Loss of ABCG1 influences regulatory T cell differentiation and atherosclerosis
Hsin-Yuan Cheng, … , Mary Sorci-Thomas, Catherine C. Hedrick
Hsin-Yuan Cheng, … , Mary Sorci-Thomas, Catherine C. Hedrick
Published August 2, 2016
Citation Information: J Clin Invest. 2016;126(9):3236-3246. https://doi.org/10.1172/JCI83136.
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Research Article Inflammation

Loss of ABCG1 influences regulatory T cell differentiation and atherosclerosis

Abstract

ATP-binding cassette transporter G1 (ABCG1) promotes cholesterol accumulation and alters T cell homeostasis, which may contribute to progression of atherosclerosis. Here, we investigated how the selective loss of ABCG1 in T cells impacts atherosclerosis in LDL receptor–deficient (LDLR-deficient) mice, a model of the disease. In LDLR-deficient mice fed a high-cholesterol diet, T cell–specific ABCG1 deficiency protected against atherosclerotic lesions. Furthermore, T cell–specific ABCG1 deficiency led to a 30% increase in Treg percentages in aorta and aorta-draining lymph nodes (LNs) of these mice compared with animals with only LDLR deficiency. When Abcg1 was selectively deleted in Tregs of LDLR-deficient mice, we observed a 30% increase in Treg percentages in aorta and aorta-draining LNs and reduced atherosclerosis. In the absence of ABCG1, intracellular cholesterol accumulation led to downregulation of the mTOR pathway, which increased the differentiation of naive CD4 T cells into Tregs. The increase in Tregs resulted in reduced T cell activation and increased IL-10 production by T cells. Last, we found that higher ABCG1 expression in Tregs was associated with a higher frequency of these cells in human blood samples. Our study indicates that ABCG1 regulates T cell differentiation into Tregs, highlighting a pathway by which cholesterol accumulation can influence T cell homeostasis in atherosclerosis.

Authors

Hsin-Yuan Cheng, Dalia E. Gaddis, Runpei Wu, Chantel McSkimming, LaTeira D. Haynes, Angela M. Taylor, Coleen A. McNamara, Mary Sorci-Thomas, Catherine C. Hedrick

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Figure 2

The advantage of Lck-Cre+ Abcg1fl/fl Treg development is intrinsic.

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The advantage of Lck-Cre+ Abcg1fl/fl Treg development is intrinsic. (A) ...
(A) CD45.1 (WT) and CD45.2 (Lck-Cre+ Abcg1fl/fl) bone marrow cells were injected at a 1:1 ratio into irradiated CD45.1/2 heterozygous recipient mice, which were analyzed 10 weeks later. Gating strategy shows the splenic CD45.1/CD45.2 Treg composition. Representative FACS plot shows CD45.1 (blue box) versus CD45.2 (red box) Tregs. Graph shows the percentages of CD45.1+ (WT) and CD45.2+ (Lck-Cre+ Abcg1fl/fl) Tregs in recipient mice. N = 5 mice per group. FSC, forward scatter; SSC, side scatter; W, width. (B and C) Increased Treg differentiation from naive Lck-Cre+ Abcg1fl/fl CD4+ cells. (B) Naive CD4+ T cells from Lck-Cre+ Abcg1fl/fl mice and Lck-Cre Abcg1fl/fl littermates were cultured with CD3/CD28 Abs plus TGF-β for 72 hours. N = 5–6 mice per group. (C) Naive CD4+ T cells isolated from WT (CD45.1) and Lck-Cre+ Abcg1fl/fl (CD45.2) donor mice were transferred into Rag1–/– recipient mice at a 1:1 ratio, and 10 days later, the recipients’ peripheral LNs were analyzed. Representative FACS plot shows CD45.1 (WT; blue box) versus CD45.2 (Lck-Cre+ Abcg1fl/fl; red box) Tregs. Dot plot shows the percentages of WT- and Lck-Cre+ Abcg1fl/fl–expressing Tregs in the recipient mice. N = 5–6 mice per group. (D) An in vitro suppression assay was performed. CellTrace Violet–labeled WT naive CD4+CD25CD62L+CD44 T cells (Teff) were cocultured with or without CD4+CD25+ Tregs from Lck-Cre Abcg1fl/fl and Lck-Cre+ Abcg1fl/fl mice at a Teff/Treg ratio of 2:1. Representative plots of Teff cell division are shown. Graph shows the percentages of CellTrace Violet–diluted Teff cells (divided cell percentage) at an increasing Teff/Treg ratio. Results were averaged from 4 to 6 mice per group. **P < 0.01 and ****P < 0.0001, by unpaired Student’s t test to determine differences between 2 groups.