Project description:In this study, we measured growth rate of Netzelia tuberspinifera(basionym Difflugia tuberspinifera) under different temperatures and revealed the molecular mechanisms of temperature adaptation based on the transcriptomics along a temperature gradient (15, 25 and 35 °C). This study can provide a reference for in-depth study on testate amoebae in future researches.

Project description:Phylogenomic reconstruction of Helotiales

Project description:Phylogenomic reconstruction of Microtus arvalis

Project description:Multi-locus sequencing for phylogenomic reconstruction of spiders

Project description:Conservation and phylogenomic reconstruction of the Neotropical poison frogs (Dendrobatidae)

Project description:Testate amoebae (Arcellinida, Amoebozoa) community diversity in New England bogs and fens assessed through lineage-specific amplicon sequencing

Project description:Transcriptional profiling of D. discoideum revealed sets of genes whose expression is enriched in amoebae interacting with different species of bacteria, including sets that appear specific to amoebae interacting with Gram(+), or with Gram(-) bacteria. In a genetic screen utilizing the growth of mutant amoebae on a variety of bacteria as a phenotypic readout, we identified amoebal genes that are only required for growth on Gram(+) bacteria, including one that encodes the cell surface protein gp130, as well as several genes that are only required for growth on Gram(-) bacteria including one that encodes a putative lysozyme, AlyL. These genes are required for parts of the transcriptional response of wild-type amoebae, and this allowed their classification into potential response pathways.

Project description:We report the transcriptome of M. abscessus in amoebae and macrophages. M. abscessus intra-amoebal and intra-macrophagic transcriptomes demonstrate of the potential of M. abscessus to adapt to an intracellular lifestyle, though amoebae largely contribute to the enhancement of M. abscessus survival macrophages.

Project description:To further development of our gene expression approch to intracellular pathogenic bacterial controlling, we have employed castamized Neochlamydia S13 genomic microarray as a discovery platform to identy genes with the potential to inhibit Legionella growth into hoat amoebae , based on our data that the the amoebae haboring amoebal endosymbiont Neochlamydia S13 (an environmental chlamydia) could evade Legionella infection.

Project description:Legionella pneumophila are important opportunistic pathogens for which environmental reservoirs such as protists are crucial for the infection of humans. Free-living amoebae are considered key hosts providing nutrients and shelter for highly efficient intracellular proliferation of L. pneumophila, which eventually leads to lysis of the amoeba host cell. Yet, the significance of other bacterial players for L. pneumophila ecology is poorly understood. In this study we used a ubiquitous amoeba and their bacterial endosymbiont to investigate the impact of this common association on L. pneumophila infection. We demonstrate that Acanthamoeba castellanii harboring the chlamydial symbiont Protochlamydia amoebophila were able to erase L. pneumophila and, in contrast to symbiont-free amoebae, survived the infection and were able to resume growth. Environmental amoeba isolates harboring P. amoebophila were equally well-protected, and fresh environmental isolates of L. pneumophila were equally well-erased, suggesting ecological relevance of this symbiont-mediated protection. We further show that protection was not mediated by impaired L. pneumophila uptake. Instead, we observed reduced virulence of L. pneumophila released from symbiont-containing amoebae that is strongly supported by transcriptome data. Interference with transition to the transmissive phase is thus likely the basis for this protection. Finally, our data indicate that the defensive response of amoebae harboring P. amoebophila leaves the amoebae with superior fitness reminiscent of immunological memory. Given that mutualistic associations between bacteria and amoebae are widely distributed, P. amoebophila and potentially other amoeba endosymbionts could be key elements in shaping environmental survival, abundance and virulence of this important pathogen thereby affecting frequency of human infection.