Project description:Coxiella burnetii undergoes a biphasic developmental cycle within its host cell that generates morphologically and physiologically distinct large cell variants (LCV) and small cell variants (SCV). During the lag phase of the C. burnetii growth cycle, non-replicating SCV differentiate into replicating LCV that in turn differentiate back into SCV during stationary phase. Nearly homogeneous SCV are observed in infected Vero cells after extended incubation (21 to 28 days). In the current study, we sought to establish whether C. burnetii developmental transitions in host cells are recapitulated during host cell-free (axenic) growth in first and second generation acidified citrate cysteine media (ACCM-1 and ACCM-2, respectively). We show that ACCM-2 supported developmental transitions and viability. Although ACCM-1 also supported SCV to LCV transition, LCV to SCV transition did not occur after extended incubation (21 days). Instead, C. burnetii exhibited a ghost-like appearance with bacteria containing condensed chromatin but otherwise devoid of cytoplasmic content. This phenotype correlated with a near total loss in viability between 14 and 21 days of cultivation. Transcriptional profiling of C. burnetii following 14 days of incubation revealed elevated expression of oxidative stress genes in ACCM-1 cultivated bacteria. ACCM-2 differs from ACCM-1 by the substitution of methyl-b-cyclodextrin (Mb-CD) for fetal bovine serum. Addition of Mb-CD to ACCM-1 at 7 days post-inoculation rescued C. burnetii viability and lowered expression of oxidative stress genes. Thus, Mb-CD appears to alleviate oxidative stress in ACCM-2 to result in C. burnetii developmental transitions and viability that mimic host cell-cultivated organisms. Axenic cultivation of C. burnetii in ACCM-2 and new methods Coxiella axenic media 1 vs 2

Project description:Coxiella burnetii, the etiological agent of Q fever, undergoes a unique biphasic developmental cycle where bacteria transition from replicating (exponential phase) large cell variant (LCV) forms to a non-replicating, (stationary phase) small cell variant (SCV) forms. The alternative sigma factor RpoS is an essential regulator of stress responses and stationary phase growth in several bacterial species, including Legionella pneumophila, which has a developmental cycle superficially similar to C. burnetii. To characterize RpoS function during C. burnetii growth and developmental, we constructed a C. burnetii ∆rpoS mutant to define the effects on intracellular and axenic growth, as well as, gene regulation during SCV development. C. burnetii ∆rpoS exhibited intracellular growth defects in J774 mouse macrophage-like cells, but not in Vero epithelial cells. RNA sequencing of C. burnetii ∆rpoS revealed that a substantial portion of the C. burnetii genome is regulated by RpoS during SCV development. Genes previously shown to have increased expression during SCV generation, including the expression of the SCV-specific protein ScvA and pathways involved in oxidative stress, arginine transport, and peptidoglycan remodeling pathways, were dysregulated in the rpoS mutant. These genes were enriched for a predicted RpoS-binding site. These data were corroborated with independent assays demonstrating that the C. burnetii rpoS mutant had increased sensitivity to hydrogen peroxide and carbenicillin. Collectively, these results demonstrate that RpoS is essential for the regulation of genes involved in SCV development and growth inside macrophage-like cells.

Project description:The inability to propagate obligate intracellular pathogens under axenic (host cell-free) culture conditions imposes severe experimental constraints that have negatively impacted progress in understanding pathogen virulence and disease mechanisms. Coxiella burnetii, the causative agent of human Q (Query) fever, is an obligate intracellular bacterial pathogen that replicates exclusively in an acidified, lysosome-like vacuole. To define conditions that support C. burnetii growth, we systematically evaluated the organismâ??s metabolic requirements using expression microarrays, genomic reconstruction, and metabolite typing. This led to development of a complex nutrient medium that supported substantial growth (~ 3 log10) of C. burnetii in a 2.5% oxygen environment. Importantly, axenically grown C. burnetii were highly infectious for Vero cells and exhibited developmental forms characteristic of in vivo grown organisms. Axenic cultivation of C. burnetii will facilitate studies of the organismâ??s pathogenesis and genetics, and aid development of Q fever preventatives such as an effective subunit vaccine. Furthermore, the systematic approach used here may be broadly applicable to development of axenic media that support growth of other medically important obligate intracellular pathogens. Host cell-free growth, Vero cell growth and carryover baseline of Coxiella burnetii

