Reduced gut microbiome diversity is associated with multiple disorders including metabolic syndrome (MetS) features, though metabolomic markers have not been investigated. Our objective was to identify blood metabolite markers of gut microbiome diversity, and explore their relationship with dietary intake and MetS. We examined associations between Shannon diversity and 292 metabolites profiled by the untargeted metabolomics provider Metabolon Inc. in 1529 females from TwinsUK using linear regressions adjusting for confounders and multiple testing (Bonferroni: P < 1.71 × 10−4). We replicated the top results in an independent sample of 420 individuals as well as discordant identical twin pairs and explored associations with self-reported intakes of 20 food groups. Longitudinal changes in circulating levels of the top metabolite, were examined for their association with food intake at baseline and with MetS at endpoint. Five metabolites were associated with microbiome diversity and replicated in the independent sample. Higher intakes of fruit and whole grains were associated with higher levels of hippurate cross-sectionally and longitudinally. An increasing hippurate trend was associated with reduced odds of having MetS (OR: 0.795[0.082]; P = 0.026). These data add further weight to the key role of the microbiome as a potential mediator of the impact of dietary intake on metabolic status and health.
The diversity of bacteria in the human gut, both in term of the number of different microbes and the comparative evenness of their abundances, is associated with higher abundance of beneficial bacteria and is emerging as an important indicator of health1,2,3,4,5,6. Lower alpha-diversity (intra-individual diversity) is suggestive of dysbiosis (microbial imbalance) and has been associated with metabolic syndrome features6.
Microbes transform food- and host-derived metabolites, such as bile acids and fibre7, and polyphenols8. The profound contribution of the gut microbiome to metabolism has been shown in conventional versus germ-free mice, where conventional mice exhibited elevated blood levels of indole-containing compounds (e.g. indoxyl sulfate and indole-3-propionic acid), serotonin, sulfated compounds (e.g. phenyl and p-cresol sulfate), and glycine-conjugated compounds (hippuric acid, cinnamoylglycine and phenylpropionylglycine)9. Many of the above metabolites are food-derived; therefore, merging microbiome and metabolomics approaches with studies which capture habitual intake is the logical next step for improving our understanding of the complex interplay between diet, the microbiome and metabolic disease.
To date there are relatively few short-term human dietary intervention studies incorporating the microbiome and metabolome. It has been shown that daily consumption of 40 g of dark chocolate for 2 weeks altered urinary output of gut microbial metabolites, increasing hippurate and methylamines, and reducing p-cresol sulfate10. Moreover, a recent randomized controlled pilot study showed feeding 30 g/d of heat-stabilized rice bran for 28 days increased abundance of 11 operational taxonomic units (OTUs), and elevated faecal levels of secondary bile acids and metabolites derived from microbial modifications of plant-derived components11.
To our knowledge, the role of a diverse gut microbiome in humans as a potential mediator of the impact of dietary intake on metabolic status and health has not been robustly addressed. Therefore, the aims of this study are: to (i) identify blood metabolites correlated with gut microbiome diversity, (ii) examine the impact of food intake on these metabolites and to, (iii) examine if longitudinal changes in these metabolites are predictive of future development of the metabolic syndrome.
Supplementary Table S1 provides the study population characteristics and subject numbers.
Microbiome diversity metabolomics associations
Eight metabolites significantly correlated with Shannon diversity in the discovery sample after adjusting for multiple testing (Table 1). These include hippurate, p-cresol sulfate, phenylacetylglutamine, 4-ethylphenolsulfate, indolepropionate and 3-phenylpropionate which were positively associated; and hyodeoxycholate and phenol sulphate which were negatively associated. Five metabolites were validated in the replication sample (Table 1). These include hippurate, p-cresol sulfate, phenylacetylglutamine, 3-phenylpropionate, and hyodeoxycholate.
Higher circulating levels of the benzoate metabolite, hippurate, were also associated with higher fruit (0.012[0.002]; P = 7.36 × 10−8) and whole grains intake (0.013[0.003]; P = 2.05 × 10−5). Another benzoate metabolite, 3-phenylpropionate, was also positively associated with whole grain (0.018[0.004]; P = 2.71 × 10−6) and fruit intake (0.010[0.002]; P = 2.45 × 10−5) while higher levels were inversely associated with lower fried and fast food intake (−0.045[0.009]; P = 5.63 × 10−7). Hippurate and 3-phenylpropionate levels were correlated (r = 0.51; P < 0.001), although summing the two metabolites did not improve their association with Shannon diversity (hippurate R2: 0.0258; 3-phenylpropionate R2: 0.0122; and combined R2: 0.0236), therefore for the remainder of the analysis we focused on hippurate.
