI virus in mouse neurovirulence tests. Molecular homology data of all the structural genes of TSE virus compared with other tick-borne flaviviruses demonstrated that TSE virus is a distinct member in the TBE virus subgroup. The data are consistent with the conclusion that TSE virus has evolved by a separate evolutionary pathway as compared with the close antigenic relatives, western European, far eastern TBE viruses and LI virus. By aligning the encoded amino acids in the viral envelope glycoprotein of mosquito- and tick-borne flaviviruses, we have also identified subgroup-specific pentapeptide motifs for the tick-borne encephalitis, Japanese encephalitis and dengue subgroup viruses of the genus Flavivirus. These pentapeptides have important implications for the evolution, classification and diagnosis of flaviviruses.

PCR detection of the sheep-associated agent of malignant catarrhal fever

From a genomic library previously constructed from a lymphoblastoid cell line (LCL) propagated from a bovine case of sheep-associated malignant catarrhal fever (SA-MCF), caused by ovine herpesvirus-2 (OHV-2), several OHV-2 clones were identified and characterised by hybridisation using probes from the unique region of the Alcelaphine herpesvirus-1 (AVH-1) genome. Nucleotide sequence from one clone was generated and the predicted amino acid sequence was found to contain regions of homology with the 140 and 160 kDa tegument proteins of Epstein-Barr virus and herpesvirus saimiri respectively. Oligonucleotide primers were constructed and a polymerase chain reaction (PCR) test was developed for the detection of OHV-2 viral DNA. Amplified product was identified by restriction with RsaI and BmyI. The primers were highly specific for OHV-2 DNA with a limit of detection of 6.4 pg of genomic DNA derived from the parent LCL. This was estimated to correspond to one diploid bovine cell. The PCR was successfully applied to detect OHV-2 DNA in peripheral blood leucocytes (pbl) from clinical cases of SA-MCF and normal sheep.

Sequencing and antigenic studies of a Norwegian virus isolated from encephalomyelitic sheep confirm the existence of louping ill virus outside Great Britain and Ireland

We have carried out an antigenic analysis and nucleotide sequence comparison of the envelope glycoprotein of recognized louping ill virus strains isolated from Scotland with that of a Norwegian virus known to cause encephalomyelitis in sheep. Monoclonal antibodies with defined specificity for the louping ill virus envelope glycoprotein failed to distinguish between the Norwegian virus and prototype louping ill virus in indirect immunofluorescence, haemagglutination inhibition and neutralization tests. Nucleotide sequencing of the envelope glycoprotein and alignment of the deduced amino acid sequence with other known sequences revealed that the Norwegian virus closely resembles (> 95% identity for nucleotide and > 98% identity for amino acid sequences) louping ill virus. Maximum variation in identities among four strains of louping ill virus were 4.4% and 1.8% respectively for nucleotide and amino acid alignments. We conclude that sheep encephalomyelitis in Norway is caused by louping ill virus. These results imply that other viruses present in Europe and known to cause encephalitis/encephalomyelitis of sheep could be caused by louping ill virus.

Louping ill virus envelope protein expressed by recombinant baculovirus and vaccinia virus fails to stimulate protective immunity

We have constructed recombinant baculoviruses and vaccinia viruses containing cloned DNA, encoding either the envelope protein alone or all of the structural proteins (core, membrane and envelope) of louping ill virus. Glycosylated viral envelope protein, presented both inside and on the surface of insect and mammalian cells, was expressed by all four recombinant viruses. Differences in antigenic presentation of the envelope protein were observed between the envelope protein and structural protein constructs as well as between the insect and mammalian cell expression systems. Despite the expression of epitopes known to elicit neutralizing and protective antibodies when present in authentic antigen, the recombinant envelope protein expressed by either vector failed to induce, in mice or rabbits, either neutralizing or protective antibodies against louping ill virus.

Nucleotide sequence of the envelope glycoprotein of Negishi virus shows very close homology to louping ill virus

Negishi virus, a member of the family Flaviviridae, was originally isolated in Japan, during an outbreak of Japanese encephalitis. Antigenically, however, Negishi virus resembles the tick-borne rather than the mosquito-borne flaviviruses. Monoclonal antibodies that bind louping ill virus showed a close antigenic relationship between louping ill and Negishi virus. The genes encoding the envelope glycoprotein of Negishi virus (strain 3248/49/P10) and louping ill virus (strain SB526) were cloned and sequenced. They showed a very close homology at both the nucleotide and deduced amino acid levels. Comparison with the known sequence of another strain of louping ill virus (strain 369/T2) and with other tick-borne flaviviruses showed that Negishi virus was more closely related to louping ill virus than to the other tick-borne viruses. The significance of this observation for virus evolution, virus distribution in the environment, and the potential use of nucleotide sequencing for rapid and precise identification of flaviviruses are discussed.