Isolation of Immune Cells from Adipose Tissue for Flow Cytometry

MPYS Modulates Fatty Acid Metabolism and Immune Tolerance at Homeostasis Independent of Type I IFNs

MPYS/STING (stimulator of IFN genes) senses cyclic dinucleotides (CDNs), generates type I IFNs, and plays a critical role in infection, inflammation, and cancer. In this study, analyzing genotype and haplotype data from the 1000 Genomes Project, we found that the R71H-G230A-R293Q (HAQ) MPYS allele frequency increased 57-fold in East Asians compared with sub-Saharan Africans. Meanwhile, the G230A-R293Q (AQ) allele frequency decreased by 98% in East Asians compared with sub-Saharan Africans. We propose that the HAQ and AQ alleles underwent a natural selection during the out-of-Africa migration. We used mouse models of HAQ and AQ to investigate the underlying mechanism. We found that the mice carrying the AQ allele, which disappeared in East Asians, had normal CDN-type I IFN responses. Adult AQ mice, however, had less fat mass than did HAQ or wild-type mice on a chow diet. AQ epididymal adipose tissue had increased regulatory T cells and M2 macrophages with protein expression associated with enhanced fatty acid oxidation. Conditional knockout mice and adoptive cell transfer indicate a macrophage and regulatory T cell-intrinsic role of MPYS in fatty acid metabolism. Mechanistically, AQ/IFNAR1-/- mice had a similar lean phenotype as for the AQ mice. MPYS intrinsic tryptophan fluorescence revealed that the R71H change increased MPYS hydrophilicity. Lastly, we found that the second transmembrane (TM) and the TM2-TM3 linker region of MPYS interact with activated fatty acid, fatty acyl-CoA. In summary, studying the evolution of the human MPYS gene revealed an MPYS function in modulating fatty acid metabolism that may be critical during the out-of-Africa migration.

A multi-colour confocal microscopy method for identifying and enumerating macrophage subtypes and adherent cells in the stromal vascular fraction of human adipose

This study examines leukocytes present in lymphoedema (LE) adipose tissue (AT) by multi-colour confocal microscopy. LE AT, collected by liposuction surgery, was digested with collagenase to separate adipocytes from other tissue cells, comprising blood and lymphatic endothelial cells, fibroblasts, and all vessel- and tissue-resident leukocytes - the stromal vascular fraction (SVF). SVF cells were activated with phorbol 12-myristate 13-acetate (PMA) and ionomycin, adding Brefeldin-A to prevent cytokine secretion during the final 4 hours. Cells were incubated with CD11b-FITC and CD40-APC (M1 MØ)' or CD206-APC (M2 MØ) specific antibodies, fixed, permeabilised, then incubated with either (1) anti-TNF-PE, (2) anti- IL-1β-PE, (3) anti-IL-6-PE, (4) anti-IL-4-PE, (5) anti-TGFβ-PE or (6) isotype-IgG-PE (control), and stained with Hoechst 33342, preserved in permanent mounting media and examined by confocal microscopy. The FITC, PE and APC fluorescence channels were set to achieve minimal cross-channel emission using single-colour controls and voltages set for optimal detection by thresholding on isotype-IgG stained activated cells. Finally, transmission and z-stack images were captured. Cells were analysed as regions of interest (ROI) based on Hoechst-33342 then enumerated as FITC⁺, FITC⁺APC⁺ or FITC⁺APC⁺PE⁺ using an ImageJ script and exported into Excel. This permitted the examination of >9000 SVF cells individually, per LE sample. This method allows for the analysis of a high number of heterogeneous cells defined into any subtype or combination by the investigators' choice of surface and intracellular expression profiles. Fibroblasts, or other cytokine producing cells, can also be analysed by using other antibodies, and the cell count data can be correlated with any clinical or laboratory data.