Dietary lipids favor the growth of the pathobiont Bilophila wadsworthia, but the relevance of this expansion in metabolic syndrome pathogenesis is poorly understood. Here, we showed that B. wadsworthia synergizes with high fat diet (HFD) to promote higher inflammation, intestinal barrier dysfunction and bile acid dysmetabolism, leading to higher glucose dysmetabolism and hepatic steatosis. Host-microbiota transcriptomics analysis reveal pathways, particularly butanoate metabolism, which may underlie the metabolic effects mediated by B. wadsworthia. Pharmacological suppression of B. wadsworthia-associated inflammation demonstrate the bacterium’s intrinsic capacity to induce a negative impact on glycemic control and hepatic function. Administration of the probiotic Lactobacillus rhamnosus CNCM I-3690 limits B. wadsworthia-induced immune and metabolic impairment by limiting its expansion, reducing inflammation and reinforcing intestinal barrier. Our results suggest a new avenue for interventions against western diet-driven inflammatory and metabolic diseases.
In the last three decades, the prevalence of obesity and associated metabolic complications such as type 2 diabetes and non-alcoholic fatty liver disease have significantly increased worldwide and represent a major socio-economic burden1. Hence, there is an increasing drive to understand factors that may influence the development and progression of the metabolic disease.
Different diets rapidly and reproducibly alter both the composition and function of the gut microbiota2. For instance, over-representation of Bilophila wadsworthia, a Gram-negative sulfite-reducing bacteria that is commonly recovered from patients with appendicitis3,4, had been associated with animal based diets and diets rich in fats2,5,6,7. At least in HFD setting, increased production of taurine conjugated bile acids had been proposed to underlie the expansion of B. wadsworthia5. The negative effect of increased abundance of B. wadsworthia on intestinal inflammation had been demonstrated, but despite its documented association with dietary fats5,7, it remains unknown whether B. wadsworthia imposes negative consequences on metabolic host function. Interestingly, higher level of B. wadsworthia had been similarly observed in individuals suffering from severe malnutrition8. The mechanism by which a single bacterium can play a pleiotropic role in myriad of diseases remained unclear, but diet seemed to play a major role in driving microbial fitness9.
It has now been recognized that alterations in gut microbiota composition and function seem to be one hallmark of metabolic impairment;1 however, causal relationships that underlie these processes are complex and are not yet fully understood. Nevertheless, the ability to access and reprogram the composition and function of the gut microbiota make it an attractive target for preventive or therapeutic intervention. Oral deliveries of specific probiotics strains belonging to Lactobacillus and Bifidobacterium species have shown to confer protective effects against obesity and metabolic syndrome in animal models10. Little is however known whether these beneficial bacteria directly modulate microbiota function and composition, which in turn limit disease progression.
Here, using a combination of host transcriptomics, metatranscriptomics, gnotobiotics and conventional mouse models, we explored the ability of the pathobiont B. wadsworthia to thrive under HFD setting (saturated animal-derived fat) and its ability to modify host physiology and metabolism. Furthermore, we investigated the capacity of the probiotic Lactobacillus rhamnosus strain CNCM I-3690, previously demonstrated to have an anti-inflammatory properties, protective effects against intestinal barrier dysfunction and HFD-induced metabolic alterations in mice, as well as able to induce a decrease of Desulfobrionaceae family, on which B. wadsworthia belongs to10,11,12. We showed that B. wadsworthia worsens the detrimental impact of HFD on host metabolism, in inflammation dependent and independent manners, and L. rhamnosus CNCM I-3690 was efficient in delimiting some of the B. wadsworthia-associated metabolic and immune impairments, suggesting that preventing B. wadsworthia’s expansion may be a novel therapeutic strategy in both inflammatory and metabolic diseases.
HFD promotes increased B. wadsworthia expansion in mice
To confirm the effect of dietary fat on the host metabolic status, mice were maintained on either control diet (CD) or high fat diet enriched with milk-fat (HFD). In agreement with previous results5,7, we observed significantly higher fecal B. wadsworthia level in HFD-fed mice but the increase was only 3.7-fold higher compared to CD-fed mice after 9 weeks of diet (Fig. 1a). This result might reflect the low level of B. wadsworthia in our animal facility. Nonetheless, mice on HFD had gained more than 20% weight compared to CD-fed mice (Fig. 1b). Weight gain was linked to an increased calorie intake (Supplementary Figure 1a). HFD-fed mice further showed elevated fasting blood glucose and insulin as well as homeostatic model assessment–insulin resistance (HOMA-IR) compared to CD-fed controls (Fig. 1c, Supplementary Figure 1b-c). Similarly, blood glucose clearance, evaluated by oral glucose tolerance test (OGTT), was altered, characterized by higher baseline and peak glycaemia and significantly upper area under the curve (AUC), in HFD-fed mice (Supplementary Figure 1d-e). Finally, HFD-fed mice displayed higher hepatic triglycerides compared to CD (Supplementary Figure 1f).
To better determine whether higher density of B. wadsworthia affects metabolic functions, B. wadsworthia was deliberately given to the mice by intragastric gavage. This protocol induced a higher and stable intestinal level of B. wadsworthia (Fig. 1d–f). Interestingly, CD-fed mice gavaged with B. wadsworthia similarly showed higher and stable level of B. wadsworthia but B. wadsworthia fecal abundance was still significantly higher in HFD-fed mice (Supplementary Figure 2). These results underscored that HFD is not necessary for B. wadsworthia to thrive in the host intestine; however, it is essential for the sustained higher levels of B. wadsworthia. We thus generated two animal models: (1) mice harboring low B. wadsworthia (HFD) and (2) mice harboring high-density levels of B. wadsworthia (HFDBw+). Using these models, we were able to discriminate the relevance of B. wadsworthia abundance in metabolic host function.
B. wadsworthia aggravates HFD-induced metabolic impairments
To determine the consequence of B. wadsworthia abundance on host metabolic status, metabolic parameters were evaluated in mice after a period of HFD feeding. We did not observe significant differences in weight gain between HFD mice harboring low or high B. wadsworthia abundance (Fig. 2a). Similarly, no significant differences in weekly food intake were observed among HFD-fed groups (Supplementary Figure 3a). Glucose clearance, as assessed by OGTT as well as insulin level and HOMA-IR were not affected by increased B. wadsworthia abundance in HFD-fed mice (Fig. 2b–d). However, HFDBw+ mice showed higher fasting glucose compared to HFD group (Fig. 2e). Furthermore, a strong positive correlation between fasting glucose and B. wadsworthia load in the caecum was observed (Fig. 2f).
