1.
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
-
-
-
Free full text
Plain language summary
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.
2.
Broccoli consumption affects the human gastrointestinal microbiota.
Kaczmarek, JL, Liu, X, Charron, CS, Novotny, JA, Jeffery, EH, Seifried, HE, Ross, SA, Miller, MJ, Swanson, KS, Holscher, HD
The Journal of nutritional biochemistry. 2019;63:27-34
-
-
-
-
Free full text
-
Plain language summary
Diet affects metabolic and gastrointestinal diseases, with the microbiome considered to be a mediating factor. Broccoli is a good source of fibre and phytochemicals including glucosinolates. The aim of this investigator-blinded, controlled feeding, randomised, crossover study was to evaluate the effects of broccoli on the composition and function of the microbiome. 18 healthy adults received 200 g cooked broccoli and 20 g raw daikon radish per day for 18 days in addition to a controlled, brassica-free diet or the same diet without the broccoli and daikon radish, with a 24-day washout period. A statistically significant increase in the ratio of Bacteroidetes to Firmicutes was observed following the broccoli intervention. When stratified by BMI above or below 25, this increase was only seen in those with a lower BMI whilst those with a higher BMI displayed a decrease in the ratio, although the latter was not statistically significant. In those with the lower BMI, there was also a correlation between the changes in the microbiota composition and glucosinolate metabolites. It was predicted that the involved changes would affect the functions of the endocrine system, transport and catabolism and energy metabolism. The authors concluded that eating broccoli may affect both the composition and the function of the microbiome.
Expert Review
Conflicts of interest:
None
Take Home Message:
- Broccoli consumption at dosages of 200g per day were shown to change the composition of gastrointestinal microbiota, increasing Bacteroidetes and decreasing Firmicutes, and impact their function
- The observed results were strongest in those with a BMI of less than 26
- While interesting, the study only included 18 participants and therefore the results should be further confirmed.
Evidence Category:
-
X
A: Meta-analyses, position-stands, randomized-controlled trials (RCTs)
-
B: Systematic reviews including RCTs of limited number
-
C: Non-randomized trials, observational studies, narrative reviews
-
D: Case-reports, evidence-based clinical findings
-
E: Opinion piece, other
Summary Review:
Introduction
There is growing evidence linking dysbiosis of the gastrointestinal microbiota and diet-induced gastrointestinal and metabolic diseases. Both long-term and acute dietary changes, fasting, eating frequency, and consumption of specific fibres and food phytochemicals play a role in shaping the composition and function of the microbiota, although evidence is lacking for specific foods. This study aimed to determine the impact of broccoli intake on the number of bacterial strains and their functional capacity.
Methods
This was a single-blind, randomised, crossover, complete feeding intervention. Study participants were healthy adults (n=18, females =10). Participants were requested to not eat Brassica vegetables for 3 weeks before the start of the study.
Subjects participated in two 18-day diet periods separated by a 24-hour washout, during which breakfast and dinner were consumed on site to observe compliance. The control diet was prepared using traditional American foods, excluding all Brassica vegetables. During the broccoli intervention period, participants consumed the same base diet with the addition of 200g of broccoli.
Faecal samples were collected on day 1, and day 16. Quantitative polymerase chain reaction was performed on bacterial strains. On day 17, time series plasma sampling and 24-hour urine collection was done.
Results
There was no difference in alpha diversity (a measure of microbiome diversity within a sample) between the two treatment periods. This indicates that no bacterial species were extinguished by broccoli treatment. Beta diversity analysis (a measure of the (dis)similarity between samples) indicated that bacterial communities were impacted by treatment (P=0.03).
After broccoli consumption, Bacteroidetes increased by 10% (P =0.03), while Firmicutes decreased by 8% (P=0.05). Overall the ratio of Bacteroidetes to Firmicutes increased by 37% (P=0.01) versus a 5% decrease in the control period. The Bacteroides genus increased by 6% (P=0.02) versus a 2% decrease in the control period.
Interestingly, the effects were most strong in those with a lower BMI (< 26 kg/m2) who had an increase in metabolites after broccoli consumption. Algorithms to predict the function of the microbiota showed that broccoli increased endocrine (P=0.05), energy metabolism (P=0.01), transport and catabolism (P=0.04) pathways.
Conclusion
Broccoli intake, at 200g daily, changes the composition and potentially impacts the function of the gut microbiota.
