MMR vaccination induces trained immunity via functional and metabolic reprogramming of γδ T cells
Rutger J. Röring, Priya A. Debisarun, Javier Botey-Bataller, Tsz Kin Suen, Özlem Bulut, Gizem Kilic, Valerie A.C.M. Koeken, Andrei Sarlea, Harsh Bahrar, Helga Dijkstra, Heidi Lemmers, Katharina L. Gössling, Nadine Rüchel, Philipp N. Ostermann, Lisa Müller, Heiner Schaal, Ortwin Adams, Arndt Borkhardt, Yavuz Ariyurek, Emile J. de Meijer, Susan L. Kloet, Jaap ten Oever, Katarzyna Placek, Yang Li, Mihai G. Netea
Rutger J. Röring, Priya A. Debisarun, Javier Botey-Bataller, Tsz Kin Suen, Özlem Bulut, Gizem Kilic, Valerie A.C.M. Koeken, Andrei Sarlea, Harsh Bahrar, Helga Dijkstra, Heidi Lemmers, Katharina L. Gössling, Nadine Rüchel, Philipp N. Ostermann, Lisa Müller, Heiner Schaal, Ortwin Adams, Arndt Borkhardt, Yavuz Ariyurek, Emile J. de Meijer, Susan L. Kloet, Jaap ten Oever, Katarzyna Placek, Yang Li, Mihai G. Netea
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Research Article Immunology

MMR vaccination induces trained immunity via functional and metabolic reprogramming of γδ T cells

Abstract

The measles, mumps, and rubella (MMR) vaccine protects against all-cause mortality in children, but the immunological mechanisms mediating these effects are poorly known. We systematically investigated whether MMR can induce long-term functional changes in innate immune cells, a process termed trained immunity, that could at least partially mediate this heterologous protection. In a randomized, placebo-controlled trial, 39 healthy adults received either the MMR vaccine or a placebo. Using single-cell RNA-Seq, we found that MMR caused transcriptomic changes in CD14+ monocytes and NK cells, but most profoundly in γδ T cells. Monocyte function was not altered by MMR vaccination. In contrast, the function of γδ T cells was markedly enhanced by MMR vaccination, with higher production of TNF and IFN-γ, as well as upregulation of cellular metabolic pathways. In conclusion, we describe a trained immunity program characterized by modulation of γδ T cell function induced by MMR vaccination.

Authors

Rutger J. Röring, Priya A. Debisarun, Javier Botey-Bataller, Tsz Kin Suen, Özlem Bulut, Gizem Kilic, Valerie A.C.M. Koeken, Andrei Sarlea, Harsh Bahrar, Helga Dijkstra, Heidi Lemmers, Katharina L. Gössling, Nadine Rüchel, Philipp N. Ostermann, Lisa Müller, Heiner Schaal, Ortwin Adams, Arndt Borkhardt, Yavuz Ariyurek, Emile J. de Meijer, Susan L. Kloet, Jaap ten Oever, Katarzyna Placek, Yang Li, Mihai G. Netea

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Figure 1

Study setup, plasma proteomics analysis after MMR vaccination, and WBC counts.

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Study setup, plasma proteomics analysis after MMR vaccination, and WBC c...
(A) Setup of the present randomized, placebo-controlled trial of MMR vaccination. M/F, males/females. (B) Volcano plot of Olink targeted proteomics (n = 1,289 analyzed proteins in total) in plasma, after MMR vaccination (n = 16). (CF) Volcano plots of subcategories of the plasma proteome measured by Olink. In the volcano plots for the subpanels, the full panel is depicted in light gray as the background. The side plots in panels BF show the relative expression values (NPX) of selected proteins in each (sub)panel. (G) Total and differentiated WBC counts, before and after vaccination in placebo- and MMR-vaccinated groups. An unadjusted P value of less than 0.05 is the cutoff for the volcano plots. P values for this figure were calculated using the Wilcoxon signed-rank test. T1, baseline; T2, one month after treatment.