Stephen E. Wright

Transgenic chickens: Insertion of retroviral genes into the chicken germ line

We infected early chicken embryos by injection of wild-type and recombinant avian leukosis viruses into the yolk of unincubated, fertile eggs. The viremic males (designated generation 0 (G-0] were tested for transmission of proviral DNA to their G-1 progeny. Nine of 37 G-0 viremic males were mosiac and proviral DNA was transmitted to their progeny at frequencies varying from 1 to 11%. All of the G-1 progeny examined by restriction enzyme analysis for clonality of proviral junction fragments had one to three simple but different fragments. The proviral DNA was transmitted from G-1 to the G-2 progeny in a Mendelian fashion thus proving that retroviral genes have been inserted into the chicken germ line. One of the viruses is a candidate vector for insertion of foreign genes into the chicken germ line.

Long-term passage of tachyzoites in tissue culture can attenuate virulence of Neospora caninum in vivo

To determine whether prolonged in vitro passage would result in attenuation of virulence in vivo, Neospora caninum tachyzoites were passaged for different lengths of time in vitro and compared for their ability to cause disease in mice. Groups of Balb/c mice were inoculated intraperitoneally with 5 x 10(6) or 1 x 10(7) of low-passage or high-passage N. caninum tachyzoites. The mice were monitored for changes in their demeanour and body weight, and were culled when severe clinical symptoms of murine neosporosis were observed. Mice inoculated with the high-passage parasites survived longer (P<0.05), and showed fewer clinical symptoms of murine neosporosis, compared to the mice receiving the low-passage parasites. The parasite was detected in the brains of inoculated mice using immunohistochemistry and ITS1 PCR. Tissue cysts containing parasites were seen in mice inoculated with both low-passage and high-passage parasites. When the in vitro growth rates of the parasites were compared, the high-passage parasites initially multiplied more rapidly (P<0.001) than the low-passage parasites, suggesting that the high-passage parasites had become more adapted to tissue culture. These results would suggest that it is possible to attenuate the virulence of N. caninum tachyzoites in mice through prolonged in vitro passage.

Evidence of the three main clonal Toxoplasma gondii lineages from wild mammalian carnivores in the UK

Toxoplasma gondii is a zoonotic pathogen defined by three main clonal lineages (types I, II, III), of which type II is most common in Europe. Very few data exist on the prevalence and genotypes of T. gondii in the UK. Wildlife can act as sentinel species for T. gondii genotypes present in the environment, which may subsequently be transmitted to livestock and humans. DNA was extracted from tissue samples of wild British carnivores, including 99 ferrets, 83 red foxes, 70 polecats, 65 mink, 64 badgers and 9 stoats. Parasite DNA was detected using a nested ITS1 PCR specific for T. gondii, PCR positive samples were subsequently genotyped using five PCR-RFLP markers. Toxoplasma gondii DNA was detected within all these mammal species and prevalence varied from 6·0 to 44·4% depending on the host. PCR-RFLP genotyping identified type II as the predominant lineage, but type III and type I alleles were also identified. No atypical or mixed genotypes were identified within these animals. This study demonstrates the presence of alleles for all three clonal lineages with potential for transmission to cats and livestock. This is the first DNA-based study of T. gondii prevalence and genotypes across a broad range of wild British carnivores.

Inoculation of Balb/c mice with live attenuated tachyzoites protects against a lethal challenge of Neospora caninum.

Neospora caninum tachyzoites attenuated through passage in tissue culture were tested for their ability to induce protective immunity against a lethal challenge dose of parasites. Balb/c mice were each inoculated with either 1x10(6) live virulent tachyzoites (Group 1) or 1x10(6) live attenuated tachyzoites (Group 2), while (Group 3) received a control inoculum. All mice were each challenged 28 days later with 5x10(6) virulent parasites. Histopathological lesions in the brains including necrosis and microgliosis were observed following post-mortem on day 28 post-challenge (p.c.) in 71% of Group 1 and 56% of Group 2. Immunohistochemistry (IHC) of these lesions showed tachyzoites and Neospora antigens to be associated with moderate brain lesions in 17% of Group 1, while in 11% of Group 2 N. caninum tissue cysts were detected, but these were not associated with lesions, Parasite DNA was detected by PCR in the brains of 86% of mice in Group 1 and 56% of mice in Group 2. Following challenge the mice in Group 3 showed high morbidity and 100% mortality within 17 days p.c. Positive IHC for N. caninum was seen in 88% of the Group 3 mice and parasite DNA was detected in all brain samples. This study shows that it is possible to protect against a lethal challenge of N. caninum through inoculation with attenuated or virulent tachyzoites. However, more severe pathology developed in mice initially inoculated with virulent parasites following a secondary challenge, compared to mice initially inoculated with attenuated parasites.