Food intakes predict longitudinal hippurate trajectories
In a subsample of the discovery group higher baseline intakes of whole grains (1.70 × 10−4[3.84 × 10−5]; P = 9.54 × 10−6), coffee (1.03 × 10−4[2.82 × 10−5]; P = 2.73 × 10−4) and fruit (8.43 × 10−5[2.71 × 10−5]; P = 1.89 × 10−3) significantly (P < 0.0025) predicted increasing hippurate trends. All food associations were independent, remaining significant in a multivariate linear regression model and together accounted for 5.3% of the variance in hippurate trend. We calculated a hippurate diet score (computed as the quartile sum of these three food intakes) in the discovery sample (hippurate association: 0.089[0.012]; P = 1.13 × 10−13, and Shannon diversity association: 0.031[0.009]; P = 5.76 × 10−4) and validated it in the validation sample against hippurate levels (0.089[0.024]; P = 3.21 × 10−4), and Shannon diversity (0.040[0.019]; P = 0.035) (independently of hippurate). The hippurate diet score was moderately heritable (A: 0.3782 [0.3024, 0.4485]; E: 0.6218 [0.5515, 0.6976]). We confirmed the same directional effects for other diversity metrics for hippurate and the diet score (Supplementary Table S2).
OTU and collapsed taxa associations with hippurate
In the whole sample thirty OTUs and sixteen collapsed taxa (Fig. 1) were significantly associated with blood levels of hippurate (P < 8.61 × 10−5 [OTUs]−1.47 × 10−3 [phylum]). Direction of effect in significant OTU and taxa hits was consistent with taxonomic relationships across all results, except within Clostridia. However, this is a known polyphyletic taxon. The positively associated taxa or OTUs belonged to the Ruminococcaeae family and one OTU of the family Rikenellaceae. The negatively associated taxa or OTUs belonged to the class Erysipelotrichi, the order Actinomycetales, the Lachnospiraceae family and the collapsed Ralstonian genus.
Following a backward stepwise linear regression using P < 0.05 as the cut-off threshold, together the remaining OTUs accounted for 58.0% of the variance in Shannon diversity and 7.1% of the variance in hippurate levels (adjusted for diversity).
OTU and Taxa associated with both hippurate and the hippurate diet score
Five OTUs and five taxa associated with hippurate were also associated with the diet score in the same direction (Table 2) in the whole sample. Specifically, reduced abundances of one OTU assigned to the genus Actinomyces were associated with an increased diet score, and similar to hippurate this trend was significant at both the family and order levels. At the genus level, reduced abundances of Ruminococcus (including 2 OTUs) and Eubacterium were associated with increasing diet scores. Moreover, increased diet scores were associated with increased abundances of OTUs assigned to the species Faecalibacterium prausnitzii and the genus Clostridiales. Most associations appeared to be to be primarily related to intakes of fruit and whole grains (Table 2). Though higher abundances of one Clostridiales OTU were associated with increased coffee intake.
Relationship of diversity, the hippurate trend and diet to MetS and its components
Supplementary Table 3 provides the clinical characteristics of the subsample of individuals studied. Longitudinal hippurate trajectories were significantly associated with Shannon diversity, independently of diet and covariates in a subsample of 1032 individuals (15.736[1.96]; P = 4.95 × 10−15), moreover the hippurate trend accounted for 6.5% of the variance in Shannon diversity.
Figure 2 shows the results of the analysis for associations between diversity, the hippurate trend and MetS. Higher Shannon diversity and an increasing hippurate trend were associated with a reduced risk of having MetS (Fig. 2a). 61.1% of the effect of the hippurate trend on MetS was accounted for by the association between Shannon diversity and MetS. Five collapsed taxa and 3 of the OTUs that were associated with both diet and hippurate were associated with MetS, including: the Actinomycetaceae family, and Actinomycetales order and Actinomyces genus within Actinomycetaceae, the Eubacterium and Ruminococcus genera (plus one OTU), which were positively associated; and OTUs assigned to the order Clostridiales and Faecalibacterium prausnitzii that were inversely associated. The percentage variance in the metabolite trend and MetS that was accounted for by the MetS association with these associated OTUs/taxa is shown in Fig. 2b.
