Background <p>Asymptomatic Entamoeba histolytica (Eh) carriage is a major transmission reservoir, yet how the gut ecosystem—particularly microbiota-derived metabolites such as secondary bile acids—supports persistent colonization remains unclear. We investigated whether gut microbiome–metabolite features are associated with Eh carriage and could influence parasite phenotypes</p> Methods <p>We integrated shotgun metagenomics from a prospectively screened outpatient cohort (n=36) with functional in vitro assays. An ordinal stepwise model across detection states (Eh−, Eh_qPCR, Eh_Cyst) was used to identify candidate microbial features, followed by bile-acid exposure assays and transcriptomic profiling to evaluate impacts on parasite fitness and metronidazole susceptibility in vitro</p> Results <p>Microbiome profiling suggested taxon-specific shifts rather than wholesale dysbiosis. Community-level beta diversity showed no significant separation, whereas genus richness was higher in Eh_Cyst (unadjusted p=0.046). Multivariable modeling yielded concordant directional but non-significant trends (all q&gt;0.9), highlighting Firmicutes genera including Coprococcus, Ruminococcus, and Catenibacterium as candidate taxa. We then evaluated deoxycholic acid (DCA), a microbiota-modified secondary bile acid. In vitro, 100 μM DCA extended Eh survival under nutrient-limited conditions and reduced metronidazole susceptibility after pretreatment. Transcriptomic profiling showed that DCA induced a distinct response, including an 8.34-fold induction of the ABC transporter P-glycoprotein-2 and upregulation of lipid remodeling and stress-response genes, supporting a bile acid–driven adaptive program consistent with intestinal persistence</p> Conclusions <p>Our findings suggest that secondary bile acids, exemplified by DCA, can reprogram Eh gene expression and attenuate metronidazole susceptibility in vitro. In the context of cyst-associated microbiome signatures, this supports the plausibility of a microbiome–bile acid–parasite axis that may promote persistence in asymptomatic carriers and could influence treatment efficacy</p>

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Multi-omics profiling and bile-acid exposure assays implicate a gut microbiome–parasite axis linked to persistent Entamoeba histolytica carriage

  • Yasuaki Yanagawa,
  • Naoko Yoshida,
  • Takashi Makiuchi,
  • Akira Kawashima,
  • Haruka Uemura,
  • Takahiro Aoki,
  • Daisuke Mizushima,
  • Hiroyuki Gatanaga,
  • Koji Watanabe

摘要

Background

Asymptomatic Entamoeba histolytica (Eh) carriage is a major transmission reservoir, yet how the gut ecosystem—particularly microbiota-derived metabolites such as secondary bile acids—supports persistent colonization remains unclear. We investigated whether gut microbiome–metabolite features are associated with Eh carriage and could influence parasite phenotypes

Methods

We integrated shotgun metagenomics from a prospectively screened outpatient cohort (n=36) with functional in vitro assays. An ordinal stepwise model across detection states (Eh−, Eh_qPCR, Eh_Cyst) was used to identify candidate microbial features, followed by bile-acid exposure assays and transcriptomic profiling to evaluate impacts on parasite fitness and metronidazole susceptibility in vitro

Results

Microbiome profiling suggested taxon-specific shifts rather than wholesale dysbiosis. Community-level beta diversity showed no significant separation, whereas genus richness was higher in Eh_Cyst (unadjusted p=0.046). Multivariable modeling yielded concordant directional but non-significant trends (all q>0.9), highlighting Firmicutes genera including Coprococcus, Ruminococcus, and Catenibacterium as candidate taxa. We then evaluated deoxycholic acid (DCA), a microbiota-modified secondary bile acid. In vitro, 100 μM DCA extended Eh survival under nutrient-limited conditions and reduced metronidazole susceptibility after pretreatment. Transcriptomic profiling showed that DCA induced a distinct response, including an 8.34-fold induction of the ABC transporter P-glycoprotein-2 and upregulation of lipid remodeling and stress-response genes, supporting a bile acid–driven adaptive program consistent with intestinal persistence

Conclusions

Our findings suggest that secondary bile acids, exemplified by DCA, can reprogram Eh gene expression and attenuate metronidazole susceptibility in vitro. In the context of cyst-associated microbiome signatures, this supports the plausibility of a microbiome–bile acid–parasite axis that may promote persistence in asymptomatic carriers and could influence treatment efficacy