Project description:The inability to propagate obligate intracellular pathogens under axenic (host cell-free) culture conditions imposes severe experimental constraints that have negatively impacted progress in understanding pathogen virulence and disease mechanisms. Coxiella burnetii, the causative agent of human Q (Query) fever, is an obligate intracellular bacterial pathogen that replicates exclusively in an acidified, lysosome-like vacuole. To define conditions that support C. burnetii growth, we systematically evaluated the organism’s metabolic requirements using expression microarrays, genomic reconstruction, and metabolite typing. This led to development of a complex nutrient medium that supported substantial growth (~ 3 log10) of C. burnetii in a 2.5% oxygen environment. Importantly, axenically grown C. burnetii were highly infectious for Vero cells and exhibited developmental forms characteristic of in vivo grown organisms. Axenic cultivation of C. burnetii will facilitate studies of the organism’s pathogenesis and genetics, and aid development of Q fever preventatives such as an effective subunit vaccine. Furthermore, the systematic approach used here may be broadly applicable to development of axenic media that support growth of other medically important obligate intracellular pathogens.

Project description:A hallmark of Coxiella burnetii, the bacterial cause of human Q fever, is a biphasic developmental cycle that generates biologically, ultrastructurally, and compositionally distinct large cell variant (LCV) and small cell variant (SCV) forms. LCVs are replicating, exponential phase forms while SCVs are non-replicating, stationary phase forms. The SCV has several properties, such as a condensed nucleoid and an unusual cell envelope, suspected of conferring enhanced environmental stability. To identify genetic determinants of the LCV to SCV transition, we profiled the C. burnetii transcriptome by microarray at 3 (early LCV), 5 (late LCV), 7 (intermediate forms), 14 (early SCV) and 21 days (late SCV) post-infection (PI) of Vero epithelial cells. Relative to early LCV, genes down-regulated in the SCV were primarily involved with intermediary metabolism. Up-regulated SCV genes included those involved in oxidative stress responses, arginine acquisition, and cell wall remodeling. A striking transcriptional signature of the SCV was induction (>7-fold) of five genes encoding predicted L,D transpeptidases that catalyze nonclassical 3-3 peptide cross-links in peptidoglycan (PG), a modification that can influence several biological traits in bacteria. Accordingly, of cross-links identified, muropeptide analysis showed PG of SCV with 46% 3-3 cross-links as opposed to 16% 3-3 cross-links for LCV. Moreover, cryo-electron microscopy revealed SCV with an unusually dense periplasmic layer that was intimately associated with the outer membrane. In contrast, LCV had a clearly distinguishable periplasm and inner/outer membranes. Collectively, these results indicate the SCV produces a unique transcriptome with a major component directed towards remodeling a PG layer that likely contributes to Coxiella's environmental resistance.

Project description:A hallmark of Coxiella burnetii, the bacterial cause of human Q fever, is a biphasic developmental cycle that generates biologically, ultrastructurally, and compositionally distinct large cell variant (LCV) and small cell variant (SCV) forms. LCVs are replicating, exponential phase forms while SCVs are non-replicating, stationary phase forms. The SCV has several properties, such as a condensed nucleoid and an unusual cell envelope, suspected of conferring enhanced environmental stability. To identify genetic determinants of the LCV to SCV transition, we profiled the C. burnetii transcriptome by microarray at 3 (early LCV), 5 (late LCV), 7 (intermediate forms), 14 (early SCV) and 21 days (late SCV) post-infection (PI) of Vero epithelial cells. Relative to early LCV, genes down-regulated in the SCV were primarily involved with intermediary metabolism. Up-regulated SCV genes included those involved in oxidative stress responses, arginine acquisition, and cell wall remodeling. A striking transcriptional signature of the SCV was induction (>7-fold) of five genes encoding predicted L,D transpeptidases that catalyze nonclassical 3-3 peptide cross-links in peptidoglycan (PG), a modification that can influence several biological traits in bacteria. Accordingly, of cross-links identified, muropeptide analysis showed PG of SCV with 46% 3-3 cross-links as opposed to 16% 3-3 cross-links for LCV. Moreover, cryo-electron microscopy revealed SCV with an unusually dense periplasmic layer that was intimately associated with the outer membrane. In contrast, LCV had a clearly distinguishable periplasm and inner/outer membranes. Collectively, these results indicate the SCV produces a unique transcriptome with a major component directed towards remodeling a PG layer that likely contributes to Coxiella's environmental resistance. Coxiella Vero time series. Coxiella was profiled at day 3, day 5, day 7, day 14 and day 21 post-infection of Vero epithelial cells.