Confirmation of results in discordant twins
We identified 55 MZ twin pairs who were discordant (1 SD apart) for Shannon diversity. Associations between Shannon diversity and hippurate were significant (P < 0.05) cross-sectionally (0.208[0.081]; P = 0.013) and longitudinally (0.478[0.078]; P = 9.53 × 10−8), and associations for top variables were in the same direction as in the much larger whole group analysis (Supplementary Table S4), except for HDL-cholesterol.
Here we have identified hippurate, through its relationship with microbiome diversity, as a potential modulator of MetS, independently of diet. Specifically, we find that circulating levels of five blood metabolites, including hippurate, are associated with greater gut microbiome diversity both cross-sectionally and longitudinally and higher intakes of fruit and whole grains. Hippurate and intakes of foods including coffee, fruit and whole grains also correlated with 5 OTUs and 5 collapsed taxa independent of diversity. In particular, hippurate was positively associated with an OTU within the order Clostridiales and the species Faecalibacterium prausnitzii and negatively with the Actinomycetaceae family, and the genera Eubacterium and Ruminococcus. Both an increasing Shannon diversity score and increasing hippurate levels were associated with a lower risk of MetS.
We identified and validated in an independent sample 5 metabolites associated with gut microbiome diversity: hippurate, p-cresol sulfate, phenylacetylglutamine and 3-phenylpropionate which were positively associated; and a negative association with hyodeoxycholate.
P-cresol sulfate (also p-cresyl sulfate) and phenylacetylglutamine are potentially toxic uremic solutes formed from the putrefication of undigested dietary proteins by colonic bacteria (and, in the case of p-cresol sulfate, subsequent modification by the liver). Our group previously showed higher p-cresol sulfate and phenylacetylglutamine levels to be strongly associated with early kidney dysfunction and gut microbiome OTUs12. Hyodeoxycholate is a secondary bile acid, produced from intestinal bacterial metabolism. Hyodeoxycholate is metabolised by glucuronidation in the human liver and kidneys, a pathway for toxin elimination13. Both 3-phenylpropionate and hippurate are derived from gut microbial metabolism of polyphenols to benzoates, though hippurate accounted for a larger portion of the variance in diversity. Hippurate is a glycine conjugate of benzoic acid formed in the mitochondria of the liver and kidneys14, and also through gut bacterial metabolism of dietary components, primarily polyphenols15,16. Although hippurate is also derived from the metabolism of quinic acid and/or shikimic acid17.
Overall, increased Shannon diversity and the hippurate trend were associated with a reduced odds of having MetS. Interestingly, 61.1% of the effect of the hippurate trend on MetS was mediated by the association between Shannon diversity and MetS. A previous study has shown reduced gut bacterial diversity of MetS features6. We believe the relationship between MetS and blood hippurate to be a novel finding, though studies have shown reduced urinary hippuric acid excretion in obesity18,19,20. We have previously found increasing circulating levels of hippurate to be associated with adipose tissue gene expression levels of neuroglobin, a type of globin21. Neuroglobin expressed in neurons and some endocrine tissues acts to protect cells against hypoxia and oxidative stress22.
Overall increased abundances OTUs/taxa of the Actinomycetaceae family and the genera Eubacterium and Ruminococcus were associated with reduced hippurate and the diet and increased MetS risk, and increased abundances of OTUs of the order Clostridiales and the species Faecalibacterium prausnitzii were associated with increased hippurate and diet score and reduced MetS risk.
The Actinomycetaceae family are typical commensals present within the oral cavity. In rare cases, an Actinomyces overgrowth contributes to an infection within the gut through forming filamentous branches that grow through damaged mucosal tissue penetrating the gut barrier, forming abscesses and fistula23. The relationship between Actinomycetaceae and the foods forming the hippurate diet score is not entirely clear. We found increased abundance of the genus Eubacterium to be associated with lower hippurate and the diet score, particularly whole grain intake. Contrary to our findings, feeding of whole grains24 and switching from a Western to plant-based diet25 in 10 humans have enriched abundances of species Eubacterium rectale. Another species, Eubacterium dolichum was found to be elevated in mice fed a Western-style diet26. Higher abundances of the genus Ruminococcus (one OTU and collapsed taxonomy) were associated with higher MetS risk. Increased Ruminococcus abundances were associated with lower fruit intake. Ruminococcus abundances were reduced following 12-week feeding of schisandra chinensis fruit, which is high in flavonoids27.
