Léna Tasse scite author profile

The human gut microbiome is a complex ecosystem composed mainly of uncultured bacteria. It plays an essential role in the catabolism of dietary fibers, the part of plant material in our diet that is not metabolized in the upper digestive tract, because the human genome does not encode adequate carbohydrate active enzymes (CAZymes). We describe a multi-step functionally based approach to guide the in-depth pyrosequencing of specific regions of the human gut metagenome encoding the CAZymes involved in dietary fiber breakdown. High-throughput functional screens were first applied to a library covering 5.4 3 10 9 bp of metagenomic DNA, allowing the isolation of 310 clones showing beta-glucanase, hemicellulase, galactanase, amylase, or pectinase activities. Based on the results of refined secondary screens, sequencing efforts were reduced to 0.84 Mb of nonredundant metagenomic DNA, corresponding to 26 clones that were particularly efficient for the degradation of raw plant polysaccharides. Seventy-three CAZymes from 35 different families were discovered. This corresponds to a fivefold target-gene enrichment compared to random sequencing of the human gut metagenome. Thirty-three of these CAZy encoding genes are highly homologous to prevalent genes found in the gut microbiome of at least 20 individuals for whose metagenomic data are available. Moreover, 18 multigenic clusters encoding complementary enzyme activities for plant cell wall degradation were also identified. Gene taxonomic assignment is consistent with horizontal gene transfer events in dominant gut species and provides new insights into the human gut functional trophic chain.

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Dual role of the MgtC virulence factor in host and non‐host environments

Rang

Alix

Félix

et al. 2006

Molecular Microbiology

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SummaryMgtC is required for intramacrophage replication of intracellular pathogens and growth in low Mg 2+ medium. A link between these two phenotypes has been proposed due to putative Mg 2+ deprivation inside phagosome. MgtC is part of a family of proteins that share a conserved N-terminal transmembrane domain and a variable C-terminal domain. A combination of predictive and experimental approaches indicates that the Salmonella MgtC C-terminal domain is cytoplasmic, adopts a fold also found in metal transporters and RNA interacting domain, and does not bind Mg 2+ . MgtC homologues from diverse g-proteobacteria, including the extracellular pathogens Yersinia pestis, Photorhabdus luminescens and Pseudomonas aeruginosa, have been expressed in a Salmonella DmgtC strain. The Y. pestis MgtC fully replaced the Salmonella MgtC whereas P. luminescens or P. aeruginosa MgtC complemented only in low Mg 2+ medium, thus dissociating for the first time the two MgtC-related phenotypes. In addition, we identified single amino acids changes that prevent or promote MgtC role in macrophages without affecting MgtC role in low Mg 2+ culture. A Salmonella DmgtC strain showed elongated and autoaggregated bacteria in low Mg 2+ medium but not in macrophages. Taken together our results suggest that MgtC has a dual role when bacteria localize in macrophages or low Mg 2+ environment.

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Experimental evolution of nodule intracellular infection in legume symbionts

Guan

Gris

Cruveiller

et al. 2013

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Soil bacteria known as rhizobia are able to establish an endosymbiosis with legumes that takes place in neoformed nodules in which intracellularly hosted bacteria fix nitrogen. Intracellular accommodation that facilitates nutrient exchange between the two partners and protects bacteria from plant defense reactions has been a major evolutionary step towards mutualism. Yet the forces that drove the selection of the late event of intracellular infection during rhizobium evolution are unknown. To address this question, we took advantage of the previous conversion of the plant pathogen Ralstonia solanacearum into a legume-nodulating bacterium that infected nodules only extracellularly. We experimentally evolved this draft rhizobium into intracellular endosymbionts using serial cycles of legume-bacterium cocultures. The three derived lineages rapidly gained intracellular infection capacity, revealing that the legume is a highly selective environment for the evolution of this trait. From genome resequencing, we identified in each lineage a mutation responsible for the extracellular-intracellular transition. All three mutations target virulence regulators, strongly suggesting that several virulence-associated functions interfere with intracellular infection. We provide evidence that the adaptive mutations were selected for their positive effect on nodulation. Moreover, we showed that inactivation of the type three secretion system of R. solanacearum that initially allowed the ancestral draft rhizobium to nodulate, was also required to permit intracellular infection, suggesting a similar checkpoint for bacterial invasion at the early nodulation/root infection and late nodule cell entry levels. We discuss our findings with respect to the spread and maintenance of intracellular infection in rhizobial lineages during evolutionary times.

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Transient Hypermutagenesis Accelerates the Evolution of Legume Endosymbionts following Horizontal Gene Transfer

et al. 2014

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Léna Tasse

Functional metagenomics to mine the human gut microbiome for dietary fiber catabolic enzymes

Dual role of the MgtC virulence factor in host and non‐host environments

Experimental evolution of nodule intracellular infection in legume symbionts

Transient Hypermutagenesis Accelerates the Evolution of Legume Endosymbionts following Horizontal Gene Transfer

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