Clinical practice applications:
- Studies like this allow practitioners to focus on specific foods in specific quantities to positively alter the microbiota and their function
- Cruciferous vegetables, like broccoli, kale, cauliflower, cabbage, Brussel sprouts, are an important group as they contain fibre and phytonutrients such as glucosinolates. These compounds can be metabolised by the microbiota into active compounds with health benefits. This study has shown the bidirectional benefit of broccoli consumption in that it can positively impact the function and composition of the microbiota
- Interestingly, the results in this small study were driven by participants with a BMI of less than 26. Sub-group analysis found no statistically significant relationships in participants with BMI >26
- It is worth noting that it is possible that the addition of 5g of fibre from the broccoli is also contributing to the changes observed.
Considerations for future research:
- Larger, controlled feeding studies that isolate specific foods to identify their effects on the microbiota are needed
- Genetic sequencing for only a few bacterial myrosinases has been completed and therefore future studies should aim to assess the metabolic capabilities in faecal samples such as myrosinase activity
- While this study and others have shown changes in the types of bacteria after cruciferous vegetable consumption the consistency of results has been mixed potentially due to differing study designs and treatment dosages. Further studies to clarify and confirm these results would be beneficial
- To assess the function of the microbiota a predictive algorithm was used. This requires experimental confirmation by such methods as metabolite profiling and whole genome shotgun sequencing.
Abstract
The human gastrointestinal microbiota is increasingly linked to health outcomes; however, our understanding of how specific foods alter the microbiota is limited. Cruciferous vegetables such as broccoli are a good source of dietary fiber and phytonutrients, including glucosinolates, which can be metabolized by gastrointestinal microbes. This study aimed to determine the impact of broccoli consumption on the gastrointestinal microbiota of healthy adults. A controlled feeding, randomized, crossover study consisting of two 18-day treatment periods separated by a 24-day washout was conducted in healthy adults (n=18). Participants were fed at weight maintenance with the intervention period diet including 200 g of cooked broccoli and 20 g of raw daikon radish per day. Fecal samples were collected at baseline and at the end of each treatment period for microbial analysis. Beta diversity analysis indicated that bacterial communities were impacted by treatment (P=.03). Broccoli consumption decreased the relative abundance of Firmicutes by 9% compared to control (P=.05), increased the relative abundance of Bacteroidetes by 10% compared to control (P=.03) and increased Bacteroides by 8% relative to control (P=.02). Furthermore, the effects were strongest among participants with body mass index <26 kg/m2, and within this group, there were associations between bacterial relative abundance and glucosinolate metabolites. Functional prediction revealed that broccoli consumption increased the pathways involved in the functions of the endocrine system (P=.05), transport and catabolism (P=.04), and energy metabolism (P=.01). These results reveal that broccoli consumption affects the composition and function of the human gastrointestinal microbiota.
3.
A controlled trial of gluten-free diet in patients with irritable bowel syndrome-diarrhea: effects on bowel frequency and intestinal function.
Vazquez-Roque, MI, Camilleri, M, Smyrk, T, Murray, JA, Marietta, E, O'Neill, J, Carlson, P, Lamsam, J, Janzow, D, Eckert, D, et al
Gastroenterology. 2013;144(5):903-911.e3
-
-
-
Free full text
-
Plain language summary
The relationship between gluten exposure and diarrhoea-predominant irritable bowel syndrome (IBS-D) is not well understood. Non-celiac IBS-D patients who are positive for HLA-DQ2/8 genes associated with CD can show symptom improvement on a gluten-free diet (GFD). The aim of this 4-week parallel randomized controlled clinical trial in HLA-DQ2/8 positive and negative patients with IBS-D was to assess the effects of a gluten-containing diet (GCD) compared to a GFD on bowel function, gut transit, small bowel (SB) and colonic barrier functions as measured by two-sugar excretion permeability test and mRNA expression of TJ proteins in mucosa of the small bowel (SB) and rectosigmoid (RS) derived by biopsy. Immune response to diets was also measured as cytokine production from peripheral blood mononuclear cells (PBMCs). Patient were recruited from the Mayo clinic’s database of IBS suffers, and invited to participate. Patients with diagnosed CD were excluded. Genotype analysis was performed for HLA-DQ2 and HLA-DQ8. 