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Fecal microbiota composition is related to brown adipose tissue 18F-fluorodeoxyglucose uptake in young adults.
Ortiz-Alvarez, L, Acosta, FM, Xu, H, Sanchez-Delgado, G, Vilchez-Vargas, R, Link, A, Plaza-Díaz, J, Llamas, JM, Gil, A, Labayen, I, et al
Journal of endocrinological investigation. 2023;46(3):567-576
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Brown adipose tissue (BAT) is a tissue that dissipates energy through the action of the uncoupling protein-1. Moreover, BAT takes up and oxidises glucose and lipids, as such working as a nutrient sink, and through its endocrine function may have cardiometabolic benefits. The aim of this study was to investigate the association of fecal microbiota composition with BAT volume and activity in young adults. This study was a cross-sectional study of 92 young healthy adults (27 men and 65 women, age: 18–25 years old). Results showed that the relative abundance of: - specific genera (Akkermansia, Lachnospiraceae sp., and Ruminococcus) were negatively correlated with BAT volume and activity. - Bifdobacterium genus was positively correlated with BAT activity. Authors concluded faecal microbiota is involved in the regulation of glucose uptake by human BAT and other metabolic tissues including white adipose tissue and skeletal muscles in young adults.
Abstract
OBJECTIVE Human brown adipose tissue (BAT) has gained considerable attention as a potential therapeutic target for obesity and its related cardiometabolic diseases; however, whether the gut microbiota might be an efficient stimulus to activate BAT metabolism remains to be ascertained. We aimed to investigate the association of fecal microbiota composition with BAT volume and activity and mean radiodensity in young adults. METHODS 82 young adults (58 women, 21.8 ± 2.2 years old) participated in this cross-sectional study. DNA was extracted from fecal samples and 16S rRNA sequencing was performed to analyse the fecal microbiota composition. BAT was determined via a static 18F-fluorodeoxyglucose (18F-FDG) positron emission tomography-computed tomography scan (PET/CT) after a 2 h personalized cooling protocol. 18F-FDG uptake was also quantified in white adipose tissue (WAT) and skeletal muscles. RESULTS The relative abundance of Akkermansia, Lachnospiraceae sp. and Ruminococcus genera was negatively correlated with BAT volume, BAT SUVmean and BAT SUVpeak (all rho ≤ - 0.232, P ≤ 0.027), whereas the relative abundance of Bifidobacterium genus was positively correlated with BAT SUVmean and BAT SUVpeak (all rho ≥ 0.262, P ≤ 0.012). On the other hand, the relative abundance of Sutterellaceae and Bifidobacteriaceae families was positively correlated with 18F-FDG uptake by WAT and skeletal muscles (all rho ≥ 0.213, P ≤ 0.042). All the analyses were adjusted for the PET/CT scan date as a proxy of seasonality. CONCLUSION Our results suggest that fecal microbiota composition is involved in the regulation of BAT and glucose uptake by other tissues in young adults. Further studies are needed to confirm these findings. CLINICAL TRIAL INFORMATION ClinicalTrials.gov no. NCT02365129 (registered 18 February 2015).
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Consumption of Extruded Sorghum SC319 Improved Gut Microbiota at Genus Level and Reduced Anthropometric Markers in Men with Overweight: A Randomized Controlled Clinical Trial.
Lúcio, H, Anunciação, P, da Silva, B, da Silva, A, Queiroz, V, de Carvalho, C, Pinheiro-Sant'Ana, H, Martino, H
Nutrients. 2023;15(17)
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Obesity is frequently associated with the dysregulation of lipid, glucose, and cholesterol metabolism, in addition to increased oxidative stress and the establishment of low-grade chronic inflammation, which are risk factors for developing non-communicable chronic diseases. The aim of this study was to investigate the effects of the consumption of extruded SC319 whole sorghum or extruded whole wheat associated with an 8-week daily 500 kcal energy restriction diet on the modulation of intestinal health with a focus on gut microbiota, short-chain fatty acid production, faecal pH, and weight loss and inflammation markers. This study was an 8-week, single-blind, controlled, randomised nutritional intervention study conducted in 21 men with overweight. The participants were randomly allocated in a 1:1 ratio to receive extruded SC319 whole sorghum or extruded whole wheat. Results showed that consuming SC319 extruded sorghum along with an energy restricted diet achieved greater weight loss and reduced body fat percentage in Brazilian men with overweight compared to the wheat group, with no differences in SCFA synthesis, faecal pH, alpha and beta-diversity, and inflammatory markers. Sorghum consumption promoted alternations in intestinal microbiome composition at the genus level, probably due to the presence of resistant starch and polyphenolic compounds. Authors conclude that sorghum consumption improved weight loss, decreased anthropometric measures, and acted as a prebiotic, thereby changing intestinal microbiome composition.
