Effect of three oral pathogens on the TMA-TMAO metabolic pathway

The oral cavity serves as a significant microbial reservoir within the human body. Studies have established links between oral diseases, especially periodontitis, and various systemic diseases, including cardiovascular diseases (CVD) (Genco and Sanz, 2020), inflammatory bowel disease (IBD) (Kul et al., 2023), non-alcoholic fatty liver disease (NAFLD) (Kuraji et al., 2021), cancer, Alzheimer’s disease (AD) (Lu et al., 2022), and rheumatoid arthritis (RA) (Chan et al., 2019) etc.

Dental plaque is the primary cause of oral diseases (Simon-Soro et al., 2022). Species such as Streptococcus mutans (Sm) are the initial inhabitants of dental plaque, adhering through mechanisms mediated by RadD and other mechanisms (Kolenbrander et al., 2010; Baty et al., 2022). RadD is a protein encoded by the FNP_1046 gene in Fusobacterium nucleatum (Fn), it promotes adhesion by recognizing and binding to partner adhesins on other species, such as SpaP on Sm, as demonstrated in heterologous expression systems (Guo et al., 2017). Subsequently, Fn plays a central bridging role in the formation of oral biofilms, uniquely positioned to interact with both early and late colonizers such as Sm and Porphyromonas gingivalis (Pg) in the oral cavity (Kaplan et al., 2009; Valadbeigi et al., 2023). Anaerobic bacteria like Pg are subsequently incorporated into the biofilm through adhesins such as Fap2, thereby exacerbating oral diseases (Mark Welch et al., 2016; Kim and Davey, 2020; Verma et al., 2023). Several studies have explored these oral pathogenic bacteria due to their potential role in linking oral and systemic diseases. These pathogens can cause systemic diseases through hematogenous (Lei et al., 2023) or intestinal pathways (Buetas et al., 2024; Wang et al., 2022).

Research has demonstrated that the progression of systemic disease is significantly influenced by gut microbiota and their metabolites through the intestinal pathway (Blasco-Baque et al., 2017; Lang and Schnabl, 2020). Trimethylamine-N-oxide (TMAO) has been recognized for its potential toxicity (Spence, 2023). Dietary sources such as carnitine, choline, creatinine, and L-carnitine are metabolized by intestinal bacteria into trimethylamine (TMA), which is then absorbed by intestinal epithelial cells. From there, TMA enters the bloodstream, is transported to the liver via the portal circulation, and is oxidized by host enzyme called hepatic flavin-containing monooxygenase 3 (FMO3) into TMAO (Shih et al., 2015). This pathway in vitro involves members of the genera Anaerococcus, Clostridium, Escherichia, Proteus, Providencia, and Edwardsiella (Romano et al., 2015), which commonly harbor the CutC and CutD genes (Canyelles et al., 2023). These genes encode bacterial enzymes crucial for the cleavage of choline to TMA. And its effect on TMA production can differ significantly across individuals in clinical research (Martínez-del Campo et al., 2015), often influenced by dietary patterns. Multivariate analyses have identified several bacterial species whose abundance correlates significantly with plasma TMAO levels but not necessarily with TMA levels in US men, indicating distinct microbial contributions under different dietary conditions (Li et al., 2022).

Studies now show a marked correlation between TMAO levels and CVD (He et al., 2023; Spence, 2023). In murine models, TMAO has been shown to promote atherosclerosis (AS) through mechanisms such as enhancing the formation of cholesterol-loaded macrophage foam cells, which are central to the development of atherosclerotic plaques (Wang et al., 2011). Furthermore, a significant study involving over 4,000 individuals undergoing coronary angiography revealed that those with TMAO levels in the highest quartile faced a 2.5 times greater risk of experiencing myocardial infarction, stroke, or vascular death within a span of three years (Tang et al., 2013). Apart from these, previous findings also indicate that TMAO is also a prognostic marker for other metabolic diseases such as myocardial infarction (MI), obesity, diabetes, NAFLD (Chen et al., 2016; Flores-Guerrero et al., 2021).

