Multi-locus phylogeny and species delimitation of Australo-Papuan blacksnakes (Pseudechis Wagler, 1830: Elapidae: Serpentes).

Genetic analyses of Australasian organisms have resulted in the identification of extensive cryptic diversity across the continent. The venomous elapid snakes are among the best-studied organismal groups in this region, but many knowledge gaps persist: for instance, despite their iconic status, the species-level diversity among Australo-Papuan blacksnakes (Pseudechis) has remained poorly understood due to the existence of a group of cryptic species within the P. australis species complex, collectively termed "pygmy mulga snakes".

The cellular immune recognition of proteins expressed by an African swine fever virus random genomic library.

The cellular immune recognition of peptides expressed by an African swine fever virus (ASFV) random genomic library has been studied. DNA from the Malawi (LIL20/1) ASFV isolate was randomly sheared by sonication, cloned into a plasmid vector downstream of a bacteriophage T7 promoter, and 72 recombinant plasmids were arbitrarily selected. These plasmids were transiently expressed following transfection into major histocompatibility complex (MHC) class I(+) class II(-) matched pig skin cells, which had been co-infected with vTF7-3, a recombinant vaccinia virus encoding bacteriophage T7 RNA polymerase.

African swine fever virus: a B cell-mitogenic virus in vivo and in vitro.

The two major characteristics of pathogenesis in African swine fever virus (ASFV) infections of domestic pigs are massive B-cell apoptosis and haemorrhage. The effects of ASFV on porcine B cells have therefore been systematically examined in vivo, by using virus-infected pigs and SCID-Beige mice reconstituted with porcine bone marrow, and in vitro, by using porcine B-cell lines and B cells from normal and ASFV-infected pigs. Secretion of porcine Ig was stimulated by ASFV both in vivo and in bone marrow cultures in vitro, with the virulent Malawi isolate of ASFV being the most effective.

Demonstration of bovine CD8+ T-cell responses to foot-and-mouth disease virus.

The aim of this study was to investigate the importance of cellular immunity in foot-and-mouth disease in cattle, in particular to determine whether a CD8+ T-cell response could be detected, as these cells may play a role in both immunity and virus persistence. As attempts to characterize classical cytotoxic T cells had yielded non-reproducible results, largely due to high backgrounds in control cultures, a proliferation assay was developed that was demonstrated to detect antigen-specific, MHC class I-restricted bovine CD8+ cells responding to foot-and-mouth disease virus (FMDV). Proliferative CD8+ T-cell responses were detected consistently from 10 to 14 days following infection with FMDV and typically lasted 3-4 weeks.

Heterotypic recognition of recombinant FMDV proteins by bovine T-cells: the polymerase (P3Dpol) as an immunodominant T-cell immunogen.

In this study we have examined the recognition of VP0, VP1, VP2, VP3 and P3Dpol by PBMC and CD4+ T-cells from infected, vaccinated-challenged, and multiply-vaccinated (O1, A24, C1 or ASIA1) cattle using recombinant proteins of an O1 serotype virus. The structural protein VP1 was recognised in an homotypic context whereas VP2, VP3, VP4 and P3Dpol were also recognised by T-cells from animals exposed to heterotypic viruses. Only the non-structural protein P3Dpol was consistently recognised by T-cells from the majority of animals examined and heterotypic recognition correlated with the presence of serologically detectable P3Dpol in purified virus.