Increased abundances of OTUs within Clostridiales and Faecalibacterium prausnitzii were associated with increased hippurate, dietary components and reduced risk of MetS. The Clostridiales OTU was strongly and positively associated with coffee intake. Significantly elevated levels of the Clostridium coccoides-Eubacterium rectale group have been shown following the incubation of human faecal microbiota with coffee samples28. Faecalibacterium prausnitzii has been shown to correlate with microbiome gene count and predict weight loss over time6. Faecalibacterium prausnitzii has been shown to be depleted in 239 MetS subjects and partially restored following a 2 year Mediterranean diet intervention29. Increased abundances of the Faecalibacterium prausnitzii OTU were mildly associated with higher whole grain intake. Whole grains appear to allow Faecalibacterium prausnitzii to flourish30.
There were a number of limitations to this study. Importantly, the metabolomics methods utilised in our study do not yield absolute concentrations. Ideally a targeted method that could provide robust validation of the quantitative results. These data however offer important insights that can be tested by other groups using targeted metabolomics methods. The use of targeted assays would have been an ideal way to validate our findings. Unfortunately it is not a viable option for our cohort. We included few males therefore these results may only apply to women. As the FFQ relies on subject reporting, the accuracy of this recall data is always to some extent problematic. If misclassification of intakes had occurred, it would appear as error and likely have obscured any real findings and not strengthened them. Furthermore, we replicated our findings in MZ twin pairs and from previous feeding studies which have shown hippurate excretion to be increased following the consumption of these foods. We have not considered the influence of freezing and transit time in these analyses. Whilst these may influence results we do not expect this to be a large effect as variations in sample collection would be distributed randomly in relation to the phenotypes assessed. However, future analyses could be improved by taking these into consideration in the experimental design and analysis stages. Moreover, it will be of interest to carry out further research to identify how the bacteria interact and how that might influence microbiome diversity, related metabolites and be affected by diet. Finally, the range of time differences between sample collections is an issue throughout this paper. Though likely our results would have been stronger if closer time points were used between data collections.
There were also many advantages. We had a large number of twin subjects with the unique combination of metabolomics profiling, dietary information and gut microbiome profiling. We also had access to a unique longitudinal metabolomics dataset in order to evaluate the influence of changes in hippurate levels on MetS risk.
In conclusion, we identified novel diet-microbiome-metabolite relationships including five specific metabolites that are related to a diverse microbiome profile. Hippurate in particular was strongly associated to increased gut microbiome diversity and consumption of polyphenol-rich foods including coffee, whole grains and fruit and reduced odds of MetS. The potential of hippurate as a marker of alpha-diversity and the interplay between a diet rich in these foods, gut microbes and hippurate production should now be established in dynamic mechanistic studies using a dietary intervention setting.
Materials and Methods
The study population included twins enrolled in the TwinsUK registry, which is a national register of healthy adult twins residing throughout the UK31. Twins included in the dataset all had completed food intake questionnaires, faecal microbiome and blood metabolomics profiling (Fig. 3a shows the dataset information). Food intakes were estimated by administering a 131-item validated Food Frequency Questionnaire (FFQ)32 between 1995 and 2001, in 2007 and from 2014 to 2015. Food intake frequencies were collapsed into 20 different food types (Supplementary Table S5). The sample was divided into discovery and validation groups according to when FFQs were completed (before or in/after 2014). Female twins who completed FFQs collected between 1995 and 2001 and in 2007 were used in the discovery analysis (n = 1529). New FFQ data was collected between 2014 and 2015; 484 additional individuals had microbiome and metabolomics data and completed FFQs during this time, 420 of these individuals who had no co-twin in the discovery sample were used as a validation sample. Quality control of the FFQ dataset has been outlined previously33. The study has been approved by the local St. Thomas’ Hospital Research Ethics Committee and was performed in accordance with the approved guidelines. All study participants provided written informed consent.