Project description:Developmental transitions of Coxiella burnetii grown in axenic media

Project description:Coxiella burnetii, a category B select agent, is endemic worldwide, except New Zealand. It causes annually several outbreaks of the zoonotic disease Q fever predominantly in small ruminants. To date, the lipopolysaccharide (LPS), besides a type IV secretion system (T4SS), is the only defined and characterized virulence determinant of C. burnetii. This surface molecule is used to distinguish between virulent (Ph I) and low-virulent (Ph II) organisms, the latter emerge only after frequent passaging in the laboratory. As an obligate intracellular pathogen, targeted genetic modification is still not a routine and labour intensive procedure. The deeper study of novel determinants is complicated and demands not only advanced techniques for axenic and for cell culture-based cultivation but also novel approaches in the high-resolution mass spectrometry. This work is the first proteomic study comparing. C. burnetii Ph I and Ph II propagated in different axenic media and in cell culture.

Project description:Salmonella Typhimurium (S. Typhimurium) is an enteric bacterium capable of invading a wide range of host cell types and adopting different intracellular lifestyles for survival. Host endocytic trafficking and autophagy have been implied to regulate the S. Typhimurium subcellular localization and survival. To reveal alternative host regulators on S. Typhimurium lifestyle, we combined a novel fluorescent reporter, Salmonella Intracellular Analyzer (SINA) with haploid forward genetic screening. This identified transcription factor c-MYC as a negative regulator of S. Typhimurium cytosolic lifestyle via stabilizing the Salmonella-containing vacuole (SCV). We further confirmed that c-MYC downstream regulated LC3 acts to maintain SCV stability and limits S. Typhimurium cytosolic lifestyle. We demonstrated that LC3 is recruited to the SCV prior to the endomembrane damage marker Galectin 3, and it regulates SCV stability independent of the autophagosome adaptor NDP52. The LC3 processing enzymes ATG3 and ATG4 reciprocally act on SCV stability, where the loss of LC3-PE conjugation in the absence of ATG3 limits SCV damages. We further identified the dosage-dependent function of the S. Typhimurium effector SopF in mediating SCV stability by actively avoiding LC3 recruitment to the proximity of the SCV to reduce its catastrophic rupture and host cell death. Altogether, we offer insights on the significance of cellular transcription profile in the determination of S. Typhimurium pathophysiology as well as the underlying host-evasion strategy of S. Typhimurium.

Project description:Background: Q fever is caused by the Coxiella burnetii, an intracellular bacterium that infects mononuclear cells. In some individuals, it causes a persistent cardiovascular infection (chronic Q fever). The aim of present study was to investigate the C. burnetii-induced IFN-γ response in chronic Q fever patients. Methods: IFN-γ was measured in supernatants of C. burnetii-stimulated peripheral blood mononuclear cells (PBMCs) of patients. Gene-expression profiles of the IFN-γ pathway in PBMCs after incubation with C. burnetii were compared between chronic Q fever patients and control individuals. Results: IFN-γ production by PBMCs of chronic Q fever patients incubated with C. burnetii in vitro, was significantly higher compared to controls. In transcriptome analysis, genes downstream of IFN-γ were strongly upregulated in patients. Conclusion: Present study showed that IFN-γ production and the response to IFN-γ seems to be intact in chronic Q fever patients.