22 patients were placed on the GCD (11 HLA-DQ2/8–negative and 11 HLA-DQ2/8–positive) and 23 on the GFD (12 HLA-DQ2/8−negative and 11 HLA-DQ2/8–positive. All meals and snacks were ingested or prepared in the Mayo Clinic. Patients were advised to eat only the foods provided by the study dieticians. Gluten-free and gluten-containing meals were prepared using the same macronutrient content (20% protein, 30% fat, 50% carb). Compliance to the diet was assessed by direct questioning by the dietitians and reported to be excellent. All patients were ingesting gluten in their diet prior to starting the study. At 4-weeks, a statistically significant decrease in stool frequency of subjects on GFD compared to subjects on GCD (p=0.04) was seen. This effect was more pronounced in subjects who were HLA-DQ2 or 8 positive (p=0.019) There was no significant diet effect (GFD vs. GCD) on, daily stool form, ease of passage or gastric emptying. The GCD was associated with higher small bowel (SB) permeability (based on 0–2 hr levels of mannitol (p=0.028) and lactulose:mannitol ratio (P=0.0012)). SB permeability was greater in HLA-DQ2/8–positive than −negative patients (P=.018). No significant differences in colonic permeability were observed. Significant diet-associated changes in occludin expression in SB mucosa in the HLA-DQ2 or 8 positive group were seen (p=0.017). Expressions of tight junction proteins (zonulin (ZO-1), occludin, and claudin-1 mRNA) in colonic mucosa were significantly lower in GCD relative to GFD in the overall groups, particularly in subjects with HLA-DQ2 or 8 positive status. Cytokine response was higher (interleukin-10) in response to GCD than GFD (unrelated to HLA genotype). A limitation in the quantification of TJ protein expression is that it was solely based on PCR (mRNA expression). In future, other methods should be included to directly identify these proteins and their distribution. The inability to document alterations in colonic permeability using the 2-sugar excretion profile from 8 to 24 hours is a limitation. This may be due to lack of sensitivity of the lactulose and mannitol excretion test, for example, due to the metabolism of both sugars by colonic bacteria. Another limitation is that the mechanism for improvement in stool frequency on a GFD in the absence of changes in colonic transit was not elucidated by our studies. This study does not specifically address the effects of gluten protein per se, and it is possible that other proteins in wheat flour may be responsible for the changes observed. The author concludes that this study provide mechanistic explanations for the observation that gluten withdrawal may improve patient symptoms in IBS. The data also partially explains that the biological effects of gluten were associated with HLA-DQ2 or 8 genotype. The relationship of dietary factors, innate and adaptive immune responses and mucosal interactions in IBS-D deserve further study. Further clinical studies evaluating the effects of gluten withdrawal in patients with IBS-D are needed.
Abstract
BACKGROUND & AIMS Patients with diarrhea-predominant irritable bowel syndrome (IBS-D) could benefit from a gluten-free diet (GFD). METHODS We performed a randomized controlled 4-week trial of a gluten-containing diet (GCD) or GFD in 45 patients with IBS-D; genotype analysis was performed for HLA-DQ2 and HLA-DQ8. Twenty-two patients were placed on the GCD (11 HLA-DQ2/8 negative and 11 HLA-DQ2/8 positive) and 23 patients were placed on the GFD (12 HLA-DQ2/8 negative and 11 HLA-DQ2/8 positive). We measured bowel function daily, small-bowel (SB) and colonic transit, mucosal permeability (by lactulose and mannitol excretion), and cytokine production by peripheral blood mononuclear cells after exposure to gluten and rice. We collected rectosigmoid biopsy specimens from 28 patients, analyzed levels of messenger RNAs encoding tight junction proteins, and performed H&E staining and immunohistochemical analyses. Analysis of covariance models was used to compare data from the GCD and GFD groups. RESULTS Subjects on the GCD had more bowel movements per day (P = .04); the GCD had a greater effect on bowel movements per day of HLA-DQ2/8-positive than HLA-DQ2/8-negative patients (P = .019). The GCD was associated with higher SB permeability (based on 0-2 h levels of mannitol and the lactulose:mannitol ratio); SB permeability was greater in HLA-DQ2/8-positive than HLA-DQ2/8-negative patients (P = .018). No significant differences in colonic permeability were observed. Patients on the GCD had a small decrease in expression of zonula occludens 1 in SB mucosa and significant decreases in expression of zonula occludens 1, claudin-1, and occludin in rectosigmoid mucosa; the effects of the GCD on expression were significantly greater in HLA-DQ2/8-positive patients. The GCD vs the GFD had no significant effects on transit or histology. Peripheral blood mononuclear cells produced higher levels of interleukin-10, granulocyte colony-stimulating factor, and transforming growth factor-α in response to gluten than rice (unrelated to HLA genotype). CONCLUSIONS Gluten alters bowel barrier functions in patients with IBS-D, particularly in HLA-DQ2/8-positive patients. These findings reveal a reversible mechanism for the disorder. Clinical trials.govNCT01094041.