Background <p>The gut microbiota plays an essential role in mucosal immunity, with secretory immunoglobulin A (IgA) acting as a key effector in neutralizing pathogens and maintaining host-microbiota homeostasis. IgA production occurs via T cell-dependent (TD) and -independent pathways, with T follicular helper (Tfh) cells driving high-affinity, antigen-specific IgA responses. However, the specific microbial taxa and metabolites that regulate Tfh-mediated IgA responses under steady-state conditions remain poorly understood. This study investigated how gut microbiota-derived signals shape Tfh responses and IgA production, with implications for enhancing mucosal vaccine efficacy.</p> Results <p>We demonstrate that Peyer’s patches (PP)-derived Tfh cells exhibit superior IgA-inducing capacity compared to splenic Tfh cells. RNA sequencing revealed distinct transcriptional profiles in PP-Tfh cells, including upregulation of the genes associated with Tfh differentiation and activation (<i>Bcl6, Cd40lg, Maf</i>), T-B cell interactions (<i>Il21, Sh2d1a, Fyn</i>), and migration (<i>Ccr6, Cxcr5</i>). Functionally, PP-Tfh cells formed larger T-B cell contact areas and induced significantly higher IgA secretion in co-culture than their splenic counterparts. Microbiota depletion experiments revealed that eliminating neomycin-depleted bacteria reduced fecal IgA levels and diminished PP-Tfh cell frequencies. Fecal microbiota transplantation from neomycin-treated mice restored both IgA production and Tfh responses in germ-free (GF) mice. Bioinformatic analysis (PICRUSt2 and LEfSe) identified butyrate-producing <i>Lachnospiraceae</i> and <i>Ruminococcaceae</i> as key drivers of the Tfh-IgA axis.</p> <p>Butyrate supplementation enhanced Tfh differentiation and IgA⁺ germinal center B cell development in vitro and increased fecal IgA levels in vivo. Mechanistically, butyrate promoted IgA production via GPR43 signaling, as its effect was lost in co-cultures with <i>Gpr43</i><sup>⁻/⁻</sup> Tfh cells. Moreover, treatment with tributyrin, a butyrate prodrug, enhanced vaccine-induced IgA and protected mice against <i>Salmonella</i> Typhimurium infection, reducing bacterial burden and tissue damage. These findings define a functional microbiota-Tfh-IgA axis sustained by neomycin-depleted, butyrate-producing bacteria.</p> Conclusions <p>Our study underscores the crucial role of the gut microbiota, particularly neomycin-depleted butyrate producing taxa, in regulating PP-Tfh cell function and IgA production. Butyrate emerges as a metabolite linking microbial metabolism to Tfh differentiation and IgA class switching. Together, these findings establish a microbiota-metabolite-Tfh cell axis essential for mucosal immune homeostasis and suggest novel strategies for enhancing vaccine efficacy and protection against enteric infections.</p> <p><MediaObject ID="MOESM2"> <VideoObject FileRef="MediaObjects/40168_2025_2284_MOESM2_ESM.mp4" VideoID="65SkT5T5U4s1JHPzYWZphR"> <Caption Language="En" xml:lang="en"> <CaptionContent> <p>Video Abstract</p> </CaptionContent> </Caption> </VideoObject> </MediaObject></p>

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Commensal microbe-derived butyrate enhances T follicular helper cell function to boost mucosal vaccine efficacy

  • Haeun Ko,
  • Chan Johng Kim,
  • Seungyeon Choi,
  • Jaegyun Noh,
  • Seung Won Kim,
  • Juhun Lee,
  • Seohyun Byun,
  • Haena Lee,
  • John Chulhoon Park,
  • Hye Eun Park,
  • Amit Sharma,
  • Minhyuk Park,
  • Junghwan Park,
  • Choong-Gu Lee,
  • Kwang Hyun Cha,
  • Sin-Hyeog Im

摘要

Background

The gut microbiota plays an essential role in mucosal immunity, with secretory immunoglobulin A (IgA) acting as a key effector in neutralizing pathogens and maintaining host-microbiota homeostasis. IgA production occurs via T cell-dependent (TD) and -independent pathways, with T follicular helper (Tfh) cells driving high-affinity, antigen-specific IgA responses. However, the specific microbial taxa and metabolites that regulate Tfh-mediated IgA responses under steady-state conditions remain poorly understood. This study investigated how gut microbiota-derived signals shape Tfh responses and IgA production, with implications for enhancing mucosal vaccine efficacy.

Results

We demonstrate that Peyer’s patches (PP)-derived Tfh cells exhibit superior IgA-inducing capacity compared to splenic Tfh cells. RNA sequencing revealed distinct transcriptional profiles in PP-Tfh cells, including upregulation of the genes associated with Tfh differentiation and activation (Bcl6, Cd40lg, Maf), T-B cell interactions (Il21, Sh2d1a, Fyn), and migration (Ccr6, Cxcr5). Functionally, PP-Tfh cells formed larger T-B cell contact areas and induced significantly higher IgA secretion in co-culture than their splenic counterparts. Microbiota depletion experiments revealed that eliminating neomycin-depleted bacteria reduced fecal IgA levels and diminished PP-Tfh cell frequencies. Fecal microbiota transplantation from neomycin-treated mice restored both IgA production and Tfh responses in germ-free (GF) mice. Bioinformatic analysis (PICRUSt2 and LEfSe) identified butyrate-producing Lachnospiraceae and Ruminococcaceae as key drivers of the Tfh-IgA axis.

Butyrate supplementation enhanced Tfh differentiation and IgA⁺ germinal center B cell development in vitro and increased fecal IgA levels in vivo. Mechanistically, butyrate promoted IgA production via GPR43 signaling, as its effect was lost in co-cultures with Gpr43⁻/⁻ Tfh cells. Moreover, treatment with tributyrin, a butyrate prodrug, enhanced vaccine-induced IgA and protected mice against Salmonella Typhimurium infection, reducing bacterial burden and tissue damage. These findings define a functional microbiota-Tfh-IgA axis sustained by neomycin-depleted, butyrate-producing bacteria.

Conclusions

Our study underscores the crucial role of the gut microbiota, particularly neomycin-depleted butyrate producing taxa, in regulating PP-Tfh cell function and IgA production. Butyrate emerges as a metabolite linking microbial metabolism to Tfh differentiation and IgA class switching. Together, these findings establish a microbiota-metabolite-Tfh cell axis essential for mucosal immune homeostasis and suggest novel strategies for enhancing vaccine efficacy and protection against enteric infections.

Video Abstract