Recently, studies highlighted a potential association between oral diseases and TMAO. Streptococcus sanguinis (Ss) is a producer of TMAO in the oral cavity, potentially amplifying the gut microbiome’s role in exacerbating AS by enhancing TMA production (Chao and Zeisel, 1990). Significantly, elevated concentrations of TMAO have been observed in individuals with periodontitis (stages III-IV), correlating with endothelial dysfunction (Zhou et al., 2022). Plasma TMAO levels were higher in ApoE^−/− mice infected with Pg via the dental pulp (Gan et al., 2023), thereby implying that periodontitis may lead to elevated plasma TMAO levels. In addition, TMAO may have an effect on the progression of periodontitis via the two-way interaction between periodontitis and gastrointestinal microbiomes (Wang Q. et al., 2022). Preliminary research revealed changes in gut microbiome and liver status in ApoE^−/− mice within an experimental periodontitis cohort, accompanied by a rise in plasma TMAO levels (Xiao et al., 2022). Additionally, clinical studies conducted by our team have also found that patients with both AS and periodontitis exhibit higher peripheral blood levels of TMAO compared to patients without periodontitis (Wang et al., 2023). However, the relationship among these changes and specific oral pathogens or the local immune response has not been elucidated.

In this study, we selected Pg and Fn for their well-established roles in periodontal disease and systemic health, with Sm serving as a comparative non-periodontal pathogen control. Building upon preliminary research linking TMAO levels to periodontitis (Xiao et al., 2022), our goal was to evaluate the effect of specific periodontal pathogens on TMAO production in mice fed a standard diet, as opposed to host inflammatory responses, and to investigate the underlying mechanisms influencing the TMA-TMAO metabolic pathway.

TMAO is a confirmed independent risk factor for NAFLD and CVD, etc (He et al., 2023; Spence, 2023), and it exhibits a bidirectional association with oral diseases (Wang et al., 2022). Our previous research revealed that experimental periodontitis in mice altered the diversity and composition of the gut microbiome, consequently affecting the TMAO levels in plasma (Xiao et al., 2022). So, we further explored the specific changes and possible pathogens associated with TMAO formation process.

An important finding of this study is the significant increase in plasma TMAO concentration in mice following oral administration of Pg. This finding is consistent with results reported in previous research on a chronic apical periodontitis animal model induced using Pg (Gan et al., 2023). In addition, high levels of betaine and creatinine were observed in the Pg group of mice in our study, potentially indicating adaptive responses to liver inflammation (Wang et al., 2021). Interestingly, the other two oral pathogens did not significantly affect TMAO levels, implying a distinct role for Pg in promoting TMAO production through the gut-liver axis. This association further indicates the relationship between periodontitis and systematic diseases.

In this study, oral administration of Pg in mice caused a significant upregulation of FMO3 gene expression in the liver compared to the other three groups. FMO3 is the vital enzyme in the oxidation of TMA into TMAO, and the Pg-induced high TMAO levels can be attributed to the upregulation of FMO3 expression. Figure 4B further support that under the background of normal mice, the process of Pg-induced elevated plasma TMAO levels depends more on the oxidation of TMA in the liver rather than the generation of TMA in the intestine. Pg, Fn, and Sm groups exhibited a downregulation in FMO2 gene expression compared to the control group, which potentially indicates a general stress response of the liver to oral pathogenic bacterial infection (Ni et al., 2022). In vitro TMAO exacerbates lipid accumulation, inflammation, and fibrosis in the liver (Vallianou et al., 2019; Carpino et al., 2020). Moreover, the gut microbiota metabolite TMAO can exacerbate lipid deposition and liver fibrosis in HepG2 cells through the KRT17 in vitro (Nian et al., 2023). Elevated TMAO levels can induce oxidative stress, subsequently activating the NLRP3 inflammasome through the PERK-FoxO1-UPR-NF-κB pathway, ultimately inducing liver inflammation (Chen et al., 2019). The findings align with the results observed in our experiments. In our study, mice administered with Pg orally exhibited hepatic steatosis, accompanied by increased expression levels of lipid metabolism factors. Additionally, in vitro experiments revealed that Pg upregulated the expression of FMO3. Similarly, upon Pg-LPS stimulation of HepG2 cells, the levels of cellular lipid metabolism factors increased. Previous findings indicate that both TMAO and FMO3 are implicated in dysregulated hepatic lipid metabolism. The genetic ablation of FMO3 (FMO3KO) markedly reduces the levels of TMAO, exhibits lipid-lowering effects, and alleviates thrombosis formation (Shih et al., 2019).

