A molecular signature for IL-10–producing Th1 cells in protozoan parasitic diseases
Chelsea L. Edwards, Jessica A. Engel, Fabian de Labastida Rivera, Susanna S. Ng, Dillon Corvino, Marcela Montes de Oca, Teija C.M. Frame, Shashi Bhushan Chauhan, Siddharth Sankar Singh, Awnish Kumar, Yulin Wang, Jinrui Na, Pam Mukhopadhyay, Jason S. Lee, Susanne Nylen, Shyam Sundar, Rajiv Kumar, Christian R. Engwerda
Chelsea L. Edwards, Jessica A. Engel, Fabian de Labastida Rivera, Susanna S. Ng, Dillon Corvino, Marcela Montes de Oca, Teija C.M. Frame, Shashi Bhushan Chauhan, Siddharth Sankar Singh, Awnish Kumar, Yulin Wang, Jinrui Na, Pam Mukhopadhyay, Jason S. Lee, Susanne Nylen, Shyam Sundar, Rajiv Kumar, Christian R. Engwerda
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Research Article Microbiology

A molecular signature for IL-10–producing Th1 cells in protozoan parasitic diseases

Abstract

Control of visceral leishmaniasis (VL) depends on proinflammatory Th1 cells that activate infected tissue macrophages to kill resident intracellular parasites. However, proinflammatory cytokines produced by Th1 cells can damage tissues and require tight regulation. Th1 cell IL-10 production is an important cell–autologous mechanism to prevent such damage. However, IL-10–producing Th1 (type 1 regulatory; Tr1) cells can also delay control of parasites and the generation of immunity following drug treatment or vaccination. To identify molecules to target in order to alter the balance between Th1 and Tr1 cells for improved antiparasitic immunity, we compared the molecular and phenotypic profiles of Th1 and Tr1 cells in experimental VL caused by Leishmania donovani infection of C57BL/6J mice. We also identified a shared Tr1 cell protozoan signature by comparing the transcriptional profiles of Tr1 cells from mice with experimental VL and malaria. We identified LAG3 as an important coinhibitory receptor in patients with VL and experimental VL, and we reveal tissue-specific heterogeneity of coinhibitory receptor expression by Tr1 cells. We also discovered a role for the transcription factor Pbx1 in suppressing CD4+ T cell cytokine production. This work provides insights into the development and function of CD4+ T cells during protozoan parasitic infections and identifies key immunoregulatory molecules.

Authors

Chelsea L. Edwards, Jessica A. Engel, Fabian de Labastida Rivera, Susanna S. Ng, Dillon Corvino, Marcela Montes de Oca, Teija C.M. Frame, Shashi Bhushan Chauhan, Siddharth Sankar Singh, Awnish Kumar, Yulin Wang, Jinrui Na, Pam Mukhopadhyay, Jason S. Lee, Susanne Nylen, Shyam Sundar, Rajiv Kumar, Christian R. Engwerda

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Figure 1

A molecular signature for mouse Tr1 cells during experimental visceral leishmaniasis (VL) caused by Leishmania donovani.

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A molecular signature for mouse Tr1 cells during experimental visceral l...
(A and B) A schematic showing a brief outline of the work flow for isolating splenic Th1 (IFN-γ+ IL-10; blue quadrant) and Tr1 cells (IFN-γ+ IL-10+; red quadrant). (C) Mean-difference plot from differential gene expression analysis between Tr1 versus Th1 cells. The 109 upregulated differentially expressed genes (DEGs) are colored red, the 76 downregulated DEGs are coloured blue, and nonsignificant genes are coloured gray. (D) The up- and downregulated canonical pathways identified in Tr1 cells, relative to Th1 cells, from Ingenuity Pathway Analysis are listed. (E) DEGs from experimental VL Tr1 versus Th1 cell comparisons were compared with 2,031 DEGs in experimental Plasmodium berghei ANKA Tr1 cells versus Th1 cells. The Venn diagrams show that 26 and 29 Tr1 cell DEGs were commonly down- and upregulated, respectively, in these 2 infections. Log fold change values shown are from experimental VL Tr1 cells versus Th1 cells.