CD9 regulates macrophage-mediated remodeling of adipose tissue in obesity
Julia Chini, Nicole DeMarco, Dana V. Mitchell, Sam J. McCright, Kaitlyn M. Shen, Divyansi Pandey, Rachel L. Clement, Jessica Miller, Rajan Jain, Deanne M. Taylor, Mitchell A. Lazar, David A. Hill
Julia Chini, Nicole DeMarco, Dana V. Mitchell, Sam J. McCright, Kaitlyn M. Shen, Divyansi Pandey, Rachel L. Clement, Jessica Miller, Rajan Jain, Deanne M. Taylor, Mitchell A. Lazar, David A. Hill
View: Text | PDF
Research Article Immunology Metabolism

CD9 regulates macrophage-mediated remodeling of adipose tissue in obesity

Abstract

Dysfunctional white adipose tissue contributes to the development of obesity-related morbidities, including insulin resistance, dyslipidemia, and other metabolic disorders. Adipose tissue macrophages (ATMs) accumulate in obesity and play both beneficial and harmful roles in the maintenance of adipose tissue homeostasis and function. Despite their importance, the molecules and mechanisms that regulate these diverse functions are not well understood. Lipid-associated macrophages (LAMs), the dominant subset of obesity-associated ATMs, accumulate in crown-like structures and are characterized by a metabolically activated and proinflammatory phenotype. We previously identified CD9 as a surface marker of LAMs. However, the contribution of CD9 to the activation and function of LAMs during obesity is unknown. Using a myeloid-specific CD9-KO model, we show that CD9 supports ATM-adipocyte adhesion and crown-like structure formation. Furthermore, CD9 promotes the expression of profibrotic and extracellular matrix remodeling genes. Loss of myeloid CD9 reduces adipose tissue fibrosis, increases visceral adipose tissue accumulation, and improves global metabolic outcomes during diet-induced obesity. These results identify CD9 as a causal regulator of pathogenic LAM functions, highlighting CD9 as a potential therapeutic target for treating obesity-associated metabolic disease.

Authors

Julia Chini, Nicole DeMarco, Dana V. Mitchell, Sam J. McCright, Kaitlyn M. Shen, Divyansi Pandey, Rachel L. Clement, Jessica Miller, Rajan Jain, Deanne M. Taylor, Mitchell A. Lazar, David A. Hill

×

Figure 3

CD9 promotes macrophage integrin expression and adhesion.

Options: View larger image (or click on image) Download as PowerPoint
CD9 promotes macrophage integrin expression and adhesion. (A and B) BMDM...
(A and B) BMDMs from control (Cd9fl/fl) and CD9-MKO (Cd9fl/fl LysMCre+/–) mice were treated with BSA or palmitate for 24 hours. (A) Expression of Cd9 was assessed by qPCR (n = 6). Shown as expression relative to BSA controls (Ctrl). (B) Surface expression of CD9 shown as relative MFI compared with BSA controls. BMDMs were gated as live CD45+ CD11b+ F4/80+ CD64+ cells (n = 4). (C) Blood monocytes isolated from WT mice fed a normal chow diet were treated with BSA or palmitate for 24 hours. Expression of Cd9 was assessed by qPCR (n = 7–8). Monocytes were gated using the gating strategy in Supplemental Figure 3. (D) Expression of integrins Itgax and Itgav by qPCR in BMDMs from control and CD9-MKO mice treated with BSA or palmitate (n = 6). (E) Flow cytometry of CD11c (Itgax) and CD51 (Itgav) shown as MFI relative to control BMDMs treated with palmitate (n = 5). (F) Adhesion assay of control or CD9-MKO BMDMs on differentiated 3T3-L1 adipocytes (n = 6). (G) Relative expression of Itgax and Itgav in epididymal white adipose tissue (eWAT) adipocyte fraction isolated from control and CD9-MKO mice fed an HFD (n = 6–9). (H and I) Representative images and quantification of immunofluorescence staining of CD11c (H) and CD51 (I) in eWAT. Data shown as relative MFI (n = 8–9). Scale bar: 200 μm. Data shown as combined data from 2–3 independent experiments (C, G–I) or representative data from 3 independent experiments (A, B, and DF). qPCR is shown as ΔCt relative to Hprt normalized to BSA controls. Data presented as mean ± SEM (AI); 2-way ANOVA with Fisher’s LSD test (A, B, and D) or unpaired 2-tailed Student’s t test (C, and EI). ns, not significant; **P < 0.01, ***P < 0.001, ****P < 0.0001.