Project description:Bacteriophages against Dickeya spp.

Project description:Bacteriophages against clinical pathogens

Project description:Impairment of the intestinal barrier allows the systemic translocation of commensal bacteria, inducing a pro-inflammatory state in the host. To explore this link, we investigated innate immune responses following increased gut permeability upon administration of dextran sulfate sodium (DSS) in mice. We found that microbiota translocation induced trained immunity (TI) in mouse myeloid bone marrow progenitors (BMPs). Enterococcus faecalis was isolated from bone marrow following DSS treatment and induced trained immunity hallmarks in bone marrow-derived mouse macrophages and human monocytes. Notably, DSS treatment or heat-killed E. faecalis reprogrammed BMPs, resulting in enhanced inflammatory responses in vitro and in vivo, and protection against pathogen infections. The C-type lectin receptor Mincle (Clec4e) was essential for E. faecalis-induced TI in BMPs. Clec4e-/- mice showed impaired TI upon E. faecalis and reduced pathology following DSS treatment. Thus, Mincle sensing of E. faecalis induces TI that may contribute to pathologies associated with increased gut permeability. This SuperSeries is composed of the SubSeries listed below.

Project description:The DNA content of bacteriophages from Bartonella grahamii was investigated by hybridization against cellular DNA from the same organism. Phage particles were isolated from plate grown bacteria as well as from different growth phases during culture in liquid medium.

Project description:Genome of bacteriophages against Dickeya chrysanthemi

Project description:Genome of bacteriophages against Salmonella enterica

Project description:Bacteriophage against Enterecoccus faecalis

Project description:HT-SELEX against E. faecalis

Project description:Investigation of lytic bacteriophages against pathogenic Escherichia coli

Project description:Intrinsic and acquired defenses against bacteriophages, including Restriction/Modification, CRISPR/Cas, and Toxin/Anti-toxin systems have been intensely studied, with profound scientific impacts. However, adaptive defenses against phage infection analogous to adaptive resistance to antimicrobials have yet to be described. To identify such mechanisms, we applied an RNAseq-based, comparative transcriptomics approach in different \textit{Pseudomonas aeruginosa} strains after independent infection by a set of divergent virulent bacteriophages. A common host-mediated adaptive stress response to phages was identified that includes the Pseudomonas Quinolone Signal, through which infected cells inform their neighbors of infection, and what may be a resistance mechanism that functions by reducing infection vigor. With host transcriptional machinery left intact, we also observe phage-mediated differential expression caused by phage-specific stresses and molecular mechanisms. These responses suggest the presence of a conserved Bacterial Adaptive Phage Response mechanism as a novel type of host defense mechanism, and which may explain transient forms of phage persistence.