Elevated serum liver enzymes, hepatic steatosis as well as cholesterol levels are commonly observed in obese individuals13. Significant increase in serum concentrations of aspartate transaminase (AST) and alanine transaminase (ALT) were observed in all HFD groups compared to CD-fed mice, but there was no significant difference between HFD and HFDBw+ groups (Supplementary Figure 3c–d). Similarly, all HFD-fed mice, regardless of treatment, have significantly elevated levels of total cholesterol and HDL in the plasma (Supplementary Figure 3e–f). On the other hand, analysis of liver histology revealed that hepatic lipid content was significantly increased in HFDBw+ group (Fig. 2g, h). In parallel, total hepatic triglyceride was significantly higher in HFDBw+ group than HFD (Fig. 2i), showing that B. wadsworthia has detrimental effects on this metabolic feature. Taken together, these results showed that the high abundance of B. wadsworthia potentiates specific HFD-induced host metabolic syndrome, with notable dysregulation of glucose homeostasis and liver function.
L. rhamnosus CNCM I-3690 prevents B. wadsworthia expansion
Having established a robust murine model of HFD-driven metabolic syndrome with stable and high levels of B. wadsworthia and the consequence of B. wadsworthia abundance on metabolic syndrome pathogenesis, we tested the therapeutic potential of the L. rhamnosus CNCM I-3690 strain in this model. Daily oral gavage of L. rhamnosus CNCM I-3690 (Lr) induced a significant decrease in fecal B. wadsworthia load (Fig. 1a–c). Similarly, L. rhamnosus CNCM I-3690 was able to further reduce B. wadsworthia expansion in caecum and small intestine.
We then determined whether preventing B. wadsworthia expansion by L. rhamnosus CNCM I-3690 has host metabolic consequences. L. rhamnosus CNCM I-3690 did not affect weight gain and food intake in HFD and in HFDBw+ mice (Fig. 2a; Supplementary Figure 3a). L. rhamnosus treated HFDBw+ mice (HFDBw+Lr+) showed reduced fasting glucose level, plasma insulin and HOMA-IR response (Fig. 2d, e, Supplementary Figure 3b). OGTT further revealed that HFDBw+Lr+ mice tended (AUC of OGTT p = 0.0582) to control glucose level better than HFDBw+ (Fig. 2b). L. rhamnosus CNCM I-3690 did not have any effect on glycemic control in HFD group with lower B. wadsworthia level (Supplementary Figure 4a, d–e) but it corrected the effect of HFD on insulin level (Supplementary Figure 4b), suggesting that in addition to suppressing B. wadsworthia-related metabolic dysfunctions by preventing its expansion in vivo, it also improves metabolic function by its inherent ability to modulate insulin level.
HFD feeding modulates microbiota composition
HFD had been consistently shown to modulate intestinal microbial community; thus, we evaluated the global microbiota changes induced by the HFD diet as well as the microbiota effect of inoculating the mice with B. wadsworthia and L. rhamnosus CNCM I-3690 using 16s rRNA-based high throughput sequencing technique. Regardless of treatment, fecal microbiota of CD group clustered differently from mice fed with HFD (Fig. 3a), highlighting a dominant effect of diet (Anosim, 9999 permutations, p = 0.0001). Compared to CD, HFD-fed mice had lower abundance of bacteria belonging to the genera Ruminococcus, Bifidobacterium and Parabacteroides and of Akkermansia muciniphila species (Fig. 3b, c). On the other hand, higher abundance of bacteria under Dorea and Sutterella genera and Ruminococcus gnavus species was observed in HFD-fed mice. Inoculating mice with B. wadsworthia did not induce major changes in microbiota composition in HFD-fed mice (Fig. 3a), although an increase in abundance of Akkermansia and Bifidobacterium genera was observed in HFDBw+ group (Supplementary Figure 5a). Similarly, L. rhamnosus CNCM I-3690, did not induce significant changes in microbiota composition; however, as expected, an increase abundance in an OTU related to L. rhamnosus was observed in HFDBw+Lr+ group (Supplementary Figure 5b). No significant differences in alpha diversity were observed among groups as measured by observed species, Chao1 and Shannon indexes (Fig. 3d and Supplementary Figure 5c). Overall, these data showed that HFD has a significant impact on microbiota composition but the effect of B. wadsworthia and L. rhamnosus CNCM I-3690 on the microbiota composition, assessed by 16S-based approach, was limited and may be more relevant at the metabolic functional level.
B. wadsworthia modulates host and microbial transcriptomics
To explore the interplay between B. wadsworthia, host metabolism, gut microbiota and L. rhamnosus CNCM I-3690, we chose to work in a controlled microbiota environment, that is a gnotobiotic mice colonized with the eight species of the so-called altered Schaedler flora (ASF)14. We further exploited this system by conducting a comprehensive transcriptomic analysis on both the host and bacterial genes. Germ-free mice were colonized with ASF, and then maintained on either CD or HFD. ASF-colonized mice were then inoculated with B. wadsworthia and treated with (HFD-ASFBw+Lr+) or without L. rhamnosus CNCM I-3690 (HFD-ASFBw+). B. wadsworthia colonization was confirmed by measuring B. wadsworthia density in the caecum (Fig. 4a).
Host (caecum) transcriptomics analysis identified many differentially regulated transcripts in HFD compared to CD fed mice. In HFD-ASF mice, expression of 302 genes was significantly altered compared to CD-ASF mice (Supplementary data 1) whereas this number reached 1630 genes in HFD-ASFBw+ mice demonstrating stronger gene modulation. Compared to HFD-ASF mice, HFD-ASFBw+ exhibited an activation in many pathways involved in inflammation and immune response and a marked alteration in fat and glucose metabolism and regulation. Notably Type II diabetes mellitus and Insulin signaling pathways were respectively over-activated and under-activated (Fig. 4b, Supplementary data 2). These alterations were largely reversed in HFD-ASFBw+Lr+ with correction of most of the altered pathway activation seen in HFD-ASFBw+ mice (Fig. 4b, Supplementary data 2). To confirm these results, we measured cytokines at the protein level in mesenteric lymph nodes (MLN), spleen and caecum and showed that, IFN-γ and IL-6 production were consistently higher in tissues of HFD-ASFBw+ mice compared to other groups and L. rhamnosus CNCM I-3690 reversed this phenotype (Fig. 4c).
