Defining the proteomic landscape of cultured macrophages and their polarization continuum

Tiah C L Oates

Research output: Contribution to journalArticle (Academic Journal)peer-review

3 Citations (Scopus)

Abstract

Macrophages have previously been characterized based on phenotypical and functional differences into suggested simplified subtypes of MØ, M1, M2a and M2c. These macrophage subtypes can be generated in a well-established primary monocyte culture model that produces cells expressing accepted subtype surface markers. To determine how these subtypes retain functional similarities and better understand their formation, we generated all four subtypes from the same donors. Comparative whole-cell proteomics confirmed that four distinct macrophage subtypes could be induced from the same donor material, with > 50% of 5435 identified proteins being significantly altered in abundance between subtypes. Functional assessment highlighted that these distinct protein expression profiles are primed to enable specific cell functions, indicating that this shifting proteome is predictive of meaningful changes in cell characteristics. Importantly, the 2552 proteins remained consistent in abundance across all macrophage subtypes examined, demonstrating maintenance of a stable core proteome that likely enables swift polarity changes. We next explored the cross-polarization capabilities of preactivated M1 macrophages treated with dexamethasone. Importantly, these treated cells undergo a partial repolarization toward the M2c surface markers but still retain the M1 functional phenotype. Our investigation of polarized macrophage subtypes therefore provides evidence of a sliding scale of macrophage functionality, with these data sets providing a valuable benchmark resource for further studies of macrophage polarity, with relevance for cell therapy development and drug discovery.
Original languageEnglish
Pages (from-to)947-963
Number of pages17
JournalImmunology and Cell Biology
Volume101
Issue number10
Early online date11 Sept 2023
DOIs
Publication statusPublished - 1 Nov 2023

Bibliographical note

Funding Information:
This work was funded by grants from the NIHR Blood and Transplant Research Unit in red cell products (IS-BTU-1214-10032), NHS Blood and Transplant (NHSBT) R&D (WP15-05) and a Wellcome Trust PhD Studentship to TCLO (8043 WT 108907/Z/15/Z Dynamic Cell), PLM was supported by a Cancerfonden (Swedish Cancer Society) postdoctoral grant (21 0340 PT) and the work by HEB was supported by the Elizabeth Blackwell Institute (University of Bristol) with funding from the University's alumni and friends. The authors thank Dr Katy Jepson for facilitating the use of the Incucyte system. The authors also acknowledge MRC and Wolfson Foundation for establishing the Wolfson Bioimaging Facility (University of Bristol) and for the use of microscopes.

Funding Information:
This work was funded by grants from the NIHR Blood and Transplant Research Unit in red cell products (IS‐BTU‐1214‐10032), NHS Blood and Transplant (NHSBT) R&D (WP15‐05) and a Wellcome Trust PhD Studentship to TCLO (8043 WT 108907/Z/15/Z Dynamic Cell), PLM was supported by a Cancerfonden (Swedish Cancer Society) postdoctoral grant (21 0340 PT) and the work by HEB was supported by the Elizabeth Blackwell Institute (University of Bristol) with funding from the University's alumni and friends.

Publisher Copyright:
© 2023 The Authors. Immunology & Cell Biology published by John Wiley & Sons Australia, Ltd on behalf of the Australian and New Zealand Society for Immunology, Inc.

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