Faecal microbiome composition
Faecal samples were collected at follow-up between 2012 and 2016, and the composition of the gut microbiome was determined by 16 S rRNA gene sequencing carried out as previously described34. Details for the microbiome quality control are described in Supplementary Text S1. Shannon diversity was the primary index considered for analysis, this index is normally distributed and most commonly used. There were on 5.46 (3.83) years between FFQ and faecal sample collection.
Non-targeted mass spectroscopy-based metabolomic profiling was undertaken in three batches all within 2 years by the metabolomics provider Metabolon, Inc. (Durham, NC) on 6056 fasting blood samples (batch 1 in serum and batches 2 and 3 in plasma), as previously outlined35 and detailed in Supplementary Text S2. The Metabolon platform identified 292 structurally named biochemicals that belong to the following broad categories: amino acids, carbohydrates, vitamins, lipids, nucleotides, peptides, and xenobiotics (Supplementary Table S6). The associations between metabolite and batch adjusted for age, BMI and family relatedness can be found in Supplementary Table S7. Quality control on the metabolomics dataset was performed as previously described35 (Supplementary Text S2). Briefly, raw data were median-normalised by dividing the metabolite concentrations by the daily median for that metabolite. Metabolite concentrations did not follow a normal distribution and were therefore inverse-normalized. There were on average 3.13 (SD: 3.10) years between the FFQ and the blood sample collection.
Classification of the metabolic syndrome
Clinical visits were undertaken where a trained research nurse or assistant collected blood samples, waist circumference and blood pressure (Supplementary Text S3 for details).
MetS status was determined by the International Diabetes Federation and the American Heart Association/National Heart, Lung, and Blood Institute criteria36.
TwinsUK omics and phenotypic data are publicly available upon request. Details can be found on the departmental website (http://www.twinsuk.ac.uk/data-access/accessmanagement/).
Statistical analysis was carried out using Stata version 12. The statistical analysis was undertaken in two parts. First, a metabolomic marker of microbiome diversity was identified, its relationship to food intake explored and associations with microbiome OTUs/collapsed taxonomies identified. In the second part, the relationship between longitudinal levels of the diversity metabolite marker, diet, diversity and associated OTUs/taxa with the risk of MetS was explored.
Part 1: Metabolomics associations with diversity, relationship to food intake and associations with microbiome OTUs/taxa
Figure 3b shows the study outline for this section.
Microbiome diversity-metabolite associations
A linear mixed regression model with Shannon diversity as a predictor of the metabolite level was undertaken in a group of 1529 females, adjusted for age, batch, BMI and family relatedness as random intercept and multiple testing (Bonferroni: 0.05/292 = 1.71 × 10−4). Significant metabolites from the discovery sample were then evaluated against Shannon diversity using the same linear regression (additionally including sex as a covariate) in the validation sample (including n = 113 males), associations passing the 5% level of significance were considered validated.
Food intake associations with diversity-associated metabolites
In the discovery sample, reported intakes of 20 food groups were used to predict levels of the validated metabolites (Bonferroni: 0.05/[5 metabolites × 20 food groups] = 5.00 × 10−4), adjusted for the same covariates as above. In a subsample of individuals from the discovery group (n = 788) longitudinal metabolomics data was available (n = 705 3 time points, n = 83 2 time points) as well as reported food group intake at the same time or 5 years before the first blood sample. Trajectories of change (indicated as ‘trend’ from here forward) in the top diversity-associated metabolite (years after baseline: 2nd time point: 7.4 [range: 2.3–12.8]; 3rd time point: 13.9 [range: 8.3–17.9]) were determined by empirical Bayes predictions (adjusted for age and BMI) which estimates the rate of change in standard deviations/year37. Using this method, point estimates were calculated and a slope of change determined. Food group intake at or before baseline metabolite levels was then used to predict the metabolite trends (Bonferroni: 0.05/20 food groups = 0.0025).
A dietary score predictive of the metabolite trend was created from quartile (Q)-ranking significantly associated foods, scoring according to the direction of association (i.e. positive association: Q1 = 0-Q4 = 3; negative association: Q1 = 3-Q4 = 0) and summing. The heritability of the score was determined by structural equation modelling using Mx (Supplementary Text S4 for details).
