Prebiotic fibers, polyphenols and other molecular components of food crops significantly affect the composition and function of the human gut microbiome and human health. The abundance of these, frequently uncharacterized, microbiome-active components vary within individual crop species. Here, we employ high throughput in vitro fermentations of pre-digested grain using a human microbiome to identify segregating genetic loci in a food crop, sorghum, that alter the composition and function of human gut microbes. Evaluating grain produced by 294 sorghum recombinant inbreds identifies 10 loci in the sorghum genome associated with variation in the abundance of microbial taxa and/or microbial metabolites. Two loci co-localize with sorghum genes regulating the biosynthesis of condensed tannins. We validate that condensed tannins stimulate the growth of microbes associated with these two loci. Our work illustrates the potential for genetic analysis to systematically discover and characterize molecular components of food crops that influence the human gut microbiome.
Celiac disease and non-celiac gluten sensitivity are provoked by the consumption of gluten from wheat, barley, rye, and related grains. Affected individuals are advised to adhere to gluten-free diets. Recently, gluten-free foods have become a marketing trend with gluten-free options in both packaged foods and restaurants/ foodservice establishments. Pasta is one of the primary gluten-containing foods in diets in North America and Europe. Gluten-free pasta formulations are commercially available. In restaurants, multiple pasta dishes are often prepared simultaneously in large multi-compartment pots, with shared cooking water. The objective of this study was to determine if gluten transfer occurs between traditional and gluten-free pasta when cooked simultaneously. Pasta was boiled in a commercial, 4-compartment, 20-qt. cooking pot containing three batches of traditional penne pasta and one batch of gluten-free penne pasta. The amount of pasta (dry weight) was either 52 g (recommended serving size) or 140 g (typical restaurant portion). Five consecutive batches of pasta were boiled, with sampling of cooking water and gluten-free pasta at completion of cooking. Water and gluten-free pasta samples were tested for gluten using the Neogen Veratox for Gliadin ELISA kit. Gluten levels were low (<20 ppm) in both water and gluten-free pasta samples through five batches at the 52-g quantity. The gluten levels in the gluten-free pasta at the 52-g quantity slowly increased through five batches but never exceeded 20 ppm. With the 140-g quantity, the levels of gluten in the cooking water increased with each batch, exceeding 50 and 80 ppm after the fourth and fifth batches. The gluten levels in the gluten-free pasta at the 140-g quantity approached 20 ppm by the fourth batch and reached nearly 40 ppm after the fifth batch. While gluten transfer does not occur at a high rate, gluten-free pasta should be prepared in a separate cooking vessel in restaurant and foodservice operations.
Waxy starches from cereal grains contain >90% amylopectin due to naturally occurring mutations that block amylose biosynthesis. Waxy starches have unique organoleptic characteristics (e.g. sticky rice) as well as desirable physicochemical properties for food processing. Using isogenic pairs of wild type sorghum lines and their waxy derivatives, we studied the effects of waxy starches in the whole grain context on the human gut microbiome. In vitro fermentations with human stool microbiomes show that beneficial taxonomic and metabolic signatures driven by grain from wild type parental lines are lost in fermentations of grain from the waxy derivatives and the beneficial signatures can be restored by addition of resistant starch. These undesirable effects are conserved in fermentations of waxy maize, wheat, rice and millet. We also demonstrate that humanized gnotobiotic mice fed low fiber diets supplemented with 20% grain from isogenic pairs of waxy vs. wild type parental sorghum have significant differences in microbiome composition and show increased weight gain. We conclude that the benefits of waxy starches on food functionality can have unintended tradeoff effects on the gut microbiome and host physiology that could be particularly relevant in human populations consuming large amounts of waxy grains.
The effects of fiber, complex carbohydrates, lipids, and small molecules from food matrices on the human gut microbiome have been increasingly studied. Much less is known about how dietary protein can influence the composition and function of the gut microbial community. Here, we used near-isogenic maize lines of conventional popcorn and quality-protein popcorn (QPP) to study the effects of the opaque-2 mutation and associated quality-protein modifiers on the human gut microbiome. Opaque-2 blocks the synthesis of major maize seed proteins (α-zeins), resulting in a compensatory synthesis of new seed proteins that are nutritionally beneficial with substantially higher levels of the essential amino acids lysine and tryptophan. We show that QPP lines stimulate greater amounts of butyrate production by human gut microbiomes in in vitro fermentation of popped and digested corn from parental and QPP hybrids. In human gut microbiomes derived from diverse individuals, bacterial taxa belonging to the butyrate-producing family Lachnospiraceae, including the genera Coprococcus and Roseburia were consistently increased when fermenting QPP vs. parental popcorn lines. We conducted molecular complementation to further demonstrate that lysine-enriched seed protein can stimulate growth and butyrate production by microbes through distinct pathways. Our data show that organisms such as Coprococcus can utilize lysine and that other gut microbes, such as Roseburia spp., instead, utilize fructoselysine produced during thermal processing (popping) of popcorn. Thus, the combination of seed composition in QPP and interaction of protein adducts with carbohydrates during thermal processing can stimulate the growth of health-promoting, butyrate-producing organisms in the human gut microbiome through multiple pathways.
Background:Waxy starches contain >90% amylopectin and are derived from grain crops carrying naturally-occurring mutations that block amylose biosynthesis. The absence of amylose in waxy starches produces unique physiochemical properties that are desirable for food processing, but the effects of increased amylopectin/amylose ratios in waxy starches on the gut microbiome and physiological characteristics of the host are not well characterized. Here, we used a whole-grain model with isogenic pairs of wild type sorghum lines and their waxy derivatives to test the hypothesis that major differences in amylose/amylopectin ratio produce significant effects on the human gut microbiome. Results:Fermentation of grain from waxy versus wild type derivatives produced substantial differences in overall microbiome composition, abundances of multiple taxa, and production of microbial metabolites (butyrate). Several of the taxonomic and metabolic signatures of fermentations from parental versus waxy lines were shared across fermentations with microbiomes from different human donors, including reduced levels of butyrate production and lower abundances of Roseburia and other amylolytic, butyrate-producing members of Lachnospiraceae in fermentations of waxy lines. Using a human microbiome-associated mouse model, we also detected significant differences in microbiome composition in animals fed low-fiber diets supplemented with 20% grain from isogenic pairs of parental versus waxy derivatives of sorghum. Remarkably, these microbiome changes were accompanied by significant differences in weight gain, with animals consuming waxy sorghum gaining significantly more weight. Conclusions:We conclude that the benefits of waxy starches on food functionality can have trade-off effects on the gut microbiome and host physiology that could be particularly relevant in human populations consuming large amounts of waxy grains.
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