Salmonella enterica serovar Dublin (S. Dublin) is associated with enteritis, typhoid and abortion in cattle. Infections are acquired by the oral route, and the bacteria transit through varied anatomical and cellular niches to elicit systemic disease. S. Dublin must therefore sense and respond to diverse extrinsic stimuli to control gene expression in a spatial and temporal manner. Two-component systems (TCSs) play key roles in such processes, and typically contain a membrane-associated sensor kinase (SK) that modifies a cognate response regulator. Analysis of the genome sequence of S. Dublin identified 31 conserved SK genes. Each SK gene was separately disrupted by lambda Red recombinase-mediated insertion of transposons harbouring unique sequence tags. Calves were challenged with a pool of the mutants together with control strains of defined virulence by the oral and intravenous routes. Quantification of tagged mutants in output pools derived from various tissues and cannulated lymphatic vessels allowed the assignment of spatial roles for each SK following oral inoculation or when the intestinal barrier was bypassed by intravenous delivery. Mutant phenotypes were also assigned in cultured intestinal epithelial cells. Mutants with insertions in barA, envZ, phoQ, ssrA or qseC were significantly negatively selected at all enteric and systemic sites sampled after oral dosing. Mutants lacking baeS, dpiB or citA were negatively selected at some but not all sites. After intravenous inoculation, only barA and phoQ mutants were significantly under-represented at systemic sites. The novel role of baeS in intestinal colonization was confirmed by oral co-infection studies, with a mutant exhibiting modest but significant attenuation at a number of enteric sites. This is the first systematic analysis of the role of all Salmonella TCSs in a highly relevant model of enteric fever. Spatial roles were assigned to eight S. Dublin SKs, but most were not essential for intestinal or systemic infection of the target host.

A reverse transcription Linear-After-The-Exponential polymerase chain reaction (RT LATE-PCR) assay was evaluated for detection of foot-and-mouth disease virus (FMDV). This pan-serotypic assay targets highly conserved sequences within the 3D (RNA polymerase) region of the FMDV genome, and uses end-point hybridisation analysis of a single mismatch-tolerant low temperature probe to confirm the identity of the amplicons. An Armored RNA (R) served as an internal control to validate virus negative results. The ability of the assay to identify FMDV was directly compared to a real-time RT-PCR assay routinely used by reference laboratories. The analytical sensitivity of the RT LATE-PCR assay was 10 genomic copies and the dynamic range of the test was identical to real-time RT-PCR based on decimal dilutions of an FMDV-positive sample. This pan-serotypic assay was able to detect FMDV in a broad range of clinical samples collected from field cases of FMD (n = 121), while samples of other viruses causing vesicular disease in livestock and genetic relatives of FMDV were negative. In addition to the laboratory-based utility of this diagnostic test, the RT LATE-PCR assay format has potential application for use in a portable ("point-of-care") device designed to achieve rapid detection of FMDV in the field.

Intra-nasal administration of a recombinant adenovirus expressing Mycobacterium tuberculosis antigen 85A (Ad85A) has been shown to provide protection against challenge with M. tuberculosis. However the role of the upper respiratory tract associated lymphoid tissue, specifically the nasal associated lymphoid tissue (NALT), in providing protection has yet to be elucidated. Here we administered Ad85A to BALB/c mice alone or following BCG priming, using intranasal inocula targeting the whole respiratory tract or only the NALT, to show that Ad85A induces an immune response in the NALT insufficient to provide protection. Rather, Ad85A delivered through the respiratory tract must induce a deep lung immune response in order to protect against M. tuberculosis.

Background: In northern Europe, bluetongue (BT) caused by the BT virus (BTV), serotype 8, was first notified in August 2006 and numerous ruminant herds were affected in 2007 and 2008. However, the origin and the time and place of the original introduction have not yet been determined. Methods and Principal Findings: Four retrospective epidemiological surveys have been performed to enable determination of the initial spatiotemporal occurrence of this emerging disease in southern Belgium: investigations of the first recorded outbreaks near to the disease epicenter; a large anonymous, random postal survey of cattle herds and sheep flocks; a random historical milk tank survey of samples tested with an indirect ELISA and a follow-up survey of nonspecific health indicators. The original introduction of BTV into the region probably occurred during spring 2006 near to the National Park of Hautes Fagnes and Eifel when Culicoides become active. Conclusions/Significance: The determination of the most likely time and place of introduction of BTV8 into a country is of paramount importance to enhance awareness and understanding and, to improve modeling of vector-borne emerging infectious diseases.