Monocyte Metabolic Plasticity and Cytokine Production Differentiate Latent TB Infection from Active Disease

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Abstract

Rationale Monocytes are central to host defence against Mycobacterium tuberculosis (Mtb), yet their functional and metabolic profiles during latent TB infection (TBI) and active TB disease (TBD) remain poorly defined. Immunometabolic dysfunction may underlie ineffective responses in TB, but cell-specific mechanisms are unclear. Objectives To compare the phenotypic, functional, and metabolic profiles of circulating monocytes from individuals with TBI, TBD, and healthy controls (HC), and assess the impact of treatment. Measurements Peripheral blood monocytes were profiled using high-dimensional flow cytometry, Luminex cytokine/chemokine assays, and SCENITH™, a flow-based metabolic assay. Unstimulated and Mtb-stimulated monocytes from treatment-naïve and treated individuals were analysed. Main Results Monocytes from TBI and TBD showed distinct phenotypes from HC, marked by elevated CD14 and CD45RA. HLA-DR was reduced in TBI versus HC and further decreased in TBD. TNF receptors were downregulated in TBI but unchanged in TBD. Baseline cytokine and chemokine profiles in TBI and TBD were similar (yet distinct from HC), but Mtb stimulation elicited a stronger cytokine response in TBI. Metabolically, TBI and TBD monocytes exhibited increased glycolysis and reduced mitochondrial dependence versus HC. Treatment partially restored mitochondrial function. Upon Mtb challenge, TBI monocytes had higher glycolytic capacity than TBD. Conclusions Monocyte metabolic plasticity and cytokine production distinguish latent from active TB and are partially reversible with treatment. Circulating monocyte metabolism reflects TB immune status and may serve as a biomarker or therapeutic target. Reprogrammed glycolytic profiles in TBI contrast with impaired adaptability in TBD, suggesting dysfunctional myeloid activation during disease.
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Abstract

Rationale Monocytes are central to host defence against Mycobacterium tuberculosis (Mtb), yet their functional and metabolic profiles during latent TB infection (TBI) and active TB disease (TBD) remain poorly defined. Immunometabolic dysfunction may underlie ineffective responses in TB, but cell-specific mechanisms are unclear.

Objectives

To compare the phenotypic, functional, and metabolic profiles of circulating monocytes from individuals with TBI, TBD, and healthy controls (HC), and assess the impact of treatment. Measurements Peripheral blood monocytes were profiled using high-dimensional flow cytometry, Luminex cytokine/chemokine assays, and SCENITH™, a flow-based metabolic assay. Unstimulated and Mtb-stimulated monocytes from treatment-naïve and treated individuals were analysed. Main Results Monocytes from TBI and TBD showed distinct phenotypes from HC, marked by elevated CD14 and CD45RA. HLA-DR was reduced in TBI versus HC and further decreased in TBD. TNF receptors were downregulated in TBI but unchanged in TBD. Baseline cytokine and chemokine profiles in TBI and TBD were similar (yet distinct from HC), but Mtb stimulation elicited a stronger cytokine response in TBI. Metabolically, TBI and TBD monocytes exhibited increased glycolysis and reduced mitochondrial dependence versus HC. Treatment partially restored mitochondrial function. Upon Mtb challenge, TBI monocytes had higher glycolytic capacity than TBD.

Conclusions

Monocyte metabolic plasticity and cytokine production distinguish latent from active TB and are partially reversible with treatment. Circulating monocyte metabolism reflects TB immune status and may serve as a biomarker or therapeutic target. Reprogrammed glycolytic profiles in TBI contrast with impaired adaptability in TBD, suggesting dysfunctional myeloid activation during disease. Competing Interest Statement The authors have declared no competing interest. Footnotes Sources of Support: This work was funded by the Health Research Board Ireland (HRB-ILP-POR-2022-033 and HRB-EIA-2019-010; awarded to S.A.B.) and The Royal City of Dublin Hospital Trust (RCDH app 185; Awarded to J.K.). The following reagent was obtained through BEI Resources, NIAID, NIH: Mycobacterium tuberculosis, Strain H37Rv, Gamma-Irradiated Whole Cells, NR-49098). Added discussion points and alterations to how data was presented.

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License: CC-BY-NC-ND-4.0