To establish the association between the metabolite and diet score with richness (defined here as number of observed OTUs) and additional diversity metrics (Simpson and Chao1), these associations were run using the same linear regression as for the Shannon diversity discovery analysis, though in the whole sample.
To identify associations between the metabolite and the microbiome, the discovery and validation samples were combined (n = 2013). Associations with the microbiome were evaluated by calculating a linear regression model using the OTUs and OTUs collapsed at each taxonomic level (phylum, class, order, family, genus) as predictors of the metabolite adjusted for covariates (age, BMI, batch, sex and family relatedness), Shannon diversity and multiple-testing (Bonferroni cut-off; Supplementary Table S8 shows the significance threshold for the OTUs and each taxonomic level). To determine the total variance of both Shannon diversity and the metabolite explained by the metabolite-associated OTUs, we included all associated OTUs in a backwards stepwise linear regression using P < 0.05 as the threshold cut-off and we report theR2 for each model. We then calculated linear mixed models of metabolite-associated OTUs/taxa using the diet score as a predictor of abundances adjusted for covariates, the metabolite and multiple testing (assigned at each taxonomic level; Supplementary Table S8). To investigate if any of the foods forming the score were driving associations, we ran a multivariate regression model including all metabolite-associated foods and the same covariates.
Part 2: The relationship between longitudinal levels of the diversity metabolite marker, diet, diversity and associated OTUs/taxa with the risk of MetS
Figure 3c shows the analysis pipeline for this section.
Relationship between microbiome diversity, longitudinal metabolite and the MetS
A subsample of 1032 individuals (primarily female) had longitudinal levels of the blood metabolite (n = 533 with 2 time points, n = 499 with 3 time points; range: 2.4–17.9 years). To evaluate whether longitudinal levels of the top diversity metabolite predicted MetS status, we ran independent linear regression models each for Shannon diversity, the metabolite trend (determined using empirical Bayes predictions as above), the diet score, and metabolite/diet-associated OTUs/taxa to predict MetS status adjusting for age, sex, and family relatedness.
Longitudinal Metabolite association with MetS mediated by Shannon diversity, the diet score and specific taxa
The aim of this analysis was to determine how much of the variance in the metabolite trend and MetS was accounted for by the MetS association with Shannon diversity, the diet score or specific OTUs/taxa. Details are provided in Supplementary Text S5.
Confirmation of findings in twins discordant for Shannon diversity
In 55 MZ twin pairs discordant (≥1 SD) for Shannon diversity, we confirmed associations between Shannon diversity and the longitudinal metabolite trend, also cross-sectional metabolite, diet score and MetS using the same regression models as the discovery analysis.
Michail, S. et al. Alterations in the gut microbiome of children with severe ulcerative colitis. Inflammatory bowel diseases 18, 1799–1808, https://doi.org/10.1002/ibd.22860 (2012).
Ott, S. J. et al. Reduction in diversity of the colonic mucosa associated bacterial microflora in patients with active inflammatory bowel disease. Gut 53, 685–693 (2004).
Manichanh, C. et al. Reduced diversity of faecal microbiota in Crohn’s disease revealed by a metagenomic approach. Gut 55, 205–211, https://doi.org/10.1136/gut.2005.073817 (2006).
Scher, J. U. et al. Decreased bacterial diversity characterizes the altered gut microbiota in patients with psoriatic arthritis, resembling dysbiosis in inflammatory bowel disease. Arthritis & rheumatology (Hoboken, N. J.) 67, 128–139, https://doi.org/10.1002/art.38892 (2015).
Turnbaugh, P. J. et al. A core gut microbiome in obese and lean twins. Nature 457, 480–484, https://doi.org/10.1038/nature07540 (2009).
Le Chatelier, E. et al. Richness of human gut microbiome correlates with metabolic markers. Nature 500, 541–546, https://doi.org/10.1038/nature12506 (2013).
Sonnenburg, J. L. & Backhed, F. Diet-microbiota interactions as moderators of human metabolism. Nature 535, 56–64, https://doi.org/10.1038/nature18846 (2016).
Cassidy, A. & Minihane, A. M. The role of metabolism (and the microbiome) in defining the clinical efficacy of dietary flavonoids. The American journal of clinical nutrition, doi:https://doi.org/10.3945/ajcn.116.136051 (2016).
