Fucosylated Human Milk Oligosaccharides Drive Structure-Specific Syntrophy between Bifidobacterium infantis and Eubacterium hallii within a Modeled Infant Gut Microbiome.

SCOPE: Fucosylated human milk oligosaccharides (fHMOs) are metabolized by Bifidobacterium infantis and promote syntrophic interactions between microbiota that colonize the infant gut. The role of fHMO structure on syntrophic interactions and net microbiome function is not yet fully understood. METHODS AND RESULTS: Metabolite production and microbial populations are tracked during mono- and co-culture fermentations of 2'fucosyllactose (2'FL) and difucosyllactose (DFL) by two B. infantis strains and Eubacterium hallii. This is also conducted in an in vitro modeled microbiome supplemented by B. infantis and/or E. hallii. Metabolites are quantified by high performance liquid chromatography. Total B. infantis and E. hallii populations are quantified through qRT-PCR and community composition through 16S amplicon sequencing. Differential metabolism of 2'FL and DFL by B. infantis strains gives rise to strain- and fHMO structure-specific syntrophy with E. hallii. Within the modeled microbial community, fHMO structure does not strongly alter metabolite production in aggregate, potentially due to functional redundancy within the modeled community. In contrast, community composition is dependent on fHMO structure. CONCLUSION: Whereas short chain fatty acid production is not significantly altered by the specific fHMO structure introduced to the modeled community, specific fHMO structure influences the composition of the gut microbiome.

Evaluación de las enzimas celulolíticas producidas por hongosnativos mediante fermentación en estado sólido (SSF) utilizando residuos de cosecha de caña de azúcar / Evaluation of cellulolytic enzymes produced by native fungi through solid state fermentation (SSF) using sugarcane harvesting residues

Los residuos agrícolas de cosecha de caña de azúcar (RAC), se constituyen en una materia prima alternativa para la producción de etanol carburante, dado su contenido de celulosa próximo al 40%. El aprovechamiento de la celulosa depende de la aplicación de tratamientos fisicoquímicos o bioquímicos, que permitan la liberación de la glucosa y su posterior utilización en procesos fermentativos. La hidrólisis enzimática de estos residuos requiere un complejo celulolítico producido por microorganismos, comprendido por tres actividades enzimáticas: Endoglucanasas, Exoglucanasas y β-Glucosidasas. En el presente estudio, se evaluaron las enzimas celulolíticas producidas por dos hongos nativos del género Aspergillus spp., CH 2016 y CH 2001, mediante procesos de fermentación en estado sólido utilizando como sustrato RAC pre-tratados con organosolventes (deslignificado) y sin este pre-tratamiento. La cepa CH 2016 presentó la mayor actividad endoglucanasa 11,0773 U/mL en el sustrato sin pre-tratar el día siete de fermentación; esta misma cepa, en el sustrato deslignificado presentó la mayor actividad exoglucanasa (0,042 U/mL) y celulasa total (0,287 UPF/mL) en el día cinco de fermentación. La cepa CH 2001 presentó la mayor actividad β-glucosidasa (0,1778 U/mL) en el sustrato sin pre-tratar el día cinco de fermentación. Se observó que las variables sustrato y tiempo de fermentación, inciden en la expresión de las enzimas celulolíticas obteniendo en este trabajo extractos enzimáticos que pueden llevar a cabo una acción hidrolítica sinérgica sobre la celulosa.

Sugarcane harvesting residues are considered as a raw material for fuel ethanol production due its high content of cellulose, around 40% DS. The use of cellulose depends of the application of physicochemical or biochemical treatments that allow the release of glucose and its subsequent uses in fermentation processes. The enzymatic hydrolysis of these residues requires a cellulolytic complex produced by microorganisms, including three enzymatic activities: Endoglucanases, β-Glucosidases and Exoglucanases. In the present study, cellulolytic enzymes produced by two native fungi Aspergillus spp., CH 2016 and CH 2001 was assessment, through of solid-state fermentation processes using as raw substrate RAC and pre-treated with organosolvents (delignified). Strain CH 2016 had the highest endoglucanase activity 11.0773 U/mL in the raw substrate on day seven of fermentation, the same strain, in the delignified substrate showed the highest activity exoglucanasa (0.042 U/mL ) and total cellulase (0.287 UPF/mL) on day five of fermentation. Strain CH 2001 got the highest β-glucosidase activity (0.1778 U/mL) in the substrate without pre-treatment on day 5 of fermentation. It was observed that the variables as substrate and fermentation time affected the expression of cellulolytic enzymes.