The Hydroxamate Siderophore Rhequichelin Is Required for Virulence of the Pathogenic Actinomycete Rhodococcus equi

We previously showed that the facultative intracellular pathogen Rhodococcus equi produces a nondiffusible and catecholate-containing siderophore (rhequibactin) involved in iron acquisition during saprophytic growth. Here, we provide evidence that the rhbABCDE cluster directs the biosynthesis of a hydroxamate siderophore, rhequichelin, that plays a key role in virulence. The rhbC gene encodes a nonribosomal peptide synthetase that is predicted to produce a tetrapeptide consisting of N(5)-formyl-N(5)-hydroxyornithine, serine, N(5)-hydroxyornithine, and N(5)-acyl-N(5)-hydroxyornithine. The other rhb genes encode putative tailoring enzymes mediating modification of ornithine residues incorporated into the hydroxamate product of RhbC. Transcription of rhbC was upregulated during growth in iron-depleted medium, suggesting that it plays a role in iron acquisition. This was confirmed by deletion of rhbCD, rendering the resulting strain R. equi SID2 unable to grow in the presence of the iron chelator 2,2-dipyridyl. Supernatant of the wild-type strain rescued the phenotype of R. equi SID2. The importance of rhequichelin in virulence was highlighted by the rapid increase in transcription levels of rhbC following infection and the inability of R. equi SID2 to grow within macrophages. Unlike the wild-type strain, R. equi SID2 was unable to replicate in vivo and was rapidly cleared from the lungs of infected mice. Rhequichelin is thus a key virulence-associated factor, although nonpathogenic Rhodococcus species also appear to produce rhequichelin or a structurally closely related compound. Rhequichelin biosynthesis may therefore be considered an example of cooption of a core actinobacterial trait in the evolution of R. equi virulence

Erratum to: ‘Integrated analysis of the local and systemic changes preceding the development of post-partum cytological endometritis’

ErratumErratum to: ‘Integrated analysis of the local and systemic changes preceding the development of post-partum cytological endometritis’ -http://hdl.handle.net/11019/90

A real-time impedance based method to assess Rhodococcus equi virulence.

Rhodococcus equi is a facultative intracellular pathogen of macrophages and the causative agent of foal pneumonia. R. equi virulence is usually assessed by analyzing intracellular growth in macrophages by enumeration of bacteria following cell lysis, which is time consuming and does not allow for a high throughput analysis. This paper describes the use of an impedance based real-time method to characterize proliferation of R. equi in macrophages, using virulent and attenuated strains lacking the vapA gene or virulence plasmid. Image analysis suggested that the time-dependent cell response profile (TCRP) is governed by cell size and roundness as well as cytoxicity of infecting R. equi strains. The amplitude and inflection point of the resulting TCRP were dependent on the multiplicity of infection as well as virulence of the infecting strain, thus distinguishing between virulent and attenuated strains

The morphology of macrophages changes following infection with <i>R. equi</i>.

<p>J774A.1 monolayers were infected with ATTO 488 labelled virulent <i>R. equi</i> 103+ (green). Monolayers were fixed 24 h post-infection; the actin cytoskeleton and cell nuclei were stained with Texas Red Phalloidin (red) and Hoechst 33258 (blue), respectively. Panel A: non-infected monolayers, panel B: monolayers infected with <i>R. equi</i> 103+. Arrows indicate the change in cell shape following infection with <i>R. equi</i>. The length of the white bar is 40 µm.</p

Bacterial strains, plasmids and oligonucleotides used in this study.

<p>Bacterial strains, plasmids and oligonucleotides used in this study.</p

Infection of macrophages with <i>R. equi</i> affects host cell size and morphology.

<p>Macrophage monolayers were infected with ATTO 488 labeled virulent <i>R. equi</i> 103+ or attenuated <i>R. equi</i> 103− strains at increasing multiplicities (MOI) of infection. Monolayers were fixed and labelled 24 h post-infection. The cell size (panel A) and cell roundness (panel B) of infected cells were compared to control cells (not infected, indicated as MOI = 0). Green bars: no intracellular bacteria; blue bars: 1 to 5 intracellular bacteria; red bars: more than 5 intracellular bacteria. +: <i>R. equi</i> 103+; −: <i>R. equi</i> 103−. Error bars denote the standard deviation of the mean.</p

Intracellular growth of virulent and attenuated <i>R. equi</i>.

<p>J774A.1 monolayers were infected with virulent (♦, <i>R. equi</i> 103+; ∇, <i>R. equi</i> Δ35000) and attenuated (□, <i>R. equi</i> 103−; •, <i>R. equi</i> Δ<i>vapA</i>) <i>R. equi</i> strains. Following a 1 hour incubation to allow phagocytosis, monolayers were washed and treated with vancomycin to kill remaining extra cellular bacteria. Intracellular bacteria were enumerated via real time qPCR of the <i>R. equi</i> 16S rRNA gene. Results are expressed as fold change in bacterial numbers relative to t = 0 (h) values. Error bars denote the standard deviation of the mean.</p

Key TCRP parameters of macrophage monolayers infected with virulent or attenuated <i>R. equi</i> strains.

<p>Shown are the maximum cell indices (Ci) values (panel A) and the the C_i inflection times (panel B) following infection of J774A.1 macrophage monolayers with virulent (♦, <i>R. equi</i> 103+; ∇, <i>R. equi</i> Δ35000) and attenuated (□, <i>R. equi</i> 103−; •, <i>R. equi</i> Δ<i>vapA</i>) <i>R. equi</i> strains at increasing multiplicity of infection. Values are the means ± SD.</p