In parallel, we analyzed in the same animals the functional activity of ASF microbiota, B. wadsworthia and L. rhamnosus CNCM I-3690 using metatrancriptomics strategy and RNAseq technology (Fig. 5a, and Supplementary data 3). The global microbiota activity of HFD-ASF mice was dysregulated with increased activity in sugar interconversions pathways and decreased activity in nitrogen metabolism pathway. Microbial gene expression in all HFD-fed mice colonized with B. wadsworthia showed strong alteration with notably significantly higher activation of Lipopolysaccharide (LPS) biosynthesis and Taurine metabolism pathways while many pathways involving amino acid, sugar, starch, and nitrogen metabolism were significantly reduced. To further evaluate whether the increased LPS production at the microbiota expression level have physiological relevance to the host, we measured serum soluble CD14 (sCD14), a component of the LPS-sensing machinery used as a surrogate marker for LPS concentration in the periphery, and found significantly higher sCD14 in HFD-ASFBw+ mice (Fig. 5b).
Finally, compared to other groups, only HFD-ASFBw+ mice showed decreased activation of Butanoate (butyrate) metabolism pathway, an alteration reverted in HFD-ASFBw+ treated with L. rhamnosus CNCM I-3690. We further confirmed this last result by measuring the fecal concentration of SCFA. A strong tendency (p = 0.0593) for reduced butyrate concentration was observed in HFD-ASFBw+ compared to HFD-ASF. Moreover, HFD-ASFBw+Lr+ mice showed significantly higher butyrate compared to HFD-ASFBw+ (Fig. 5c). Interestingly, HFD-ASFBw+ also showed lower fecal propionate concentration compared to HFD-ASFBw+Lr group (Fig. 5d).
Taken together, these results showed that B. wadsworthia acts on both host and microbiota by worsening HFD-induced intestinal inflammation, inhibiting pathways involved in metabolic homeostasis, favoring increased LPS production and translocation, and decreasing butyrate production by the microbiota. Most of these B. wadsworthia-associated alterations were fully or partly reversed by L. rhamnosus CNCM I-3690 administration.
B. wadsworthia enhances HFD-induced bile acid dysmetabolism
Our host transcriptomic data revealed that B. wadsworthia modulates a number of genes involved in taurine metabolism, which is linked with bile acid homeostasis. Bile acids are increasingly recognized as important signaling factors and regulators of metabolism15,16. As such, we investigated the bile acid profile of mice harboring complex microbiota. Indeed, we found that HFD feeding leads to changes in bile acid composition in the caecum; these alterations were characterized by significantly higher total bile acids and elevated primary bile acids conjugates, as opposed to secondary conjugates (Fig. 6a–c). Furthermore, cecal bile acids of mice fed with HFD showed decreased proportion of bile acids such as DCA and HDCA. B. wadsworthia tends to further dysregulate bile acid composition in the caecum with higher levels of taurocholic acid (TCA), a taurine-conjugated bile acid, as well as other bile acids such as UDCA and MCA-β. Furthermore, in the serum of HFD-fed mice, taurine conjugated bile acid concentration was more than 100-fold higher compared to CD, with an even stronger increase in HFDBw+ group (Fig. 6d, e). In contrast, HFDBw+Lr+ showed lower total and taurine-conjugated bile acids compared to HFDBw+, suggesting the efficiency of L. rhamnosus CNCM I-3690 to reverse the effect of HFD and B. wadsworthia on bile acids.
L. rhamnosus CNCM I-3690 reverts B. wadsworthia host dysfunction
Based on our simplified microbiota studies, the presence of B. wadsworthia downregulated the production of SCFA and upregulated the global synthesis of LPS by the intestinal microbial communities and was further associated with higher systemic LPS. Guided by these results, we similarly assessed the SCFA concentration in caecum and the LPS availability in the systemic compartment in our HFD conventional mice model. In accordance with the results obtained from ASF-colonized mice, butyrate concentration tended to be lower in the caecum of HFDBw+ than in HFD mice and L. rhamnosus CNCM I-3690 was associated with a higher level of butyrate and propionate (Fig. 7a, b). Similarly, serum sCD14 level was significantly higher in HFDBw+ than in HFD mice, but L. rhamnosus CNCM I-3690 did not reverse this phenotype (Fig. 7c).
Intestinal barrier dysfunction is an important feature in obesity and metabolic syndrome17. We hypothesized that this parameter may underlie the increased systemic bioavailability of LPS. Thus, we assessed intestinal permeability using a classical permeability marker FITC-dextran. HFDBw+ mice exhibited increased intestinal permeability as demonstrated by higher serum FITC-dextran levels following oral gavage (Fig. 7d). Intestinal permeability was dampened by L. rhamnosus CNCM I-3690 in HFDBw+ but not HFD (Fig. 7d, Supplementary Figure 6a), suggesting this phenotype is modulated by L. rhamnosus through regulation of B. wadsworthia abundance. Overall, these results show that the increased B. wadsworthia abundance augments the impact of HFD-induced gut barrier alterations and L. rhamnosus CNCM I-3690 partially reverse this effect.
Disruption of the gut barrier may allow increased intestinal permeability to bacterial endotoxins, such as LPS, and in turn may increase mucosal inflammation and lead to systemic inflammation. Hence, we next examined whether B. wadsworthia further exacerbates HFD-induced inflammatory response in conventional mice. We first characterized the state of mucosal inflammation by quantifying lipocalin-2 levels in the feces on different time-points during the experiment (Fig. 7e). HFD feeding tended to show higher levels of lipocalin-2 in the feces compared to CD but this was further and significantly increased in HFDBw+ mice, particularly at week 7 and 9. Cytokine levels in MLN, ileum and jejunum of HFDBw+ were similarly higher compared to either CD or HFD or both groups, underscoring a state of heightened mucosal inflammation in HFDBw+ group (Fig. 7f–h). L. rhamnosus CNCM I-3690 treatment was able to dampen some of these responses, particularly for fecal lipocalin-2 levels, TNF-α and IFN-γ in HFDBw+ but not in HFD group (Fig. 7e–h, Supplementary Figure 6b).
We further assessed the state of systemic inflammation and observed a similar pattern with significantly increased production of several pro-inflammatory cytokines such as IFN-γ, TNF-α and IL-6 in the spleen and liver of HFDBw+ mice (Fig. 7i, j). Similar to mucosal immune response, L. rhamnosus CNCM I-3690 treated mice displayed a cytokine pattern closer to the control groups, suggesting its ability to dampen the pro-inflammatory effect of B. wadsworthia. All together, these results showed that B. wadsworthia synergizes with HFD in inducing higher states of systemic and mucosal inflammation, which can be at least partly reversed by L. rhamnosus CNCM I-3690.