Maternal and foetal immune responses of cattle following an experimental challenge with Neospora caninum at day 70 of gestation

The immune responses of pregnant cattle and their foetuses were examined following inoculation on day 70 of gestation either intravenously (iv) (group 1) or subcutaneously (sc) (group 2) with live NC1 strain tachyzoites or with Vero cells (control) (group 3). Peripheral blood mononuclear cell (PBMC) responses to Neospora antigen and foetal viability were assessed throughout the experiment. Two animals from each group were sacrificed at 14, 28, 42 and 56 days post inoculation (pi). At post mortem, maternal lymph nodes, spleen and PBMC and when possible foetal spleen, thymus and PBMC samples were collected for analysis. Inoculation with NC1 (iv and sc) lead to foetal deaths in all group 1 dams (6/6) and in 3/6 group 2 dams from day 28pi; statistically significant (p ≤ 0.05) increases in cell-mediated immune (CMI) responses including antigen-specific cell proliferation and IFN-γ production as well as increased levels of IL-4, IL-10 and IL-12 were observed in challenged dams compared to the group 3 animals. Lymph node samples from the group 2 animals carrying live foetuses showed greater levels of cellular proliferation as well as significantly (p ≤ 0.05) higher levels of IFN-γ compared to the dams in group 2 carrying dead foetuses. Foetal spleen, thymus and PBMC samples demonstrated cellular proliferation as well as IFN-γ, IL-4, IL-10 and IL-12 production following mitogenic stimulation with Con A from day 14pi (day 84 gestation) onwards. This study shows that the generation of robust peripheral and local maternal CMI responses (lymphoproliferation, IFN-γ) may inhibit the vertical transmission of the parasite.

Detection of Neospora caninum in wild carnivorans in Great Britain.

Samples of brain and other tissues were collected from 99 ferrets (Mustela furo), 83 red foxes (Vulpes vulpes), 70 European polecats (Mustela putorius), 65 American mink (Neovison vison), 64 Eurasian badgers (Meles meles) and 9 stoats (Mustela erminea), from around Great Britain. DNA was extracted from approximately 1g of tissue and tested by specific nested ITS1 PCR for Neospora caninum. The results from the PCR demonstrated that Neospora specific DNA was detected in all species of wild carnivorans with the exception of the stoats (0/9). Neospora DNA positive samples were detected in: polecats 18.6% (13/70), badgers 10.9% (7/64), ferrets 10.1% (10/99), foxes 4.8% (4/83) and mink 4.6% (3/65). In the badgers N. caninum DNA positive samples were found in brain (n=2), liver (n=2) and neck muscle (n=3). Selected positive ITS1 DNA sequences were submitted to Genbank. Sequence UKwildlife1 (accession number JX857862) was found in two badgers, whilst UKwildlife2 and UKwildlife3 (accession numbers JX857863 and JX857864 respectively) were found in ferrets, all three sequences demonstrated point mutations at a single base, while sequence UKwildlife4 (accession number JX857865) was found in all the species that tested positive and showed complete identity when compared against published reference sequences for: N. caninum (Nc Liverpool isolate, EU564166). Our data shows that almost all the wild carnivoran mammal species tested are intermediate hosts for N. caninum and are therefore capable of acting as reservoirs of infection for other species. These species could also act as useful sentinel species, demonstrating the presence of the parasite in particular geographical and environmental locations.

Region coding for subgroup specificity of envelope of avian retroviruses does not determine lymphomagenicity

The purpose of this study was to test whether the region coding for subgroup envelope specificity was a determinant of oncogenic potential. An avian retrovirus recombinant was constructed to contain the envelope gene (env) determinant for subgroup A of an avian RNA tumor virus in one of the non-oncogenic, endogenous avian retroviruses, RAV-0. The results show that such a recombinant virus does not induce lymphoma when injected into susceptible, newborn chicks. Thus, it is concluded that the envelope determinant for subgroup of avian RNA tumor viruses does not determine malignant potential.

Detection and Localization of the v-myb(AMV) Gene Products of Avian Myeloblastosis Virus by a Synthetic Peptide Antiserum

An antiserum made against a synthetic peptide from an internal region of the predicted amino acid sequence of the avian myeloblastosis virus (AMV) transforming v-myb(AMV) gene identified two products, p46v-myb(AMV) and p32v-myb(AMV), which were localized in the nucleus of AMV-transformed myeloblasts. We propose that these proteins are the in vivo products of the v-myb(AMV) gene and thus the transforming protein(s) of AMV.

Transformation-Defective Virus Generation from Cloned Nondefective Avian Sarcoma Virus

An avian sarcoma virus, twice cloned by soft agar colony assay without intervening passage of the virus and apparently freed of transformation-defective ( td ) viruses, has been found

Candidate Products of Avian Myeloblastosis Virus Oncogene Region Produced by in vitro Translation of Genomic RNA

Avian myeloblastosis virus (AMV) genomic RNA was translated in vitro to identify the AMV transforming gene (myb) product(s). Full-length RNA yielded, in addition to the expected Pr76gag, a gag-related product of 92,000 daltons which did not appear to be a gag-oncogene fusion protein. Subgenomic AMV RNA in vitro translation, nonstructural products (specific for AMV) were of 54,000, 49,000 and 34,000 daltons. Based on their sizes and similar peptide maps for the smaller two proteins, it is proposed that they derive from the myb region of AMV.