Granulocyte chemotactic properties of M. tuberculosis versus M. bovis-infected bovine alveolar macrophages.

The incidence of bovine tuberculosis (TB) continues to rise, and causes significant economic losses worldwide. The causative agent of bovine TB, Mycobacterium bovis, is closely related to the human pathogen M. tuberculosis, and yet these two organisms differ profoundly in their ability to cause disease in cattle. The innate immune system is primarily responsible for controlling disease, with the alveolar macrophage (AlvMvarphi) acting as one of the first points of contact between host and respiratory pathogens. In this study we have examined some of the differences in this component of the host immune response to M. bovis and M. tuberculosis, with the aim of improving our understanding of why M. bovis is able to cause disease in cattle whereas M. tuberculosis is efficiently controlled. Initial studies using microarray technology revealed that chemokines represented some of the most differentially expressed genes between M. tuberculosis and M. bovis-infected bovine AlvMvarphi. M. tuberculosis-infected bovine AlvMvarphi expressed significantly higher levels of the chemokines CCL3, CCL4, CCL5 and CXCL8, whereas M. bovis-infected AlvMvarphi were shown to express higher levels of CCL23. We further demonstrated the role of chemokines in bovine TB by showing that supernatants from AlvMvarphi infected with M. tuberculosis were significantly more effective than those from M. bovis-infected cells at attracting bovine granulocytes in an in vitro chemotaxis assay. These results have significant implications in vivo as they suggest that the M. bovis-infected macrophage is able to circumvent activation of the host chemotactic response and thereby evade killing by the host immune system.

Differential responses of bovine macrophages to infection with bovine-specific and non-bovine specific mycobacteria.

Members of the Mycobacterium tuberculosis complex share a high level of genetic identity, however pathogenic ability appears to display host restriction. Interestingly M. tuberculosis, the primary cause of tuberculosis in humans, is non-pathogenic in cattle. Conversely Mycobacterium bovis, the cause of tuberculosis in cattle, is also responsible for a proportion of tuberculosis cases in humans. We hypothesise that differences in the abilities of M. bovis and M. tuberculosis to cause pathogenesis in cattle will be reflected in their interactions with bovine antigen presenting cells. To analyse the importance of host species in mycobacterial infection, bovine antigen presenting cells were infected with bovine or human mycobacterial strains. Levels of nitric oxide and tumour necrosis factor production, markers of antimicrobial activity, were found to be associated with a specific mycobacterial strain, and varied between cell subsets.

CD45 is required for type I IFN production by dendritic cells.

CD45 is a leukocyte tyrosine phosphatase, essential for normal immune responses. We have studied the function of splenic dendritic cells of CD45(+/+), CD45(-/-), CD45RABC and CD45RO transgenic mice. We show that there are increased numbers of plasmacytoid dendritic cells in CD45(-/-) mice. DC of all mice are capable of responding to lymphocytic choriomeningitis virus (LCMV) infection by up-regulation of MHC and costimulatory molecules. DC of CD45(-/-) mice have an impaired capacity to produce type I interferons in response to LCMV infection in vivo. These data indicate that lack of CD45 expression in DC has a profound effect on their function. This is largely restored by CD45RABC or CD45RO transgenes.

CD45 negatively regulates tumour necrosis factor and interleukin-6 production in dendritic cells.

CD45 is known to regulate signalling through many different surface receptors in diverse haemopoietic cell types. Here we report for the first time that CD45-/- bone marrow dendritic cells (BMDC) are more activated than CD45+/+ cells and that tumour necrosis factor (TNF) and interleukin-6 (IL-6) production by BMDC and splenic dendritic cells (sDC), is increased following stimulation via Toll-like receptor (TLR)3 and TLR9. Nuclear factor-kappaB activation, an important downstream consequence of TLR3 and TLR9 signalling, is also increased in CD45-/- BMDC. BMDC of CD45-/- mice also produce more TNF and IL-6 following stimulation with the cytokines TNF and interferon-alpha. These results show that TLR signalling is increased in CD45-/- dendritic cells and imply that CD45 is a negative regulator of TLR and cytokine receptor signalling in dendritic cells.

Expression of TOLL-like receptors (TLR) by bovine antigen-presenting cells-potential role in pathogen discrimination?

Invading pathogens are controlled by the innate and adaptive arms of the immune system. Adaptive immunity, mediated by B and T lymphocytes, recognises pathogens via high affinity receptors. However, the establishment of a primary adaptive immune response is not rapid enough to eradicate invading microorganisms as it involves cell proliferation, gene activation and protein synthesis. More rapid defence mechanisms are provided by innate immunity, which recognises invading pathogens by germ-line-encoded pattern recognition receptors. Recent evidence shows that this recognition can mainly be attributed to the family of TOLL-like receptors (TLR). Binding of pathogen-associated molecular patterns to TLR induces the production of reactive oxygen and nitrogen intermediates, pro-inflammatory cytokines, and up-regulates expression of co-stimulatory molecules, subsequently initiating the adaptive immunity. In this paper, we will discuss the current knowledge with regards to the TLR, and in particular the bovine family of TLR. In addition, we will show the expression of TLR mRNA in bovine antigen-presenting cell subsets, summarise the discovery and the critical roles of TLR2 in host defence against Mycobacteria, and provide evidence for a mycobacteria species-specific response of bovine macrophages.