B. wadsworthia’s inflammation-independent modulating properties
In accordance with previous study5, we observed that B. wadsworthia possessed inherent pro-inflammatory properties; however, it remains unknown at what extent this B. wadsworthia feature plays a role in development of host metabolic impairment. Inflammation is an important feature of metabolic syndrome; consequently, it is also unclear whether B. wadsworthia-associated metabolic impairments are just secondary to B. wadsworthia-driven inflammation. To address these questions, inflammation in HFD-fed mice was suppressed using a broadly used immunosuppressant, ciclosporine. Cytokine analysis in spleen, MLN and intestine as well as Lipocalin-2 level in stools showed that ciclosporine (Ci) effectively abrogated the inflammatory response in HFD-fed mice, regardless whether they harbor low or high-density B. wadsworthia (Fig. 8a, b; Supplementary Figure 7a–c). Thus, by normalizing the inflammatory state between the HFD-Ci and HFD-CiBw+, potential interference of inflammation can be eliminated and direct metabolic effect of B. wadsworthia can be clearly inferred.
No difference in B. wadsworthia density was observed between ciclosporine treated and untreated HFDBw+, ruling out any direct effect of ciclosporine treatment on B. wadsworthia (Fig. 8c). Ciclosporine treated HFD and HFDBw+ mice showed significantly less weight gain compared to non-treated mice, underscoring the importance of inflammation in promoting weight gain (Fig. 8d). Regardless of weight change however, ciclosporine did not affect fasting glucose, insulin and HOMA-IR in HFD-fed mice (Fig. 8e–g). However, HFDBw+ mice treated with ciclosporine showed significantly elevated fasting insulin and this was associated with a strong tendency (p = 0.0576) for higher HOMA scores. OGTT further showed that ciclosporine-treated HFD-fed mice tend to exhibit improved glucose tolerance compared to non-treated mice; but HFDBw+ mice still had worse glucose tolerance, as evidenced by higher glycemic level 15 min following oral challenge and significantly higher AUC, compared to HFD mice (Fig. 8h, i).
In terms of hepatic effect, ciclosporine did not seem to significantly dampen hepatic steatosis in both HFD (Fig. 8j, k). Although, there was a tendency (p = 0.0728) for HFD-CiBw+ to have lower steatosis compared to HFDBw+ group. Nonetheless, the difference in steatosis between HFD and HFDBw+ remains significant regardless of ciclosporine treatment. Altogether, these results showed that the pro-inflammatory effects of B. wadsworthia partly mask its negative metabolic effects. Moreover, B. wadsworthia exhibits negative intrinsic metabolic effect independently of inflammation.
HFD had been consistently associated with increased abundance of B. wadsworthia, a bacterium implicated in increased colitis severity of Il-10-/- mice5. However, the impact of B. wadsworthia on non-genetically susceptible host, and whether and how its expansion could promote an impaired metabolic function remains poorly understood. Here, we utilized a hypothesis-driven approach, using a combination of host trancriptomics, metatrancriptomics and gnotobiotic techniques, to dissect how B. wadsworthia is able to modulate host metabolic response to HFD. We then tested our hypotheses in conventional HFD murine model. Our results showed that, beside intestinal pro-inflammatory effects, B. wadsworthia promotes intestinal barrier defect, systemic inflammation, bile acid dysmetabolism and changes in microbiome functional profile, leading to the worsening of HFD-induced metabolic effects. Moreover, we showed that L. rhamnosus CNCM I-3960 was able to inhibit most of the B. wadsworthia-driven host metabolic and inflammatory impairments.
To determine the mechanistic basis by which B. wadsworthia impacts host metabolism and how L. rhamnosus CNCM I-3690 attenuates these effects, we performed transcriptomic analysis on both the host and microbiota. To fully understand the system, we chose to work in a controlled microbiota environment, wherein bacterial and host function can be inferred to a specific microbe or condition. Among the gene pathways that were significantly modulated by the presence of B. wadsworthia are those involved in bile acid metabolism. Bile acids are synthesized from cholesterol. In the liver, taurine, along with glycine, are used to conjugate bile acids to produce primary bile acids. Bile acids undergo enterohepatic circulation, which includes circulating in the intestine where primary bile acids are further deconjugated and converted into secondary bile acids by the microbiota. Saturated animal-derived fats had been previously shown to promote the production of taurine conjugated bile acids, such as taurocholic acid (TCA)2,5. In this study, we observed that HFD significantly upregulates intestinal genes involved in the metabolism of taurine with increased concentration of taurine conjugated bile acids and decreased proportion of secondary bile acids in the caecum. B. wadsworthia further aggravates the bile acid deregulation in HFD context and this can be alleviated by L. rhamnosus CNCM I-3690 treatment. This is important as secondary bile acids have an important negative feedback role in decreasing bile acid synthesis;15 hence, the increased total serum and caecum bile acids in HFDBw+ group may be compounded by the decreased negative feedback signaling due to lower proportion of secondary bile acids. Additionally, unlike conjugated bile acids, unconjugated bile acids, such as cholic acid and chenodeoxycholic acid, are strong agonist for bile acid receptors, including Farnesoid X receptor and transmembrane G protein-coupled receptor;16 signaling through these receptors activates transcriptional networks and signaling cascades relevant for cholesterol and lipid metabolism, maintenance of glucose and hepatic homeostasis, as well as genes involved in suppressing inflammation and strengthening intestinal barrier function15,18. Moreover, the pro-inflammatory properties of primary bile acids had been described19,20. Altogether, these data suggest that B. wadsworthia’s impact on bile acid metabolism may be one mechanism by which the bacterium potentiates HFD-induced metabolic impairment and host dysfunctions, particularly inflammation and barrier dysfunction.
How the presence of B. wadsworthia leads to a disproportionate level of bile acids remains an open question, but it is possible that B. wadsworthia has an inherent ability to drive the production of primary acid, particularly TCA, for its own advantage. Indeed, it had been previously shown that B. wadsworthia expands in the presence of taurine conjugated bile acids, especially TCA5. Similarly, we observed that B. wadsworthia grow in vitro ten times more in the presence of 1% taurine (Supplementary Figure 8). Thus, in conjunction with previous results, this suggests that taurine and its derivatives, particularly TCA, may not be necessary for B. wadsworthia’s survival but are essential for its increased fitness and growth.
Our metatranscriptomics studies revealed also that LPS synthesis pathway was highly upregulated in HFDBw+ mice microbiota. This was paralleled by higher LPS translocation, which may at least partly explain the increased systemic inflammatory response we observed in HFDBw+, both in ASF-colonized and conventional mice. L. rhamnosus CNCM I-3690 may be reducing the pro-inflammatory phenotype in HFDBw+ mice by decreasing the abundance of B. wadsworthia, and also by decreasing the bioavailability of LPS in the systemic circulation and/or through its intrinsic anti-inflammatory effects that had been previously demonstrated in other murine models11. Although L. rhamnosus CNCM I-3690 was efficient in decreasing inflammatory markers and intestinal permeability in HFDBw+, it was ineffective in decreasing these phenotypes in HFD mice, highlighting that L. rhamnosus CNCM I-3690 acts through B. wadsworthia modulation in this setting.
