Identification of Type 4B Secretion System Substrates That Are Conserved among Coxiella burnetii Genomes and Promote Intracellular Growth.

Coxiella burnetii is a Gram-negative pathogen that infects a variety of mammalian hosts. Infection of domesticated ewes can cause fetal abortion, whereas acute human infection normally manifests as the flu-like illness Q fever. Successful host infection requires replication of the pathogen within the lysosomal Coxiella-containing vacuole (CCV). The bacterium encodes a type 4B secretion system (T4BSS) that delivers effector proteins into the host cell. Disruption of C. burnetii T4BSS effector export abrogates CCV biogenesis and bacterial replication. Over 150 C. burnetii T4BSS substrates have been designated often based on heterologous protein translocation by the Legionella pneumophila T4BSS. Cross-genome comparisons predict that many of these T4BSS substrates are truncated or absent in the acute-disease reference strain C. burnetii Nine Mile. This study investigated the function of 32 proteins conserved among diverse C. burnetii genomes that are reported to be T4BSS substrates. Despite being previously designated T4BSS substrates, many of the proteins were not translocated by C. burnetii when expressed fused to the CyaA or BlaM reporter tags. CRISPR interference (CRISPRi) indicated that of the validated C. burnetii T4BSS substrates, CBU0122, CBU1752, CBU1825, and CBU2007 promote C. burnetii replication in THP-1 cells and CCV biogenesis in Vero cells. When expressed in HeLa cells tagged at its C or N terminus with mCherry, CBU0122 localized to the CCV membrane and the mitochondria, respectively. Collectively, these data further define the repertoire of bona fide C. burnetii T4BSS substrates. IMPORTANCE Coxiella burnetii secretes effector proteins via a T4BSS that are required for successful infection. Over 150 C. burnetii proteins are reported to be T4BSS substrates and often by default considered putative effectors, but few have assigned functions. Many C. burnetii proteins were designated T4BSS substrates using heterologous secretion assays in L. pneumophila and/or have coding sequences that are absent or pseudogenized in clinically relevant C. burnetii strains. This study examined 32 previously reported T4BSS substrates that are conserved among C. burnetii genomes. Of the proteins tested that were previously designated T4BSS substrates using L. pneumophila, most were not exported by C. burnetii. Several T4BSS substrates that were validated in C. burnetii also promoted pathogen intracellular replication and one trafficked to late endosomes and the mitochondria in a manner suggestive of effector activity. This study identified several bona fide C. burnetii T4BSS substrates and further refined the methodological criteria for their designation.

The Accessory Gene saeP of the SaeR/S Two-Component Gene Regulatory System Impacts Staphylococcus aureus Virulence During Neutrophil Interaction.

Staphylococcus aureus (S. aureus) causes a range of diseases ranging from superficial skin and soft-tissue infections to invasive and life-threatening conditions (Klevens et al., 2007; Kobayashi et al., 2015). S. aureus utilizes the Sae sensory system to adapt to neutrophil challenge. Although the roles of the SaeR response regulator and its cognate sensor kinase SaeS have been demonstrated to be critical for surviving neutrophil interaction and for causing infection, the roles for the accessory proteins SaeP and SaeQ remain incompletely defined. To characterize the functional role of these proteins during innate immune interaction, we generated isogenic deletion mutants lacking these accessory genes in USA300 (USA300ΔsaeP and USA300ΔsaeQ). S. aureus survival was increased following phagocytosis of USA300ΔsaeP compared to USA300 by neutrophils. Additionally, secreted extracellular proteins produced by USA300ΔsaeP cells caused significantly more plasma membrane damage to human neutrophils than extracellular proteins produced by USA300 cells. Deletion of saeQ resulted in a similar phenotype, but effects did not reach significance during neutrophil interaction. The enhanced cytotoxicity of USA300ΔsaeP cells toward human neutrophils correlated with an increased expression of bi-component leukocidins known to target these immune cells. A saeP and saeQ double mutant (USA300ΔsaePQ) showed a significant increase in survival following neutrophil phagocytosis that was comparable to the USA300ΔsaeP single mutant and increased the virulence of USA300 during murine bacteremia. These data provide evidence that SaeP modulates the Sae-mediated response of S. aureus against human neutrophils and suggest that saeP and saeQ together impact pathogenesis in vivo.