A bovine macrophage screening system for identifying attenuated transposon mutants of Mycobacterium avium subsp. paratuberculosis with vaccine potential.

Johne's disease is a chronic granulomatous enteritis in ruminants caused by Mycobacterium avium subsp. paratuberculosis (MAP). The disease is responsible for considerable economic losses in the livestock industry and in particular within the dairy sector. A more effective vaccine against Johne's disease would be of major benefit. In this study, we developed an efficient procedure for identifying mutants of MAP with reduced virulence that are potential live vaccine candidates against Johne's disease. A mariner transposon was used to create random insertional libraries in two different MAP strains (989 and k10), an effective cattle macrophage survival system was developed, and a total of 1890 insertion mutants were screened by using a 96-prong multi-blot replicator (frogger) system. Two of the transposon mutants with poor survival ability in macrophages were tested in mice. These strains were found to be attenuated in vivo, thereby validating the further use of this macrophage screening system to identify MAP mutants with potential as candidate vaccines against Johne's disease.

Inactivation of the Mycobacterium tuberculosis fadB4 gene results in increased virulence in host cell and mice.

The genome of Mycobacterium tuberculosis encodes many proteins involved in fatty acid metabolism, a subset of which are required for virulence. The Mycobacterium tuberculosis fadB4 gene, which shares strong similarity with oxidoreductases and fatty acid synthases, is up-regulated during infection of macrophages and is predicted to protect the bacterium from the hostile environment of the host cell. In order to determine if fadB4 plays a role in the virulence of M. tuberculosis, we constructed a M. tuberculosis mutant in which the fadB4 had been disrupted (DeltafadB4). Surprisingly, DeltafadB4, grew more rapidly in host cells compared to wild-type M. tuberculosis or the DeltafadB4 or the gene-disrupted strain complemented with fadB4. In addition, macrophages infected with DeltafadB4 displayed reduced secretion of the cytokine TNF-alpha, suggesting a role for the FadB4 protein in influencing the pro-inflammatory host response to M. tuberculosis. After infection of mice, DeltafadB4 demonstrated an increased replication at early time-points post-infection compared to the growth of wild-type M. tuberculosis. This increased capacity of DeltafadB4 to replicate in vivo was reflected in the decreased time to death of immuno-deficient RAG-1(-/-) mice infected with M. tuberculosis lacking the fadB4 gene. Therefore fadB4 is part of the family of genes whose expression serves to regulate the virulence of M. tuberculosis within the host.

Effect of phthiocerol dimycocerosate deficiency on the transcriptional response of human macrophages to Mycobacterium tuberculosis.

The control of mycobacterial infections is dependent on the finely tuned synergism between the innate and adaptive immune responses. The macrophage is the major host cell for Mycobacterium tuberculosis and the degree of virulence of mycobacteria may influence the initial macrophage response to infection. The cell wall molecule, phthiocerol dimycocerosate (DIM), is an important virulence factor that influences the early growth of M. tuberculosis in the lungs. To explore the basis for this effect we have compared the early gene response of human THP-1 macrophages to infection with virulent M. tuberculosis and the DIM-deficient DeltafadD26 M. tuberculosis strain using microarrays. Detailed analysis revealed a common core of macrophage genes, which were rapidly induced following infection with both strains, and deficiency of DIM had no significant effect on this initial macrophage transcriptional responses. In addition to chemokines and pro-inflammatory cytokines, the early response genes included components of the Toll-like receptor signalling, antigen presentation and apoptotic pathways, interferon response genes, cell surface receptors and their ligands, including TNF-related apoptosis inducing ligand (TRAIL) and CD40, and other novel genes. Therefore, although fadD26 deficiency is responsible for the early attenuation of the growth of M. tuberculosis in vivo, this effect is not associated with differences in the initial macrophage transcriptional response.