In addition to LPS synthesis, the presence of B. wadsworthia induced a decreased expression of microbial genes involved in butanoate metabolism in ASF-colonized mice. Furthermore, the decreased production of butyrate was confirmed by dosage in colon lumen of the mice. Aside from its effect in modulating inflammatory response21, butyrate had been shown enhance intestinal epithelial barrier by assembly of tight junctions22,23. Furthermore, dietary supplementation with butyrate had been previously shown to confer preventive and therapeutic benefits in animal model of obesity and insulin resistance24. Interestingly, L. rhamnosus strains had been shown to be efficient in compensating butyrate deficiency and enhance intestinal barrier11,25, thereby providing another potential mechanism of action of L. rhamnosus.
We showed that B. wadsworthia increased HFD-induced metabolic syndrome, which is a condition often associated with low degree of systemic inflammation26. At the same time, B. wadsworthia had been demonstrated to exacerbate intestinal inflammation in genetically susceptible mice5 and also to induce systemic inflammation in wild type animals27. Higher state of inflammation is characterized by wasting and weight loss while metabolic syndrome is characterized by low grade inflammation and higher body mass index. Thus, a key question is how can B. wadworthia affect both opposing pathologies. Moreover, the contribution and relative importance of B. wadworthia’s pro-inflammatory properties in disturbing host metabolic status in HFD setting is unknown. By pharmacologically suppressing the inflammation, we unmasked the capacity of B. wadsworthia to directly induce a negative impact on host metabolic function. Specifically, we were able to discriminate distinct metabolic impairments, namely reduced glucose clearance and fatty liver phenotype, influenced by B. wadworthia that do not completely rely on its pro-inflammatory properties. Nonetheless, B. wadworthia-driven inflammation remains an important factor that further tip the balance to stronger metabolic dysfunctions. Accordingly, this may explain why B. wadworthia is able to play a pathological role on two contrasting settings. It is also important to note that although we showed in this study that B. wadsworthia promoted heightened immune response, this did not translate to patent colitis development compared to previous reports5. This might be due to the fact that our murine model is not a genetically susceptible host, and therefore have intact compensatory mechanism that prevents the development of overt intestinal inflammation. Hence, B. wadsworthia’s effect on metabolic function in our system outweighs its effect on development of overt inflammation due to lack of additional stimuli. As a result, the phenotype we achieved is a model by which B. wadsworthia potentiates the deleterious effect of HFD on host metabolic homeostasis. Taken all together, the effect of B. wadsworthia to the host can be pleiotropic, but the combination of genetics, host and environmental factors ultimately dictate the degree of inflammation and type of pathologies B. wadworthia will exacerbate or influence.
Overall, we demonstrated that B. wadworthia augments some of the deleterious host metabolic effects of HFD by modifying multiple targets: altering the functional potential of intestinal microbes, promoting higher intestinal permeability, development of heightened immune response both at mucosal and systemic level, and disproportionate bile acid concentrations. All these pathways ultimately converge to further disturb the host metabolic function in HFD setting (Supplementary Figure 8). Importantly, we also unraveled that B. wadsworthia, independent of its pro-inflammatory properties, has the capacity to negatively affect glucose and hepatic homeostasis. These results suggest that the carriage of high levels of Bilophila species or strains might modulate the susceptibility to not only inflammatory but also metabolic diseases. Collectively, our study provides a conceptual framework to further test this hypothesis in human and warrants the evaluation of preventative strategies, such as probiotics use, to suppress the expansion of Bilophila.
For conventional experiment, male C57BL/6J mice were purchased from Janvier (France) and used after 1 week of receipt. Mice at 5 weeks of age were fed ad libitum with purified control diet (CD, Envigo TD.120508) or high fat diet (HFD, 38% fat, dominantly milk fat, Envigo TD.97222) for 9 weeks. For deliberate B. wadsworthia inoculation, after maintaining the mice in HFD or CD for 2 weeks, mice were inoculated via oral gavage with ~107 CFU of B. wadsworthia ATCC 49260 suspended in 200 μl of medium (Bacteroides bile esculin with 1% Taurine and 0.5 mg/ml cysteine) or medium alone for three consecutive days. For L. rhamnosus CNCM I-3690 treatment, 1 week after the last B. wadsworthia inoculation, mice were gavaged daily with 109 CFU of L. rhamnosus CNCM I-3690 suspended in 200 μl of vehicle (phosphate buffer saline with 15% glycerol) or vehicle for 5 weeks. For ciclosporine experiment, 1 week after the last B. wadsworthia inoculation, mice were injected i.p. with ciclosporine (25 mg/kg; Sandimmum Novartis) or vehicle (PBS) 3x a week for 5 weeks.
For altered Schaedler flora (ASF) experiment, male C57BL/6J germ-free (GF) mice were obtained from Transgenese et Archivage Animaux Modeles (CNRS, UPS44, Orleans, France) and used after 1 week of receipt. Sterility was confirmed microscopically and by microbiological technique. ASF colonized mice were kindly provided by E. Verdu from McMaster University (Canada). Fresh cecal samples from ASF-colonized mice were suspended and diluted in pre-reduced sterile 0.9% NaCl with 15% glycerol (1 g in 10 ml) under anaerobic condition. Aliquots of ASF cecal suspension were stored at −80 °C. GF mice (5 weeks of age) were inoculated via oral gavage with 200 μl of ASF cecal suspension and maintained on either HFD or CD. 3 weeks after ASF inoculation, mice were orally gavaged with B. wadsworthia or medium for 3 consecutive days. 1 week after the last B. wadsworthia inoculation, mice were gavaged daily with 109 CFU of L. rhamnosus CNCM I-3690 or vehicle for 4 weeks. ASF mice were housed in isolator for the whole experiment.
Weekly food consumption was measured cage-wise. Mice were fasted for 6 h prior to sacrifice and then put to sleep using isoflurane. Mice were culled by cervical dislocation and appropriate tissues were harvested. All experiments were performed in accordance with the French animal experimental committee (Comite d’Ethique en Experimentation Animale).
Oral glucose tolerance test
Oral glucose tolerance test was performed 3–5 days before the sacrifice. Mice were fasted by removing the food and bedding 1 h before the onset of light cycle. After 6 h of fasting, glucose solution (2 g/kg) was administered by oral gavage. Blood glucose level at time 0 (fasting glucose, taken before glucose gavage) and at 15, 30, 60, and 120 min after glucose gavage was analyzed using OneTouch glucometer (Roche). Glucose level was plotted against time and areas under the glucose curve (AUC) were calculated by following trapezoidal rule. Plasma insulin concentration (collected in EDTA-coated tubes) at time 0 (fasting insulin) and 30 was analyzed from tail vein blood (collected in EDTA-coated tubes) using ultra sensitive mouse insulin ELISA kit (Alpco). Homeostatic model assessment of insulin resistance (HOMA-IR) was calculated according to the formula: fasting glucose (nmol/L) x fasting insulin (microU/L)/22.5.
