Microbiota control immune regulation in humanized mice
Elke Gülden, Nalini K. Vudattu, Songyan Deng, Paula Preston-Hurlburt, Mark Mamula, James C. Reed, Sindhu Mohandas, Betsy C. Herold, Richard Torres, Silvio M. Vieira, Bentley Lim, Jose D. Herazo-Maya, Martin Kriegel, Andrew L. Goodman, Chris Cotsapas, Kevan C. Herold
Elke Gülden, Nalini K. Vudattu, Songyan Deng, Paula Preston-Hurlburt, Mark Mamula, James C. Reed, Sindhu Mohandas, Betsy C. Herold, Richard Torres, Silvio M. Vieira, Bentley Lim, Jose D. Herazo-Maya, Martin Kriegel, Andrew L. Goodman, Chris Cotsapas, Kevan C. Herold
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Research Article Immunology

Microbiota control immune regulation in humanized mice

Abstract

The microbiome affects development and activity of the immune system, and may modulate immune therapies, but there is little direct information about this control in vivo. We studied how the microbiome affects regulation of human immune cells in humanized mice. When humanized mice were treated with a cocktail of 4 antibiotics, there was an increase in the frequency of effector T cells in the gut wall, circulating levels of IFN-γ, and appearance of anti-nuclear antibodies. Teplizumab, a non–FcR-binding anti-CD3ε antibody, no longer delayed xenograft rejection. An increase in CD8+ central memory cells and IL-10, markers of efficacy of teplizumab, were not induced. IL-10 levels were only decreased when the mice were treated with all 4 but not individual antibiotics. Antibiotic treatment affected CD11b+CD11c+ cells, which produced less IL-10 and IL-27, and showed increased expression of CD86 and activation of T cells when cocultured with T cells and teplizumab. Soluble products in the pellets appeared to be responsible for the reduced IL-27 expression in DCs. Similar changes in IL-10 induction were seen when human peripheral blood mononuclear cells were cultured with human stool samples. We conclude that changes in the microbiome may impact the efficacy of immunosuppressive medications by altering immune regulatory pathways.

Authors

Elke Gülden, Nalini K. Vudattu, Songyan Deng, Paula Preston-Hurlburt, Mark Mamula, James C. Reed, Sindhu Mohandas, Betsy C. Herold, Richard Torres, Silvio M. Vieira, Bentley Lim, Jose D. Herazo-Maya, Martin Kriegel, Andrew L. Goodman, Chris Cotsapas, Kevan C. Herold

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Figure 1

Changes in microbiota and lymphocytes with antibiotics.

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Changes in microbiota and lymphocytes with antibiotics. 16S sequencing w...
16S sequencing was performed on freshly isolated pellets from humanized mice (A) and humanized mice treated with the cocktail of 4 antibiotics for 2 weeks (B). Following antibiotic treatment there was a 24 ± 4.32-fold depletion of Eubacteria (n = 11, P = 0.0002) and a 34.7 ± 1.86-fold depletion of segmented filamentous bacteria (P = 4.33 × 10–9). The flora was largely restricted to Ternicutes spp. after antibiotic treatment. (C) The number of CD2+ cells in the lamina propria of the mice treated with antibiotics (Abx) compared with mice that did not receive antibiotics is shown (each symbol represents an individual mouse, P = 0.0382, Student’s t test). (D) There was a significant interaction between antibiotic treatment and CD4+ T cell subsets in the gut (P = 0.0004, 2-way ANOVA). Naive and effector T cells were decreased and increased, respectively. *P < 0.05, **P < 0.01; n = 8 and 9/group. (E) Similar findings were seen within the CD8+ T cells but the differences were not statistically significant. (F) The number of CD19+ cells in the lamina propria of the mice treated with antibiotics compared with mice that did not receive antibiotics is shown (each symbol represents an individual mouse; P = 0.0261, Student’s t test) (G) The circulating levels of IFN-γ were elevated in the antibiotic-treated mice. Each symbol represents an individual mouse that was or was not treated with antibiotics. **P = 0.008, Student’s t test. CM, central memory T cell; EMRA, effector memory RA T cell.