So, we may conclude that the differences in plasma TMAO levels between the Pg and other groups, primarily driven by Pg’ s enhanced upregulation of hepatic FMO3, which facilitates greater TMA to TMAO conversion. Additionally, Pg induces stronger inflammatory responses and alters hepatic lipid metabolism, which could indirectly influence the metabolism of compounds related to TMAO production.

Significant changes in the gut microbiome structure were detected in mice exposed to both Pg and Fn groups. These changes included a decrease in the proportions of Firmicutes/Bacteroidota, indicating a potential disruption of gut microbiota balance (Zhang et al., 2022; Ruan et al., 2023). Muribaculaceae and Alloprevotella genera are related to the intestinal inflammation, barrier dysfunction, as well as glucose and lipid metabolism, further emphasizing the role of these oral pathogens in systemic diseases (Lagkouvardos et al., 2019; Ismael et al., 2022).

However, the variations in gut genera associated with TMAO remain unclear, which is consistent with previous reports, perhaps due to standard diet we used. Apart from that, it is a little bit surprising that the profiles of the microbiota and their associated metabolites—cecal TMA and TMAO—are quite distinct. TMA production in the gut is directly influenced by gut microbiota. Unlike studies that have investigated high-choline or high-fat diets (Agus et al., 2021), where an increased substrate availability might lead to higher and more consistent levels of cecum TMA and TMAO, our mice were on a standard diet. This is relevant when considering the internal consumption of cecum TMA to cecum TMAO. While a major portion of cecum TMAO stems from plasma TMAO, we propose that a segment might also arise from local oxidative processes within the gut, as indicated by the recent literature (Koay et al., 2021), mediated by specific microbiota or intestinal cells under oxidative stress, although further investigation is needed to confirm these pathways. And correlation between plasma TMA and gut microbiota seems to mirror the relationship with cecum TMA due to the translocation process. Moreover, while plasma TMAO correlates with systemic diseases like AS, the associated gut microbes may influence disease progression rather than directly contributing to TMAO production. Fn and Pg can alter the gut microbiota structure, leading to intestinal inflammation. Although the Sm group did not exhibit apparent liver or intestinal symptoms, increased relative abundances of Alistipes and Prevotellaceae_UCG-001 were noted. Alistipes is linked to bile acid metabolism and anti-inflammatory properties (Parker et al., 2020), while Prevotellaceae UCG-001 is positively correlated with AMPK signaling pathway and negatively correlated with markers of glucose and lipid metabolism disorder (Song et al., 2019). These genera are moderately correlated with cecal TMA content; however, their increased presence did not coincide with elevated TMA levels in the cecum or plasma, illustrating complex microbial interactions that may be influenced by other unmeasured factors. These observations can be attributed to the stimulation by the gut microbiota, which may require specific dietary substrates. Furthermore, the production of TMAO in mice on a normal diet may not primarily be mediated by the gut microbiome but rather by changes in the FMO3 enzyme pathway.

Despite being introduced exogenously, Fn exhibited only a modest two-fold increase, consistent with its known role in biofilm rather than in a free-floating, planktonic form (Brennan and Garrett, 2019). Surprisingly, both Pg and Fn were detected in control animals, which can be attributed to Pg’s scarce presence in the intestinal tract, primarily entering via oral ingestion (Jia et al., 2024), and Fn’s baseline presence as an intestinal resident. Notably, an increased detection of Pg in the liver was observed, indicating that Pg may partially translocate to the liver (Yao et al., 2023), highlighting the potential systemic effect of oral pathogens. However, this study did not use fluorescent labeling to track pathogenic bacteria, a limitation that future research will address to better understand pathogen dynamics and interactions.

