Lysosomal acid lipase, CSF1R, and PD-L1 determine functions of CD11c+ myeloid-derived suppressor cells
Ting Zhao, Sheng Liu, Xinchun Ding, Erica M. Johnson, Nasser H. Hanna, Kanhaiya Singh, Chandan K. Sen, Jun Wan, Hong Du, Cong Yan
Ting Zhao, Sheng Liu, Xinchun Ding, Erica M. Johnson, Nasser H. Hanna, Kanhaiya Singh, Chandan K. Sen, Jun Wan, Hong Du, Cong Yan
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Research Article Immunology

Lysosomal acid lipase, CSF1R, and PD-L1 determine functions of CD11c+ myeloid-derived suppressor cells

Abstract

Lysosomal acid lipase (LAL) is a key enzyme in the metabolic pathway of neutral lipids. In the blood of LAL-deficient (Lal–/–) mice, increased CD11c+ cells were accompanied by upregulated programmed cell death ligand 1 (PD-L1) expression. Single-cell RNA sequencing of Lal–/– CD11c+ cells identified 2 distinctive clusters with a major metabolic shift toward glucose utilization and reactive oxygen species overproduction. Pharmacologically blocking pyruvate dehydrogenase in glycolysis not only reduced CD11c+ cells and their PD-L1 expression but also reversed their capabilities of T cell suppression and tumor growth stimulation. Colony-stimulating factor 1 receptor (CSF1R) played an essential role in controlling Lal–/– CD11c+ cell homeostasis and function and PD-L1 expression. Pharmacological inhibition of LAL activity increased CD11c, PD-L1, and CSF1R levels in both normal murine myeloid cells and human blood cells. Tumor-bearing mice and human patients with non–small cell lung cancer also showed CD11c+ cell expansion with PD-L1 and CSF1R upregulation and immunosuppression. There were positive correlations among CD11c, PD-L1, and CSF1R expression and negative correlations with LAL expression in patients with lung cancer or melanoma using The Cancer Genome Atlas database and patient samples. Therefore, CD11c+ cells switched their functions to immune suppression and tumor growth stimulation through CSF1R/PD-L1 upregulation and metabolic reprogramming.

Authors

Ting Zhao, Sheng Liu, Xinchun Ding, Erica M. Johnson, Nasser H. Hanna, Kanhaiya Singh, Chandan K. Sen, Jun Wan, Hong Du, Cong Yan

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Figure 4

Metabolic reprogramming in Lal–/– CD11c+ cells.

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Metabolic reprogramming in Lal–/– CD11c+ cells. (A and B) Gene expressio...
(A and B) Gene expression of glycolysis (A) and citrate cycle (B) across cell clusters in t-SNE plots of CD11c+ cells from Lal–/– versus Lal+/+ mice. (C) Statistical analysis of ROS MFI in Lal–/– versus Lal+/+ CD11c+ cells by flow cytometry. (D) Expression of gene response to ROS across cell clusters in t-SNE plots of CD11c+ cells from Lal–/– versus Lal+/+ mice. (E) Extracellular acidification rate (ECAR) of glycolysis and oxygen consumption rate (OCR) in mitochondrial respiration in Lal–/– versus Lal+/+ CD11c+ cells. (F) ATP production in mitochondrial respiration in Lal–/– versus Lal+/+ CD11c+ cells. (G) MFI of G6PD, PDH, LDH, and GLUD expression in Lal–/– versus Lal+/+ CD11c+ cells by flow cytometry. (H) Percentage of CD11c+ cells in the blood and percentage of PD-L1+ cells in CD11c+ blood cells after CPI-613 treatment by flow cytometry analysis. (I) CPI-613–pretreated CD11c+ cells were cocultured with CFSE-labeled Lal+/+ CD4+ T cells for T cell proliferation assay. (J) CPI-613–pretreated CD11c+ cells (2 × 105) were coinjected with B16 melanoma cells (2 × 105) into the flank region of Lal+/+ recipient mice for tumor growth assay. Data are expressed as mean ± SD. Experiments were independently repeated, n = 4 for C, G, and I, n = 6–8 for E and F, n = 7 for H, n = 12 for J. *P < 0.05, **P < 0.01, unpaired Student’s t test for C, F, and G, 2-way ANOVA for H and I, 1-way ANOVA for J.