Measurements of plasma parameters
Blood samples were collected in heparin-coated tubes via cardiac puncture, centrifuged and then plasma samples were stored at −80 °C. Plasma cholesterol, triglycerides, high-density lipoprotein (HDL), aspartate transaminase (AST) and alanine transaminase (ALT) measurement were performed by the Biochemistry Platform (CRI, UMR 1149, Paris) using Olympus AU400 Chemistry Analyzer.
Measurements of bile acids
Measurement of bile acids (BA) composition and concentration in plasma and intestinal contents was performed by the Chemistry department at Saint Antoine Hospital (UMR 7203, France) using high performance liquid chromatography (HPLC, Agilent 1100, France) coupled in series with mass spectrometer (QTRAP 2000, Canada)20.
Measurements of SCFA
Measurement of the short-chain fatty acids (SCFA) from fecal content was performed by the mass spectrometer platform at Universite de Nantes (IRS-UN, France) using gas chromatography coupled with mass spectrometry28.
Quantification of cytokines
Single cell suspensions from MLN and spleen were isolated by smashing the cells in 70 μm mesh. 1 × 106 cells were plated in 24 well-plate and then stimulated with phorbol 12-myristate 13-acetate (PMA, 50 ng/mL; Sigma-Aldrich) and ionomycin (1 µM; Sigma Aldrich) for 48 h at 37 °C. Supernatants were collected and used for cytokine analysis.
Fifty milligram of intestinal tissues and liver samples were suspended in T-PER Tissue Protein Extraction Reagent (Thermo Scientific) and homogenized suing FastPrep (6 m/s in 40 s). Homogenates were centrifuged and supernatants were used for cytokine and total protein concentration analysis. Total protein concentration of the tissue homogenates were analyzed using Pierce BCA Protein Assay Kit (Thermo Scientific). Cytokine concentrations were normalized according to the measured protein concentration.
Cytokines were measured using Legendplex Mouse Inflammation Panel (Biolegend) or individual ELISA kit (R&D Mouse DuoSet IL-6; Mabtech IFN-γ, IL-17a ELISA kits; Ebioscience TNF-α ELISA kit).
Liver histology and hepatic triglycerides measurement
A slice of left lobe of the liver was fixed in 4% PFA for 48 h and then transferred to ethanol, fixed in paraffin, trimmed, processed, sectioned into slices approximately 3 μm thick, mounted on a glass slide and stained with hematoxylin and eosin (H&E). Hepatic lipids were evaluated by quantifying the % lipid area using the software ImageJ29.
In vivo intestinal permeability and plasma sCD14
In vivo assay of intestinal barrier function was performed using fluorescein-conjugated dextran (FITC-dextran, 3–5kDA) method, as previously described30. Briefly, on the day of sacrifice, FITC-dextran (0.6 mg/g of body weight) was administered to the mice by oral gavage and 3 h later, blood samples were collected in heparin-coated tubes. Fluorescence intensity was measured in the plasma using a microplate reader (Tecan). Plasma concentration of soluble CD14 (sCD14) was measured using CD14 ELISA kit (R&D).
Quantification of fecal LCN2
Frozen fecal samples were weighed and reconstituted in cold PBS. Samples were then agitated on a FastPrep bead beater machine for 40 s at setting 6 using 4.5 mm glass beads to obtain homogenous fecal suspension. Samples were then centrifuged for 5 min at 10,000×g (4 °C) and clear supernatants were collected and stored at −20 °C until analysis. LCN2 levels were estimated using Duoset murine LCN2 Elisa Kit (R&D) as per manufacturer’s instructions and expressed as pg/mg of stool.
DNA extraction and bacterial quantification
Fecal, cecal and small intestinal content genomic DNA was extracted from the weighted stool samples using a method that was previously described31, which is based on the Godon DNA extraction method. Quantifications of all bacteria and B. wadsworthia were performed by qPCR using TaqMan Gene Expression Assays (Life technologies) and Takyon SYBR Green PCR kit (Eurogentec). All bacteria was quantified using the following oligonucleotides: (sense) 5′-CGGTGAATACGTTCCCGG-3′ and (antisense) 5′-TACGGCTACCTTGTTACGACTT-3′ and (probe) 5′-CTTGTACACACCGCCCGTC-3′. B. wadsworthia was quantified using specific primers for the tpa gene (accession no. AF269146): (sense) 5′-CGCCGGTATCGAAATCGTGA-3′ and (antisense) 5′-ATTCGCGGAAGGAGCGAGAG-3′. Sulfite-reducing bacteria were quantified using specific primers for the dsra gene (encoding a dissimilatory sulfite reductase alpha subunit) as described by Devkota5.
16s rRNA gene sequencing
16s rRNA gene sequencing of fecal DNA samples (collected at week 9 of CD or HFD) was performed as previously described31. Briefly, the V3-V4 region was amplified and sequencing was done using an Illumina MiSeq platform (Illumina). Sequencing data were analyzed using the quantitative insights into microbial ecology (QIIME 1.9.1) software package. Sequences were clustered into operational taxonomic unites (OTU) at a 97% identity threshold using a closed-reference picking approach with UCLUST against the Greengenes reference database (version 13.5) and phylogenetic tree was built using FastTree. Rarefaction was performed (13,000 sequences per sample) and used to compare abundance of OTUs across samples. Alpha-diversity was estimated using both richness and evenness indexes (Chao1, Shannon or number of observed species). Beta-diversity was measured Bray Curtis distance matrix and was used to build principal coordinates analysis (PCoA) plots. Linear discriminant analysis (LDA) effect size (LEfSe) algorithm was used to identify taxa that are specific to diet and/or treatment. Sequencing data are deposited in European Nucleotide Archive (ENA) under the accession number PRJEB25364.
Mouse gene expression and microarray analysis
Total RNA was isolated from the caecum of ASF-colonized mice using RNeasy Mini Kit, according to manufacturer’s instructions. The RNA integrity was verified in Bioanalyzer 2100 with RNA 6000 Nano chips (Agilent Technologies). Only samples that have RNA integrity >9 were used for the study. Mouse transcriptomics was performed using SurePrint G3 Mouse GE 8x60K Microarray (Design ID: 028005, Agilent Technologies), according to manufacturer’s instructions. Microarray data are deposited in GEO under the accession number GSE111451 [https://www-ncbi-nlm-nih-gov.gate2.inist.fr/geo/query/acc.cgi?acc=GSE111451].