Wikoff, W. R. et al. Metabolomics analysis reveals large effects of gut microflora on mammalian blood metabolites. Proceedings of the National Academy of Sciences of the United States of America 106, 3698–3703, https://doi.org/10.1073/pnas.0812874106 (2009).
Martin, F. P. et al. Metabolic effects of dark chocolate consumption on energy, gut microbiota, and stress-related metabolism in free-living subjects. Journal of proteome research 8, 5568–5579, https://doi.org/10.1021/pr900607v (2009).
Sheflin, A. M. et al. Pilot dietary intervention with heat-stabilized rice bran modulates stool microbiota and metabolites in healthy adults. Nutrients 7, 1282–1300, https://doi.org/10.3390/nu7021282 (2015).
Barrios, C. et al. Gut-Microbiota-Metabolite Axis in Early Renal Function Decline. PloS one 10, e0134311, https://doi.org/10.1371/journal.pone.0134311 (2015).
Perreault, M. et al. Role of glucuronidation for hepatic detoxification and urinary elimination of toxic bile acids during biliary obstruction. PloS one 8, e80994, https://doi.org/10.1371/journal.pone.0080994 (2013).
Temellini, A. et al. Conjugation of benzoic acid with glycine in human liver and kidney: a study on the interindividual variability. Xenobiotica; the fate of foreign compounds in biological systems 23, 1427–1433 (1993).
Gonthier, M. P., Verny, M. A., Besson, C., Remesy, C. & Scalbert, A. Chlorogenic acid bioavailability largely depends on its metabolism by the gut microflora in rats. The Journal of nutrition 133, 1853–1859 (2003).
Walsh, M. C. et al. Influence of acute phytochemical intake on human urinary metabolomic profiles. The American journal of clinical nutrition 86, 1687–1693 (2007).
Ulaszewska, M. M. et al. Urinary metabolomic profiling to identify biomarkers of a flavonoid-rich and flavonoid-poor fruits and vegetables diet in adults: the FLAVURS trial. Metabolomics: Official journal of the Metabolomic Society 12, 32, https://doi.org/10.1007/s11306-015-0935-z (2016).
Shearer, J. et al. Metabolomic profiling of dietary-induced insulin resistance in the high fat-fed C57BL/6J mouse. Diabetes, obesity & metabolism 10, 950–958, https://doi.org/10.1111/j.1463-1326.2007.00837.x (2008).
Waldram, A. et al. Top-down systems biology modeling of host metabotype-microbiome associations in obese rodents. Journal of proteome research 8, 2361–2375, https://doi.org/10.1021/pr8009885 (2009).
Calvani, R. et al. Gut microbiome-derived metabolites characterize a peculiar obese urinary metabotype. International journal of obesity (2005) 34, 1095–1098, https://doi.org/10.1038/ijo.2010.44 (2010).
Pallister, T. et al. Untangling the relationship between diet and visceral fat mass through blood metabolomics and gut microbiome profiling. International journal of obesity (2005) 41, 1106–1113, https://doi.org/10.1038/ijo.2017.70 (2017).
Burmester, T., Gerlach, F. & Hankeln, T. Regulation and role of neuroglobin and cytoglobin under hypoxia. Advances in experimental medicine and biology 618, 169–180 (2007).
Bonnefond, S. et al. Clinical features of actinomycosis: A retrospective, multicenter study of 28 cases of miscellaneous presentations. Medicine 95, e3923, https://doi.org/10.1097/md.0000000000003923 (2016).
Martinez, I. et al. Gut microbiome composition is linked to whole grain-induced immunological improvements. The ISME journal 7, 269–280, https://doi.org/10.1038/ismej.2012.104 (2013).
David, L. A. et al. Diet rapidly and reproducibly alters the human gut microbiome. Nature 505, 559–563, https://doi.org/10.1038/nature12820 (2014).
Turnbaugh, P. J., Backhed, F., Fulton, L. & Gordon, J. I. Diet-induced obesity is linked to marked but reversible alterations in the mouse distal gut microbiome. Cell host & microbe 3, 213–223, https://doi.org/10.1016/j.chom.2008.02.015 (2008).
Song, M. Y., Wang, J. H., Eom, T. & Kim, H. Schisandra chinensis fruit modulates the gut microbiota composition in association with metabolic markers in obese women: a randomized, double-blind placebo-controlled study. Nutrition research (New York, N.Y.) 35, 655–663, https://doi.org/10.1016/j.nutres.2015.05.001 (2015).
