Tissue-resident macrophage populations constitute a mosaic of phenotypes, yet how their metabolic states link to the range of phenotypes and functions in vivo is still poorly defined. Here, using... Show moreTissue-resident macrophage populations constitute a mosaic of phenotypes, yet how their metabolic states link to the range of phenotypes and functions in vivo is still poorly defined. Here, using high-dimensional spectral flow cytometry, we observe distinct metabolic profiles between different organs and functionally link acetyl CoA carboxylase activity to efferocytotic capacity. Additionally, differences in metabolism are evident within populations from a specific site, corresponding to relative stages of macrophage maturity. Immune perturbation with intestinal helminth infection increases alternative activation and metabolic rewiring of monocyte-derived macrophage populations, while resident TIM4+ intestinal macrophages remain immunologically and metabolically hyporesponsive. Similar metabolic signatures in alternatively-activated macrophages are seen from different tissues using additional helminth models, but to different magnitudes, indicating further tissue-specific contributions to metabolic states. Thus, our high-dimensional, flow-based metabolic analyses indicates complex metabolic heterogeneity and dynamics of tissue-resident macrophage populations at homeostasis and during helminth infection.Gauging the in vivo metabolism of immune cells at the single-cell level has proven challenging. Here the authors use spectral flow cytometry to investigate metabolic profiles in tissue-resident macrophages from several organs and changes in response to helminth infection. Show less
Zande, H.J.P. van der; Brombacher, E.C.; Lambooij, J.M.; Pelgrom, L.R.; Zawistowska-Deniziak, A.; Patente, T.A.; ... ; Guigas, B. 2023
Obesity-associated metabolic inflammation drives the development of insulin resistance and type 2 diabetes, notably through modulating innate and adaptive immune cells in metabolic organs. The... Show moreObesity-associated metabolic inflammation drives the development of insulin resistance and type 2 diabetes, notably through modulating innate and adaptive immune cells in metabolic organs. The nutrient sensor liver kinase B1 (LKB1) has recently been shown to control cellular metabolism and T cell priming functions of DCs. Here, we report that hepatic DCs from high-fat diet-fed (HFD-fed) obese mice display increased LKB1 phosphorylation and that LKB1 deficiency in DCs (CD11c Delta LKB1) worsened HFD-driven hepatic steatosis and impaired glucose homeostasis. Loss of LKB1 in DCs was associated with increased expression of Th17-polarizing cytokines and accumulation of hepatic IL-17A+ Th cells in HFD-fed mice. Importantly, IL-17A neutralization rescued metabolic perturbations in HFD-fed CD11c Delta LKB1 mice. Mechanistically, deficiency of the canonical LKB1 target AMPK in HFD-fed CD11c Delta AMPK alpha 1 mice recapitulated neither the hepatic Th17 phenotype nor the disrupted metabolic homeostasis, suggesting the involvement of other and/ or additional LKB1 downstream effectors. We indeed provide evidence that the control of Th17 responses by DCs via LKB1 is actually dependent on both AMPK alpha 1 salt-inducible kinase signaling. Altogether, our data reveal a key role for LKB1 signaling in DCs in protection against obesityinduced metabolic dysfunctions by limiting hepatic Th17 responses. Show less
Pelgrom, L.R.; Patente, T.A.; Otto, F.; Nouwen, L.V.; Ozir-Fazalalikhan, A.; Ham, A.J. van der; ... ; Everts, B. 2022
How mechanistic target of rapamycin complex 1 (mTORC1), a key regulator of cellular metabolism, affects dendritic cell (DC) metabolism and T cell-priming capacity has primarily been investigated in... Show moreHow mechanistic target of rapamycin complex 1 (mTORC1), a key regulator of cellular metabolism, affects dendritic cell (DC) metabolism and T cell-priming capacity has primarily been investigated in vitro, but how mTORC1 regulates this in vivo remains poorly defined. Here, using mice deficient for mTORC1 component raptor in DCs, we find that loss of mTORC1 negatively affects glycolytic and fatty acid metabolism and maturation of conventional DCs, particularly cDC1s. Nonetheless, antigen-specific CD8(+) T cell responses to infection are not compromised and are even enhanced following skin immunization. This is associated with increased activation of Langerhans cells and a subpopulation of EpCAM-expressing cDC1s, of which the latter show an increased physical interaction with CD8(+) T cells in situ. Together, this work reveals that mTORC1 limits CD8(+) T cell priming in vivo by differentially orchestrating the metabolism and immunogenicity of distinct antigen-presenting cell subsets, which may have implications for clinical use of mTOR inhibitors. Show less
In this issue of Cell Metabolism, Balmer et al. show that the timing and concentration of acetate exposure is critical to how it is metabolized by and affects the function of CD8 T cells. When... Show moreIn this issue of Cell Metabolism, Balmer et al. show that the timing and concentration of acetate exposure is critical to how it is metabolized by and affects the function of CD8 T cells. When abundantly present at the time of reactivation, acetate rewires CD8 T cell metabolism to suppress their reactivation and limit inflammation. Show less