Microarray data processing and analysis was performed as previously described28. Briefly, Agilent Feature Extraction Software v10.7.3.1 was used to convert scanned signal into tab-delimited text files. p-value for each probe in each array was computed to test whether the scanned signal is significantly higher than background signal. Probes were filtered according to two criteria: only probes with p-value lower than 0.05 were considered and present in at least 60% of arrays in at last one biological groups. Signals were then log2 transformed, normalized according to quantiles method, corrected for batch effect using ComBat method32 with covariate and Agilent’s probes ID were mapped to EntrezGeneID for further analysis. Differential analysis was performed using empirical Bayesian test (eBayes). Beside of analyzing of significant differentially expressed genes, we applied the functional class scoring (FCS) method “Pathway Level Analysis of Gene Expression (PLAGE, embedded in the GSVA R package)”33 to quantify the level of activity of each KEGG pathway in each sample and utilized empirical Bayes test to compare for the differentially enrichment between biological groups. Significant terms were selected at Benjamini-Hochberg’s method corrected p-value lower than 0.05.
Microbial gene expression and RNA-sequencing analysis
Total bacterial RNA from cecal content was extracted by mechanic bead-beating lysis method combined with phenol/choloroform RNA extraction method. Briefly, cecal content was suspended in 200 μl of RNAse free water and then 250 μl phenol (pH 4.8)/chloroform-isoamyalcohol mixture (5:1 ratio), 12.5 μl of SDS (20%), 25 μl NaAc (3 M, pH 8) were added to the suspension. Cecal content suspension was then agitated on a FastPrep bead beater machine for 40 s at setting 5 followed by 60 s in ice for another round of bead beating for 20 s at setting 5. After lysis, the upper phase of the suspension was collected after 15 min of centrifugation at 13,000×g (4 °C). Traces of phenol were eliminated by adding 250 μl of chloroforme-isoamylalchohol and then collecting the upper phase after 10 min of centrifugation. Bacterial RNA was then purified using High Pure RNA Isolation Kit (Roche), as per manufacturer’s instructions. Total RNA concentration and integrity was determined using a Bioanalyzer 2100 (Agilent).
Library preparation and RNA-sequencing was performed by the High-throughput Sequencing Platform of I2BC. Total bacterial RNA were purified using RiboZero. Library was sequenced using NextSeq 500 on the single lane 75 bp paired-end mode.
Metatranscriptomics data processing and analysis was performed by first trimming unmapped reads and then were aligned using Bowtie2 aligner34 to genome sequences retrieved form NCBI RefSeq database except for L. rhamnosus CNCM I-3690, which was mapped using a genome generated from Danone Nutricia. Mapped reads was quality filtered and only reads with MAPQ ≥ 5 was used. Reads were counted against transcript features database (General Feature Format (GFF) files from NCBI RefSeq database except for L. rhamnosus CNCM I-3690 which was predicted using Prokka v1.12b) using the mode “union”. Count data was further filtered using the following criteria: genes with 0 read across all samples and genes with <1 count per million were excluded. For visualization, count data was transformed using Variance Modeling at the Observation Level (voom method)35 and then normalized by quantile method. Differential analysis was performed using the exact tests for differences between two groups of negative binomial counts programmed in the R package “edgeR”36. All the significant signatures (up-regulated or down-regulated genes) were annotated for enriched pathways using the package GOstats37. Pathway definition for bacteria was downloaded from PATRIC database. Pathway lists were cleaned to exclude host pathways that were predicted from the same enzyme commission numbers (EC) assigned to both bacteria and host genes. As for host microarray, the method PLAGE was used to compare the pathway activity level between groups. p-values were adjusted using Benjamini-Hochberg’s method to correct for multiple-testing problem. Significant threshold is fixed at alpha = 0.05 (type 1 error). All metatranscriptomics were deposited on GEO repository under the accession number GSE112387 [https://www-ncbi-nlm-nih-gov.gate2.inist.fr/geo/query/acc.cgi?acc=GSE112387].
In each experiment, multiple mice were analyze as biological replicates. No statistical methods were used to predetermine sample size. Sample size was estimated according to previous experience using the models described. No samples, mice or data points were excluded from the reported analysis. Animals were randomly assigned to each experimental groups. All analyses were performed unblinded except the histological analyses. Dot plots with a linear scale show the arithmetic mean. Bar graphs are expressed as mean ± standard error of mean (SEM). Except for 16s rRNA, microarray and RNA-sequencing results, GraphPad Prism version 7.0b was used for all statistical analysis. The Kolmogorov–Smirnov test was used to verify that all data set were normally distributed. For data sets that failed normality, nonparametric tests were used to analyze statistical differences. For comparisons between two groups, significance was determined using two-tailed Student’s t-test or nonparametric Mann–Whitney test. For comparisons among more than two groups, one way analysis of variance (ANOVA) followed by post-hoc Bonferroni test or nonparametric Kruskal-Wallis test followed by post hoc Dunn’s test and two-way ANOVA corrected for multiple comparison with a Bonferroni test were used. An F or Bartlett’s test was performed to determine difference in variances for t-tests and ANOVAs, respectively. An unpaired Student’s t-test with Welch’s correction was applied when variances were not equal. Differences were noted as significant at p ≤ 0.05.
Sequencing data are deposited in European Nucleotide Archive (ENA) under the accession number PRJEB25364. Microarray data are deposited in GEO under the accession number GSE111451. All metatranscriptomics were deposited on GEO repository under the accession number GSE112387. All other data are available from authors.
Sonnenburg, J. L. & Backhed, F. Diet-microbiota interactions as moderators of human metabolism. Nature 535, 56–64, (2016).
David, L. A. et al. Diet rapidly and reproducibly alters the human gut microbiome. Nature 505, 559–563, (2014).
Bernard, D., Verschraegen, G., Claeys, G., Lauwers, S. & Rosseel, P. Bilophila wadsworthia bacteremia in a patient with gangrenous appendicitis. Clin. Infect. Dis. 18, 1023–1024 (1994).
Kasten, M. J., Rosenblatt, J. E. & Gustafson, D. R. Bilophila wadsworthia bacteremia in two patients with hepatic abscesses. J. Clin. Microbiol. 30, 2502–2503 (1992).
Devkota, S. et al. Dietary-fat-induced taurocholic acid promotes pathobiont expansion and colitis in Il10 -/- mice. Nature 487, 104–108 (2012).
Everard, A. et al. Cross-talk between Akkermansia muciniphila and intestinal epithelium controls diet-induced obesity. Proc. Natl Acad. Sci. USA 110, 9066–9071 (2013).