In summary, Pg demonstrates a significantly greater effect on increasing peripheral blood TMAO levels compared to Fn and Sm. This is primarily due to Pg’s unique capabilities in disrupting the intestinal barrier and directly stimulating the expression of FMO3 in the liver. Despite minimal differences in intestinal TMA precursors and TMA levels among the groups, Pg’s specific biological mechanisms allow it to more effectively influence TMAO production through the gut-liver axis. Our study shows that, compared to the control group, the content of Pg in the liver is significantly increased, whereas the changes in Fn are not substantial, further supporting that Pg’s ability to compromise the intestinal barrier and reach the liver is more pronounced than Fn. Additionally, in vitro experiments have confirmed that stimulation by Pg increases the expression of FMO3 and lipid factors in liver cells. There is also substantial evidence that Pg can enter the liver and cause hepatic steatosis (Yoneda et al., 2012; Kuraji et al., 2021; Wang Q. et al., 2022).

In contrast, although Fn can also induce intestinal inflammation and changes in the gut microbiota, its impact on TMAO production in healthy individuals under a normal diet is relatively weaker than Pg, possibly due to its less disruptive effect on the intestinal barrier. The effect of Sm is even less pronounced; significant changes in Sm were not detected in the intestines or liver, and while genera related to cecal TMA metabolism appeared to shift in the Sm group, the overall diversity of the gut microbiota was more similar to the control group. Existing studies indicate that Sm has been demonstrated to enter the systemic circulation and cause pathogenic effects through intravenous injection, yet oral administration does not exacerbate intestinal or hepatic symptoms. aligning with our findings (Kitamoto and Kamada, 2022).

This study highlights the significant effect of the periodontal pathogen Pg on the TMA-TMAO pathway, primarily through modulation of FMO3 expression and regulation of hepatic lipid metabolism, compared to Fn and Sm. Pg uniquely enhances TMAO production, which is closely associated with the progression of systemic diseases, highlighting its potential as a key target in understanding and managing TMAO-related metabolic diseases. Future studies should delve into the molecular mechanisms by which Pg regulates FMO3 expression and its effects on lipid metabolism, aiming to uncover new therapeutic avenues for mitigating the effect of high TMAO levels on systemic health.

The similar changes in gut microbiota structure and composition induced by Pg and Fn, indicate their potential involvement in the influence of periodontitis on intestinal diseases.

The datasets generated for this study can be found in the Sequence Read Archive (SRA) SUB14350117. It is associated with BioProject PRJNA1095377.

Ethical approval was not required for the studies on humans in accordance with the local legislation and institutional requirements because only commercially available established cell lines were used. The animal study was approved by Nanjing University Animal Experiment Ethics Committee (Approval No. IACUC-D2102033). The study was conducted in accordance with the local legislation and institutional requirements.

XW: Conceptualization, Data curation, Formal analysis, Funding acquisition, Investigation, Methodology, Project administration, Resources, Software, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing. LC: Conceptualization, Data curation, Investigation, Methodology, Resources, Supervision, Validation, Writing – review & editing. YT: Conceptualization, Data curation, Methodology, Writing – review & editing. WX: Conceptualization, Resources, Software, Writing – review & editing. LH: Formal analysis, Software, Writing – review & editing. JW: Formal analysis, Supervision, Writing – review & editing. HW: Formal analysis, Funding acquisition, Resources, Writing – review & editing. SX: Conceptualization, Data curation, Formal analysis, Funding acquisition, Investigation, Methodology, Project administration, Resources, Software, Supervision, Validation, Visualization, Writing – review & editing.

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. This research was supported by two grants: the National Natural Science Foundation of China (82001111) and the Nanjing Department of Health under Grant (ZKX21055).

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

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The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fcimb.2024.1413787/full#supplementary-material↗.