Mills, C. E. et al. In vitro colonic metabolism of coffee and chlorogenic acid results in selective changes in human faecal microbiota growth. The British journal of nutrition 113, 1220–1227, https://doi.org/10.1017/s0007114514003948 (2015).
Haro, C. et al. The gut microbial community in metabolic syndrome patients is modified by diet. The Journal of nutritional biochemistry 27, 27–31, https://doi.org/10.1016/j.jnutbio.2015.08.011 (2016).
Benus, R. F. et al. Association between Faecalibacterium prausnitzii and dietary fibre in colonic fermentation in healthy human subjects. The British journal of nutrition 104, 693–700, https://doi.org/10.1017/s0007114510001030 (2010).
Moayyeri, A., Hammond, C. J., Hart, D. J. & Spector, T. D. The UK Adult Twin Registry (TwinsUK Resource). Twin research and human genetics: the official journal of the International Society for Twin Studies 16, 144–149, https://doi.org/10.1017/thg.2012.89 (2013).
Bingham, S. A. et al. Nutritional methods in the European Prospective Investigation of Cancer in Norfolk. Public health nutrition 4, 847–858 (2001).
Teucher, B. et al. Dietary patterns and heritability of food choice in a UK female twin cohort. Twin research and human genetics: the official journal of the International Society for Twin Studies 10, 734–748, https://doi.org/10.1375/twin.10.5.734 (2007).
Goodrich, J. K. et al. Genetic Determinants of the Gut Microbiome in UK Twins. Cell host & microbe 19, 731–743, https://doi.org/10.1016/j.chom.2016.04.017 (2016).
Menni, C. et al. Metabolomic markers reveal novel pathways of ageing and early development in human populations. International journal of epidemiology 42, 1111–1119, https://doi.org/10.1093/ije/dyt094 (2013).
Alberti, K. G. et al. Harmonizing the metabolic syndrome: a joint interim statement of the International Diabetes Federation Task Force on Epidemiology and Prevention; National Heart, Lung, and Blood Institute; American Heart Association; World Heart Federation; International Atherosclerosis Society; and International Association for the Study of Obesity. Circulation 120, 1640–1645, https://doi.org/10.1161/circulationaha.109.192644 (2009).
Rabe-Hesketh, S. & Skrondal, A. Classical latent variable models for medical research. Statistical methods in medical research 17, 5–32, https://doi.org/10.1177/0962280207081236 (2008).
We thank Dr. Julia K. Goodrich, Dr Ruth E. Ley and the Cornell technical team for generating the microbial data. The Twins UK microbiota project was funded by the National Institute of Health (NIH) RO1 DK093595, DP2 OD007444. Twins UK receives funding from the Wellcome Trust European Community’s Seventh Framework Programme (FP7/2007-2013 to TwinsUK); the National Institute for Health Research (NIHR) Clinical Research Facility at Guy’s & St Thomas’ NHS Foundation Trust and NIHR Biomedical Research Centre based at Guy’s and St Thomas’ NHS Foundation Trust and King’s College London. CM is funded by the MRC AimHY (MR/M016560/1) grant. AC is a Royal Society Wolfson Research Merit Award Holder.
Robert P. Mohney is employed by Metabolon Inc. TDS is co-founder of MapMyGut Ltd. All other authors have nothing to disclose.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
About this article
Cite this article
Pallister, T., Jackson, M.A., Martin, T.C. et al. Hippurate as a metabolomic marker of gut microbiome diversity: Modulation by diet and relationship to metabolic syndrome. Sci Rep 7, 13670 (2017). https://doi.org/10.1038/s41598-017-13722-4
npj Biofilms and Microbiomes (2021)
Circulating amino acids and amino acid-related metabolites and risk of breast cancer among predominantly premenopausal women
npj Breast Cancer (2021)
The sugar composition of the fibre in selected plant foods modulates weaning infants’ gut microbiome composition and fermentation metabolites in vitro
Scientific Reports (2021)
Plasma metabolites associated with chronic kidney disease and renal function in adults from the Baltimore Longitudinal Study of Aging
Metabolomic profiling of metoprolol hypertension treatment reveals altered gut microbiota-derived urinary metabolites
Human Genomics (2020)