<p dir="ltr">Dietary fibers have been observed to modulate the gut microbiome in ways that prevent and moderate human diseases and confer health benefits onto their human host. How dietary fibers do this is through their structure; gut microbes are equipped with a variety of differ- ent carbohydrate-active enzymes (CAZymes) that allow some to hydrolyze glycosidic bonds, thereby utilizing the dietary fiber. The more complex the dietary fiber, the more diverse the maintained gut microbiota may be, as specialist species may be required for complete hydrol- ysis. Therefore, increasing structural complexity of dietary fibers may increase gut microbial diversity and help prevent diseases. To understand if structural features impact the gut mi- crobiome, a set of resistant glucans varying in structures, including mixed-linkage -glucans, resistant maltodextrins (similar to type IV resistant starch) and polydextroses, which are comprised entirely of glucose, were used as substrates in an in vitro sequential batch fermen- tation using fecal microbiota form three healthy donors as inocula. I measured metabolic outputs, growth curves, and community structures by 16S rRNA amplicon sequencing, which I analyzed for through alpha and beta diversity differences and taxa that overrepresented and increased in each treatment. My results show that, depending on the donor and the resistant glucan, structure does significantly impact the concentrations of short-chain fatty acids (SCFAs) and other metabolites that are produced. Resistant glucan structure also impacts alpha and beta diversity to a degree and linear discriminant analysis (by LEfSe) results also support that specific species have preference towards substrates as well. Next, resistant glucans were supplemented into a high-fat diet, and compared these diets to a low- fat diet (LFD), high-fat diet with cellulose (HFD), and high-fat without cellulose (HWC) in a mouse study using C57BL/6J mice over 4 weeks. Increasing microbial diversity will not only increase diversity in the gut microbiome, but it will also provide protective effects in behavior such as helping to prevent anxiety. I measured weight, metabolic outputs, 16S community structure, changes in alpha and beta diversity, and differential abundances of OTUs and taxa by discriminant analysis Effect Size (LEfSe) and Metastats, and anxiety behaviors using open field and light/dark box tests. Microbial community structure was significantly different in treatment groups from controls. Anxiety for mice in tapioca dextrin 01 (TD01), tapioca dextrin 03 (TD03), and resistant maltodextrin (RMF) treatment groups were gen- erally increased, suggesting that the chemical structure of these resistant dextrins may alter the gut microbiome in ways that may influence behavior.</p><p dir="ltr">My overall results support the hypothesis that the fine structural features of dietary fibers do significantly impact the gut microbiome by selecting for specific microbiota, and may even impact cognition and behavior.</p>
| Identifer | oai:union.ndltd.org:purdue.edu/oai:figshare.com:article/24797100 |
| Date | 14 December 2023 |
| Creators | Phuong Mai Lea Nguyen (17584623) |
| Source Sets | Purdue University |
| Detected Language | English |
| Type | Text, Thesis |
| Rights | CC BY 4.0 |
| Relation | https://figshare.com/articles/thesis/_b_THE_IMPACT_OF_FINE_CHEMICAL_STRUCTURES_OF_b_b_RESISTANT_DEXTRINS_ON_MAINTENANCE_OF_GUT_MICROBIOME_DIVERSITY_AND_FUNCTION_b_b_i_IN_VITRO_i_b_b_AND_b_b_i_IN_VIVO_i_b_/24797100 |
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