Schneeberger, M. et al. Akkermansia muciniphila inversely correlates with the onset of inflammation, altered adipose tissue metabolism and metabolic disorders during obesity in mice. Sci. Rep. 5, 16643 (2015).
Smith, M. et al. Gut microbiomes of Malawian twin pairs discordant for kwashiorkor. Science 339, 548–554, (2013).
Wu, M. et al. Genetic determinants of in vivo fitness and diet responsiveness in multiple human gut Bacteroides. Science 350, aac5992 (2015).
Wang, J. et al. Modulation of gut microbiota during probiotic-mediated attenuation of metabolic syndrome in high fat diet-fed mice. ISME J. 9, 1–15, (2015).
Laval, L. et al. Lactobacillus rhamnosus CNCM I-3690 and the commensal bacterium Faecalibacterium prausnitzii A2-165 exhibit similar protective effects to induced barrier hyper-permeability in mice. Gut Microbes 6, 1–9 (2015).
Grompone, G. et al. Anti-inflammatory Lactobacillus rhamnosus CNCM I-3690 strain protects against oxidative stress and increases lifespan in Caenorhabditis elegans. PLoS ONE 7, e52493 (2012).
Festi, D. et al. Hepatic steatosis in obese patients: clinical aspects and prognostic significance. Obes. Rev. 5, 27–42 (2004).
Dewhirst, F. E. et al. Phylogeny of the defined murine microbiota: altered Schaedler flora. Appl. Environ. Microbiol. 65, 3287–3292 (1999).
Thomas, C., Pellicciari, R., Pruzanski, M., Auwerx, J. & Schoonjans, K. Targeting bile-acid signalling for metabolic diseases. Nat. Rev. Drug Discov. 7, 678–693, (2008).
Wahlstrom, A., Sayin, S. I., Marschall, H. U. & Backhed, F. Intestinal crosstalk between bile acids and microbiota and its impact on host metabolism. Cell Metab. 24, 41–50, (2016).
Cani, P. D. et al. Changes in gut microbiota control metabolic endotoxemia-induced inflammation in high-fat diet-induced obesity and diabetes in mice. Diabetes 57, 1470–1481, (2008).
Schaap, F. G., Trauner, M. & Jansen, P. L. Bile acid receptors as targets for drug development. Nat. Rev. Gastroenterol. Hepatol. 11, 55–67, (2014).
Duboc, H. et al. Increase in fecal primary bile acids and dysbiosis in patients with diarrhea-predominant irritable bowel syndrome. Neurogastroenterol. Motil. 24, 513–520, (2012). e246-517.
Duboc, H. et al. Connecting dysbiosis, bile-acid dysmetabolism and gut inflammation in inflammatory bowel diseases. Gut 62, 531–539, (2013).
Segain, J. P. et al. Butyrate inhibits inflammatory responses through NFkappaB inhibition: implications for Crohn’s disease. Gut 47, 397–403 (2000).
Peng, L., Li, Z. R., Green, R. S., Holzman, I. R. & Lin, J. Butyrate enhances the intestinal barrier by facilitating tight junction assembly via activation of AMP-activated protein kinase in Caco-2 cell monolayers. J. Nutr. 139, 1619–1625, (2009).
Peng, L., He, Z., Chen, W., Holzman, I. R. & Lin, J. Effects of butyrate on intestinal barrier function in a Caco-2 cell monolayer model of intestinal barrier. Pediatr. Res. 61, 37–41, (2007).
Gao, Z. et al. Butyrate improves insulin sensitivity and increases energy expenditure in mice. Diabetes 58, 1509–1517, (2009).
Ritze, Y. et al. Lactobacillus rhamnosus GG protects against non-alcoholic fatty liver disease in mice. PLoS ONE 9, e80169 (2014).
Hotamisligil, G. S. Inflammation and metabolic disorders. Nature 444, 860–867, (2006).
Feng, Z. et al. A human stool-derived Bilophila wadsworthia strain caused systemic inflammation in specific-pathogen-free mice. Gut Pathog. 9, 59 (2017).
Hoffmann, T. W. et al. Microorganisms linked to inflammatory bowel disease-associated dysbiosis differentially impact host physiology in gnotobiotic mice. ISME J. 10, 460–477, (2016).
Crane, J. D. et al. Inhibiting peripheral serotonin synthesis reduces obesity and metabolic dysfunction by promoting brown adipose tissue thermogenesis. Nat. Med. 21, 166–172, (2015).
Martín, R. et al. Faecalibacterium prausnitziiprevents physiological damages in a chronic low-grade inflammation murine model. BMC Microbiol. 15, 67 (2015).
Lamas, B. et al. CARD9 impacts colitis by altering gut microbiota metabolism of tryptophan into aryl hydrocarbon receptor ligands. Nat. Med. 22, 598–605 (2016).
Johnson, W. E. et al. Adjusting batch effects in microarray expression data using empirical Bayes methods. Biostatistics 8, 118–127 (2007).
Hanzelmann, J. et al. GSVA: gene set variation analysis for microarray and RNA-Seq data. BMC Bioinform. 14, 7 (2013).
Langmead, B. et al. Fast gapped-read alignment with Bowtie 2. Nat. Methods 9, 357–359, (2012).
Law, C. W. et al. voom: precision weights unlock linear model analysis tools for RNA-seq read counts. Genome Biol. 15, R29, (2014).
Robinson, M. D. et al. edgeR: a Bioconductor package for differential expression analysis of digital gene expression data. Bioinformatics 26, 139–140, (2010).
Falcon, S. et al. Using GOstats to test gene lists for GO term association. Bioinformatics 23, 257–258 (2007).
We thank the members of the INRA-Jouy-en-Josas animal facility and the ANAXEM germ-free platform for their assistance with the animal experiments; Dr. Elena Verdu for the ASF samples; Dr. Jean-Marc Chatel for his assistance during the experimental design process with ciclosporine experiments; Julie Riviere and Abdel for their assistance with the histological work, Marjorie Lebarbenchon for technical help. Our work has benefited from the facilities and expertize of the @BRIDGE Histological and Microarray Platform of UMR 1313 GABI, High-throughput Sequencing Platform of I2BC, Biochemistry Platform of UMR 1149 Inflammation Research Center, and IRS-UN Mass Spectrometry Platform of CRNH. J.M.N. holds a fellowship from Canadian Association of Gastroenterology and Canadian Institute of Health Research. This work was supported by a grant in aid from Danone Nutricia Research.
P.V. is a Danone Employee. The remaining authors declare no competing interests.
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Natividad, J.M., Lamas, B., Pham, H.P. et al. Bilophila wadsworthia aggravates high fat diet induced metabolic dysfunctions in mice. Nat Commun 9, 2802 (2018). https://doi.org/10.1038/s41467-018-05249-7
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