Human case of bubonic plague resulting from the bite of a wild Gunnison's prairie dog during translocation from a plague-endemic area.

Plague is a zoonotic disease (transmitted mainly by fleas and maintained in nature by rodents) that causes severe acute illness in humans. We present a human plague case who became infected by the bite of a wild Gunnison's prairie dog, and a good practical example of the One Health approach that resulted in a rapid public health response. The exposure occurred while the animal was being transported for relocation to a wildlife refuge after being trapped in a plague enzootic area. This is the first report of a human plague case resulting from the bite of a Gunnison's prairie dog. Additionally, we present an observation of a longer incubation period for plague in captive prairie dogs, leading to a recommendation for a longer quarantine period for prairie dogs during translocation efforts.

Oxidative stress response genes in Mycobacterium tuberculosis: role of ahpC in resistance to peroxynitrite and stage-specific survival in macrophages.

The Mycobacterium tuberculosis ahpC gene, encoding the mycobacterial orthologue of alkylhydroperoxide reductase, undergoes an unusual regulatory cycle. The levels of AhpC alternate between stages of expression silencing in virulent strains grown as aerated cultures, secondary to a natural loss of the regulatory oxyR function in all strains of the tubercle bacillus, and expression activation in static bacilli by a yet undefined mechanism. The reasons for this unorthodox regulatory cycle controlling expression of an antioxidant factor are currently not known. In this work, M. tuberculosis H37Rv and Mycobacterium smegmatis mc(2)155 ahpC knockout mutants were tested for sensitivity to reactive nitrogen intermediates, in particular peroxynitrite, a highly reactive combinatorial product of reactive nitrogen and oxygen species, and sensitivity to bactericidal mechanisms in resting and activated macrophages. Both M. tuberculosis ahpC::Km(r) and M. smegmatis ahpC::Km(r) showed increased susceptibility to peroxynitrite. In contrast, inactivation of ahpC in M. tuberculosis did not cause increased sensitivity to donors of NO alone. M. tuberculosis ahpC::Km(r) also showed decreased survival in unstimulated macrophages, but the effect was no longer detectable upon IFNgamma activation. These studies establish a specific role for ahpC in antioxidant defences involving peroxynitrite and most likely additional cidal mechanisms in macrophages, with the regulatory cycle likely contributing to survival upon coming out of the stationary phase during dormancy (latent infection) or upon transmission to a new host.

A genetic and functional analysis of the unusually large variable region in the M.AluI DNA-(cytosine C5)-methyltransferase.

The M.AluI DNA-(cytosine C5)-methyltransferase (5mC methylase) acts on the sequence 5'-AGCT-3'. The amino acid sequences of known 5mC methylases contain ten conserved motifs, with a variable region between Motifs VIII and IX that contains one or more "target-recognizing domains" (TRDs) responsible for DNA sequence specificity. Monospecific 5mC methylases are believed to have only one TRD, while multispecific 5mC methylases have as many as five. M.AluI has the second-largest variable region of all known 5mC methylases, and sequence analysis reveals five candidate TRDs. In testing whether M.AluI is in fact monospecific it was found that AGCT methylation represents only 80-90% of the methylating activity of this enzyme, while control experiments with the enzyme M.HhaI gave no unexplained activity. Because individual TRDs can be deleted from multispecific methylases without general loss of activity, a series of insertion and deletion mutants of the M.AluI variable region were prepared. All deletions that removed more than single amino acids from the variable region caused significant loss of activity; a sensitive in vivo assay for methylase activity based on McrBC restriction suggested that the central portion of the variable region is particularly important. In some cases, multispecific methylases can accommodate a TRD from another multispecific methylase, thereby acquiring an additional specificity. When TRDs were moved from a multispecific methylase into two different locations in the variable region of M.AluI, all hybrid enzymes had greatly reduced activity and no new specificities. M.AluI thus behaves in most respects as a monospecific methylase despite the remarkable size of its variable region.