Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT06405958 |
| Other study ID # |
S2024-0859-0001 |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
July 1, 2024 |
| Est. completion date |
December 31, 2026 |
Study information
| Verified date |
May 2024 |
| Source |
Asan Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
The microbiome acts as an antigen and can induce signaling through receptors like TLRs and
NODs. Microbial metabolites can directly act on gut cells or reach other organs systemically.
Studies show that the commensal, non-pathogenic microbiota plays an important role in
regulating the immune system in various ways:
- Promoting differentiation of Th17 cells and ILC3 signaling to regulate IL-17A production
- Influencing iNKT cell generation early in life to prevent inflammatory activities
- Facilitating CD4+ T cell differentiation and balancing Th1/Th2 responses
- Inducing regulatory T cells (Tregs) that promote immune homeostasis
- Tregs in Peyer's patches help maintain a microbiome that supports homeostasis
The microbiome influences T cells, B cells and immune homeostasis. This has implications for
transplantation, where modulating the microbiome could impact the graft's acceptance by
affecting the recipient's immune cells that respond to the transplant.
In summary, it highlights the microbiome's role in immune regulation and the potential for
leveraging this interaction therapeutically, including in the context of transplantation.
Description:
The microorganisms coexisting in our bodies are known to be involved in immune functions in
various ways. The microbiome basically acts as an antigen in the immune system and is known
to be able to induce ligands for toll-like receptors (TLRs) and NOD, which is one of the
pattern recognition receptors. Microbial metabolites such as short-chain fatty acids (SCFAs)
or AhR ligands can directly act on intestinal cells and gut immune cells, but can also reach
other organs through systemic circulation and regulate immunity. Many studies have shown that
not pathogenic but coexisting microbiota can regulate the immune system, as described below.
Intestinal colonization of segmented filamentous bacteria promotes the differentiation of
CD4+Th17 cells and induces signaling through the ILC3/IL-22/SAA1/2 axis, leading to IL-17A
production by RORγt+Th17 cells. IL-22 derived from ILC3 facilitates IL-17A production by Th17
cells, contributing to the inhibition of certain microbial species. Decreased MHCII
expression in ILC3 prevents the activation of commensal-specific CD4+ T cells, avoiding
immune responses against the colonization of harmless microbes. Early-life microbial
colonization partially inhibits the generation of abundant iNKT cells through sphingolipid
production, preventing potential disease-promoting activities in the intestinal lamina
propria and lungs.
Colonization by Bacteroides fragilis, a major constituent of the mammalian gut microbiota,
promotes CD4+ T cell differentiation and contributes to balancing Th1 and Th2 in a
polysaccharide A-dependent manner. Polysaccharide A is taken up by lamina propria dendritic
cells via TLR2 and presented to naive CD4+ T cells, which differentiate into regulatory T
cells (iTregs) in the presence of active TGF-β, and the IL-10 produced by these cells
promotes immune homeostasis.
Maintaining this immune homeostasis also requires selectively maintaining appropriate gut
microbes. Foxp3+ Tregs contributing to immune homeostasis are located in Peyer's patches and
induce class switching in B cells, thereby maintaining and managing a microbial composition
that can sustain bodily homeostasis.
The above results exemplify how the immune system and the coexisting microbial ecosystem
influence each other. This suggests that after transplantation, the microbiome can affect T
cells, B cells, and consequently impact and be impacted by the graft.
