CRIg-expressing peritoneal macrophages are associated with disease severity in patients with cirrhosis and ascites
Katharine M. Irvine, Xuan Banh, Victoria L. Gadd, Kyle K. Wojcik, Juliana K. Ariffin, Sara Jose, Samuel Lukowski, Gregory J. Baillie, Matthew J. Sweet, Elizabeth E. Powell
Katharine M. Irvine, Xuan Banh, Victoria L. Gadd, Kyle K. Wojcik, Juliana K. Ariffin, Sara Jose, Samuel Lukowski, Gregory J. Baillie, Matthew J. Sweet, Elizabeth E. Powell
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Research Article Hepatology Inflammation

CRIg-expressing peritoneal macrophages are associated with disease severity in patients with cirrhosis and ascites

Abstract

Infections are an important cause of morbidity and mortality in patients with decompensated cirrhosis and ascites. Hypothesizing that innate immune dysfunction contributes to susceptibility to infection, we assessed ascitic fluid macrophage phenotype and function. The expression of complement receptor of the immunoglobulin superfamily (CRIg) and CCR2 defined two phenotypically and functionally distinct peritoneal macrophage subpopulations. The proportion of CRIghi macrophages differed between patients and in the same patient over time, and a high proportion of CRIghi macrophages was associated with reduced disease severity (model for end-stage liver disease) score. As compared with CRIglo macrophages, CRIghi macrophages were highly phagocytic and displayed enhanced antimicrobial effector activity. Transcriptional profiling by RNA sequencing and comparison with human macrophage and murine peritoneal macrophage expression signatures highlighted similarities among CRIghi cells, human macrophages, and mouse F4/80hi resident peritoneal macrophages and among CRIglo macrophages, human monocytes, and mouse F4/80lo monocyte-derived peritoneal macrophages. These data suggest that CRIghi and CRIglo macrophages may represent a tissue-resident population and a monocyte-derived population, respectively. In conclusion, ascites fluid macrophage subset distribution and phagocytic capacity is highly variable among patients with chronic liver disease. Regulating the numbers and/or functions of these macrophage populations could provide therapeutic opportunities in cirrhotic patients.

Authors

Katharine M. Irvine, Xuan Banh, Victoria L. Gadd, Kyle K. Wojcik, Juliana K. Ariffin, Sara Jose, Samuel Lukowski, Gregory J. Baillie, Matthew J. Sweet, Elizabeth E. Powell

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Figure 6

Relationship between human and murine peritoneal macrophage signatures.

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Relationship between human and murine peritoneal macrophage signatures. ...
(A and B) Murine peritoneal macrophage-specific gene set enrichment with respect to the ascites fluid macrophage profile. Ascites macrophage data are ranked according to differential expression between subpopulations (indicated by red-blue bars), and the gene set of interest is mapped onto this profile (black bars) to determine enrichment score (green lines) (Thio., thioglycollate). Enrichment of genes (C) upregulated and (D) downregulated in murine Gata6-deficient macrophages in ascites macrophages (GSEA analysis as in A). Relative expression of (E) GATA6, (F) TGFB2, (G) CXCL13, (H) LRG1, (I) RARB, (J) RAI14, and (K) CD49F in CRIghi and CRIglo macrophages stimulated with ATRA (n = 3, repeated-measures 2-way ANOVA followed by Sidak multiple comparison test for differences between macrophage populations or time point). (AJ) ANOVA P values for the effect of macrophage population or (K) ATRA stimulation on gene expression; *P < 0.05, **P < 0.01. (L) Mean fluorescence intensity (MFI) of CD49F surface expression on ascites macrophage populations (Mann-Whitney test, n = 6) and representative dot plot. Dot plot data represent mean ± SEM.