Abstract
BACKGROUND Sorghum is a cereal source of energy, carbohydrates, resistant starch, proanthocyanidins, and 3-deoxyanthocyanins; it promotes satiety by slowing digestion and benefits intestinal health. OBJECTIVE This study investigated the effects of extruded sorghum SC319 consumption on intestinal health, weight loss, and inflammatory markers in men with overweight. METHODS This was a randomized, controlled, single-blind clinical trial. Twenty-one men were randomly allocated into one of two groups: the sorghum group (test), which received 40 g of extruded SC319 whole sorghum (n = 10), or the wheat group (control), which received 38 g of extruded whole wheat (n = 11) for eight weeks. RESULTS The sorghum consumption increased the weight loss intragroup, decreased the body fat percentage intergroup, and did not change inflammatory markers, while the wheat group had increased IL-6 levels compared to baseline. Short-chain fatty acid production, fecal pH, and α and β diversity indexes did not differ intra- and intergroup after interventions. However, sorghum consumption decreased genus levels of Clostridium_sensu_stricto 1, Dorea, and Odoribacter and increased CAG-873 and Turicibacter compared to baseline. Further, sorghum showed a tendency (p = 0.07) to decrease the proteobacteria phyla compared to wheat. CONCLUSION Extruded sorghum SC319 improved intestinal microbiota and body composition and promoted weight loss, demonstrating its prebiotic potential.
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Host-diet-gut microbiome interactions influence human energy balance: a randomized clinical trial.
Corbin, KD, Carnero, EA, Dirks, B, Igudesman, D, Yi, F, Marcus, A, Davis, TL, Pratley, RE, Rittmann, BE, Krajmalnik-Brown, R, et al
Nature communications. 2023;14(1):3161
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Composition of the human gut microbiome has been shown to be associated with chronic diseases such as obesity, however whether they have a causal effect in disease development or whether microbiota composition is a direct result of the disease is unclear. This randomised control trial of 17 individuals aimed to determine the effects of a diet designed to modulate the gut microbiome (MBD) on human energy balance compared to a typical Western style diet (WD). The MBD diet maximised fibre, resistant starch, and limited processed foods and resulted in a significant decrease in the amount of energy produced by individuals compared to the WD. It was also shown that the MBD increased the microbial composition and decreased nutrient breakdown. It was concluded that the MBD increased the amount of gut bacteria and altered the amount of energy produced by individuals on this diet. This study could be used by healthcare practitioners to understand that composition of the gut microbiome can affect the amount of energy gained from food. Diets high in fibre, starch and low in processed foods, which promote microbial diversity may help individuals to lose weight.
Abstract
The gut microbiome is emerging as a key modulator of human energy balance. Prior studies in humans lacked the environmental and dietary controls and precision required to quantitatively evaluate the contributions of the gut microbiome. Using a Microbiome Enhancer Diet (MBD) designed to deliver more dietary substrates to the colon and therefore modulate the gut microbiome, we quantified microbial and host contributions to human energy balance in a controlled feeding study with a randomized crossover design in young, healthy, weight stable males and females (NCT02939703). In a metabolic ward where the environment was strictly controlled, we measured energy intake, energy expenditure, and energy output (fecal and urinary). The primary endpoint was the within-participant difference in host metabolizable energy between experimental conditions [Control, Western Diet (WD) vs. MBD]. The secondary endpoints were enteroendocrine hormones, hunger/satiety, and food intake. Here we show that, compared to the WD, the MBD leads to an additional 116 ± 56 kcals (P < 0.0001) lost in feces daily and thus, lower metabolizable energy for the host (89.5 ± 0.73%; range 84.2-96.1% on the MBD vs. 95.4 ± 0.21%; range 94.1-97.0% on the WD; P < 0.0001) without changes in energy expenditure, hunger/satiety or food intake (P > 0.05). Microbial 16S rRNA gene copy number (a surrogate of biomass) increases (P < 0.0001), beta-diversity changes (whole genome shotgun sequencing; P = 0.02), and fermentation products increase (P < 0.01) on an MBD as compared to a WD along with significant changes in the host enteroendocrine system (P < 0.0001). The substantial interindividual variability in metabolizable energy on the MBD is explained in part by fecal SCFAs and biomass. Our results reveal the complex host-diet-microbiome interplay that modulates energy balance.