LDL receptor–mediated lipoprotein uptake fuels human CD4+ T cell polarization toward a c-MAF/IL-10– and FOXP3-driven phenotype
Angela Markovska, Niels S. van Heusden, Dagmar Duijzer, Alejandra Bodelón, Greta Rogani, Enric Mocholi, Edwin C.A. Stigter, Can Gulersonmez, Sander Kooijman, Leonie Van der Zee, Monique T. Mulder, Jeanine E. Roeters van Lennep, Patrick C.N. Rensen, Jorg van Loosdregt, Sebastiaan J. Vastert, Noam Zelcer, Marianne Boes, Henk S. Schipper
Angela Markovska, Niels S. van Heusden, Dagmar Duijzer, Alejandra Bodelón, Greta Rogani, Enric Mocholi, Edwin C.A. Stigter, Can Gulersonmez, Sander Kooijman, Leonie Van der Zee, Monique T. Mulder, Jeanine E. Roeters van Lennep, Patrick C.N. Rensen, Jorg van Loosdregt, Sebastiaan J. Vastert, Noam Zelcer, Marianne Boes, Henk S. Schipper
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Research Article Cell biology Immunology

LDL receptor–mediated lipoprotein uptake fuels human CD4+ T cell polarization toward a c-MAF/IL-10– and FOXP3-driven phenotype

Abstract

Human CD4+ T cells utilize nutrients, including lipids, to support their activation and polarization. Considering the pivotal role of lipoproteins in lipid transport, we reasoned that lipoprotein uptake and processing could effect CD4+ T cell function. Here, we demonstrate that activation of human CD4+ T cells induced expression of LDL receptor (LDLR) to facilitate LDLR-mediated endocytosis of LDL. Degradation of surface LDLR on CD4+ T cells with PCSK9 hampered activation and proliferation of the cells. Lipoprotein deprivation or blocking of lysosomal cholesterol egress impaired activation of mechanistic target of rapamycin complex 1 (mTORC1), affecting CD4+ T cell activation and proliferation. Furthermore, lipoprotein deprivation of cultured primary CD4+ T cells lead to reduced expression of c-MAF and FOXP3, key transcription factors for IL-10, accompanied by reduced IL-10 secretion. The pivotal role of LDLR-mediated lipoprotein uptake for mTORC1 activity, c-MAF and FOXP3 expression, and IL-10 secretion was confirmed using LDLR-dysfunctional CD4+ T cells from patients with homozygous familial hypercholesterolemia. Our study offers valuable insights into the lipoprotein metabolism of human CD4+ T cells and their reliance on the LDLR pathway for activation and polarization, a feature that may be leveraged to modulate CD4+ T cell function.

Authors

Angela Markovska, Niels S. van Heusden, Dagmar Duijzer, Alejandra Bodelón, Greta Rogani, Enric Mocholi, Edwin C.A. Stigter, Can Gulersonmez, Sander Kooijman, Leonie Van der Zee, Monique T. Mulder, Jeanine E. Roeters van Lennep, Patrick C.N. Rensen, Jorg van Loosdregt, Sebastiaan J. Vastert, Noam Zelcer, Marianne Boes, Henk S. Schipper

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Figure 1

Activated CD4+ T cells upregulate LDLR expression and lipoprotein metabolism.

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Activated CD4+ T cells upregulate LDLR expression and lipoprotein metabo...
(A) Normalized expression of LDLR mRNA values among immune cell types obtained from the Human Cell Atlas (https://data.humancellatlas.org/). Effector memory T cells were defined as CD127+CD25CD62LCD45RA, naive T cells as CD127+CD25CD62L+CD45RA+, and Tregs as CD4+CD25+CD127. (B) LDLR mRNA normalized to RPL13A and shown relative to resting cells in CD4+ T cells from healthy donors activated for 24 hours with anti-CD3/CD28. Two-tailed unpaired t test (**P < 0.01; n = 9). (C).Western blot of LDLR and GAPDH (loading control) in CD4+ T cells activated for 24 hours with anti-CD3/CD28. (D) Geometric mean fluorescence intensity (gMFI) of cell-surface LDLR on CD4+ T cells. (E) Representative flow cytometry plot of CD25 and LDLR staining of CD4+ T cells at resting (t = 0) or after 48 hours of activation (t = 48). (F) Log2 fold change of LDLR in ex vivo blood-derived CD4+ T cells from patients with systemic juvenile idiopathic arthritis (JIA) in active (n = 7) or remission state (n = 7) relative to the CD4+ T cells from the individuals acting as healthy controls (HC) (n = 7). One-way ANOVA with Tukey’s multiple comparisons test (***P < 0.001). (G and H) Representative histograms of CD4+ T cells loaded with LDL/VLDL-DyLight and quantification of the gMFI of the signal. Cells were activated (anti-CD3/CD28) and loaded with LDL/VLDL-DyLight, with or without unlabeled lipoproteins, for 16 hours in lipoprotein-deprived medium. Kruskal-Wallis test with Dunn’s multiple comparisons test (*P < 0.05, ****P < 0.0001; n = 9). (I) qRT-PCR analysis of genes involved in lipoprotein uptake and metabolism in CD4+ T cells from healthy donors at the indicated times after stimulation with anti-CD3/CD28. Values are normalized to RPL13A endogenous control and shown relative to resting cells (n = 3).