Identifying glycan consumers in human gut microbiota samples using metabolic labeling coupled with fluorescence-activated cell sorting.

The composition and metabolism of the human gut microbiota are strongly influenced by dietary complex glycans, which cause downstream effects on the physiology and health of hosts. Despite recent advances in our understanding of glycan metabolism by human gut bacteria, we still need methods to link glycans to their consuming bacteria. Here, we use a functional assay to identify and isolate gut bacteria from healthy human volunteers that take up different glycans. The method combines metabolic labeling using fluorescent oligosaccharides with fluorescence-activated cell sorting (FACS), followed by amplicon sequencing or culturomics. Our results demonstrate metabolic labeling in various taxa, such as Prevotella copri, Collinsella aerofaciens and Blautia wexlerae. In vitro validation confirms the ability of most, but not all, labeled species to consume the glycan of interest for growth. In parallel, we show that glycan consumers spanning three major phyla can be isolated from cultures of sorted labeled cells. By linking bacteria to the glycans they consume, this approach increases our basic understanding of glycan metabolism by gut bacteria. Going forward, it could be used to provide insight into the mechanism of prebiotic approaches, where glycans are used to manipulate the gut microbiota composition.

The current drug discovery landscape for trypanosomiasis and leishmaniasis: Challenges and strategies to identify drug targets.

Human trypanosomiasis and leishmaniasis are vector-borne neglected tropical diseases caused by infection with the protozoan parasites Trypanosoma spp. and Leishmania spp., respectively. Once restricted to endemic areas, these diseases are now distributed worldwide due to human migration, climate change, and anthropogenic disturbance, causing significant health and economic burden globally. The current chemotherapy used to treat these diseases has limited efficacy, and drug resistance is spreading. Hence, new drugs are urgently needed. Phenotypic compound screenings have prevailed as the leading method to discover new drug candidates against these diseases. However, the publication of the complete genome sequences of multiple strains, advances in the application of CRISPR/Cas9 technology, and in vivo bioluminescence-based imaging have set the stage for advancing target-based drug discovery. This review analyses the limitations of the narrow pool of available drugs presently used for treating these diseases. It describes the current drug-based clinical trials highlighting the most promising leads. Furthermore, the review presents a focused discussion on the most important biological and pharmacological challenges that target-based drug discovery programs must overcome to advance drug candidates. Finally, it examines the advantages and limitations of modern research tools designed to identify and validate essential genes as drug targets, including genomic editing applications and in vivo imaging.

Drugging the gut microbiota: toward rational modulation of bacterial composition in the gut.

The human gastrointestinal tract hosts almost a trillion microorganisms, organized in a complex community known as the gut microbiota, an integral part of human physiology and metabolism. Indeed, disease-specific alterations in the gut microbiota have been observed in several chronic disorders, including obesity and inflammatory bowel diseases. Correcting these alterations could revert the development of such pathologies or alleviate their symptoms. Recently, the gut microbiota has been the target of drug discovery that goes beyond classic probiotic approaches. This short review examines the promises and limitations of the latest strategies designed to modulate the gut bacterial community, and it explores the druggability of the gut microbiota by focusing on the potential of small molecules and prebiotics.

Small-Molecule Allosteric Triggers of Clostridium difficile Toxin B Auto-proteolysis as a Therapeutic Strategy.

Clostridium difficile causes increasing numbers of life-threatening intestinal infections. Symptoms associated with C. difficile infection (CDI) are mediated by secreted protein toxins, whose virulence is modulated by intracellular auto-proteolysis following allosteric activation of their protease domains by inositol hexakisphosphate (IP6). Here, we explore the possibility of inactivating the C. difficile toxin B (TcdB) by triggering its auto-proteolysis in the gut lumen prior to cell uptake using gain-of-function small molecules. We anticipated that high calcium concentrations typically found in the gut would strongly chelate IP6, precluding it from pre-emptively inducing toxin auto-proteolysis if administered exogenously. We therefore designed IP6 analogs with reduced susceptibility to complexation by calcium, which maintained allosteric activity at physiological calcium concentrations. We found that oral administration of IP6 analogs attenuated inflammation and promoted survival in mouse models of CDI. Our data provide impetus to further develop small-molecule allosteric triggers of toxin auto-proteolysis as a therapeutic strategy.