Your search keyword '"Verheijen, Fenne W. M."' showing total 5 results

1. Deciphering metabolic crosstalk in context: lessons from inflammatory diseases

Author

Verheijen, Fenne W M, Tran, Thi N M, Chang, Jung-Chin, Broere, Femke, Zaal, Esther A, Berkers, Celia R, Verheijen, Fenne W M, Tran, Thi N M, Chang, Jung-Chin, Broere, Femke, Zaal, Esther A, and Berkers, Celia R

Abstract

Metabolism plays a crucial role in regulating the function of immune cells in both health and disease, with altered metabolism contributing to the pathogenesis of cancer and many inflammatory diseases. The local microenvironment has a profound impact on the metabolism of immune cells. Therefore, immunological and metabolic heterogeneity as well as the spatial organization of cells in tissues should be taken into account when studying immunometabolism. Here, we highlight challenges of investigating metabolic communication. Additionally, we review the capabilities and limitations of current technologies for studying metabolism in inflamed microenvironments, including single-cell omics techniques, flow cytometry-based methods (Met-Flow, single-cell energetic metabolism by profiling translation inhibition (SCENITH)), cytometry by time of flight (CyTOF), cellular indexing of transcriptomes and epitopes by sequencing (CITE-Seq), and mass spectrometry imaging. Considering the importance of metabolism in regulating immune cells in diseased states, we also discuss the applications of metabolomics in clinical research, as well as some hurdles to overcome to implement these techniques in standard clinical practice. Finally, we provide a flowchart to assist scientists in designing effective strategies to unravel immunometabolism in disease-relevant contexts.

Published

2024

2. Deciphering metabolic crosstalk in context: lessons from inflammatory diseases.

Author

Verheijen, Fenne W. M., Tran, Thi N. M., Chang, Jung‐Chin, Broere, Femke, Zaal, Esther A., and Berkers, Celia R.

Abstract

Metabolism plays a crucial role in regulating the function of immune cells in both health and disease, with altered metabolism contributing to the pathogenesis of cancer and many inflammatory diseases. The local microenvironment has a profound impact on the metabolism of immune cells. Therefore, immunological and metabolic heterogeneity as well as the spatial organization of cells in tissues should be taken into account when studying immunometabolism. Here, we highlight challenges of investigating metabolic communication. Additionally, we review the capabilities and limitations of current technologies for studying metabolism in inflamed microenvironments, including single‐cell omics techniques, flow cytometry‐based methods (Met‐Flow, single‐cell energetic metabolism by profiling translation inhibition (SCENITH)), cytometry by time of flight (CyTOF), cellular indexing of transcriptomes and epitopes by sequencing (CITE‐Seq), and mass spectrometry imaging. Considering the importance of metabolism in regulating immune cells in diseased states, we also discuss the applications of metabolomics in clinical research, as well as some hurdles to overcome to implement these techniques in standard clinical practice. Finally, we provide a flowchart to assist scientists in designing effective strategies to unravel immunometabolism in disease‐relevant contexts. [ABSTRACT FROM AUTHOR]

Published

2024

3. Single-cell profiling reveals age-associated immunity in atherosclerosis

Author

Smit, Virginia, primary, de Mol, Jill, additional, Schaftenaar, Frank H, additional, Depuydt, Marie A C, additional, Postel, Rimke J, additional, Smeets, Diede, additional, Verheijen, Fenne W M, additional, Bogers, Laurens, additional, van Duijn, Janine, additional, Verwilligen, Robin A F, additional, Grievink, Hendrika W, additional, Bernabé Kleijn, Mireia N A, additional, van Ingen, Eva, additional, de Jong, Maaike J M, additional, Goncalves, Lauren, additional, Peeters, Judith A H M, additional, Smeets, Harm J, additional, Wezel, Anouk, additional, Polansky, Julia K, additional, de Winther, Menno P J, additional, Binder, Christoph J, additional, Tsiantoulas, Dimitrios, additional, Bot, Ilze, additional, Kuiper, Johan, additional, and Foks, Amanda C, additional

Published

2023

4. AMPK activation induces RALDH+ tolerogenic dendritic cells by rewiring glucose and lipid metabolism.

Author

Brombacher, Eline C., Patente, Thiago A., van der Ham, Alwin J., Moll, Tijmen J. A., Otto, Frank, Verheijen, Fenne W. M., Zaal, Esther A., de Ru, Arnoud H., Tjokrodirijo, Rayman T. N., Berkers, Celia R., van Veelen, Peter A., Guigas, Bruno, and Everts, Bart

Subjects

*REGULATORY T cells, *AMP-activated protein kinases, *T cell differentiation, *FATTY acid oxidation, *LIPID metabolism, *T cells

Abstract

Dendritic cell (DC) activation and function are underpinned by profound changes in cellular metabolism. Several studies indicate that the ability of DCs to promote tolerance is dependent on catabolic metabolism. Yet the contribution of AMP-activated kinase (AMPK), a central energy sensor promoting catabolism, to DC tolerogenicity remains unknown. Here, we show that AMPK activation renders human monocyte-derived DCs tolerogenic as evidenced by an enhanced ability to drive differentiation of regulatory T cells, a process dependent on increased RALDH activity. This is accompanied by several metabolic changes, including increased breakdown of glycerophospholipids, enhanced mitochondrial fission–dependent fatty acid oxidation, and upregulated glucose catabolism. This metabolic rewiring is functionally important as we found interference with these metabolic processes to reduce to various degrees AMPK-induced RALDH activity as well as the tolerogenic capacity of moDCs. Altogether, our findings reveal a key role for AMPK signaling in shaping DC tolerogenicity and suggest AMPK as a target to direct DC-driven tolerogenic responses in therapeutic settings. [ABSTRACT FROM AUTHOR]

Published

2024

5. AMPK activation induces RALDH+ tolerogenic dendritic cells by rewiring glucose and lipid metabolism.

Author

Brombacher EC, Patente TA, van der Ham AJ, Moll TJA, Otto F, Verheijen FWM, Zaal EA, de Ru AH, Tjokrodirijo RTN, Berkers CR, van Veelen PA, Guigas B, and Everts B

Subjects

Humans, T-Lymphocytes, Regulatory immunology, T-Lymphocytes, Regulatory metabolism, Enzyme Activation, Signal Transduction, Cells, Cultured, Dendritic Cells immunology, Dendritic Cells metabolism, Lipid Metabolism, Glucose metabolism, AMP-Activated Protein Kinases metabolism, Immune Tolerance, Cell Differentiation

Abstract

Dendritic cell (DC) activation and function are underpinned by profound changes in cellular metabolism. Several studies indicate that the ability of DCs to promote tolerance is dependent on catabolic metabolism. Yet the contribution of AMP-activated kinase (AMPK), a central energy sensor promoting catabolism, to DC tolerogenicity remains unknown. Here, we show that AMPK activation renders human monocyte-derived DCs tolerogenic as evidenced by an enhanced ability to drive differentiation of regulatory T cells, a process dependent on increased RALDH activity. This is accompanied by several metabolic changes, including increased breakdown of glycerophospholipids, enhanced mitochondrial fission-dependent fatty acid oxidation, and upregulated glucose catabolism. This metabolic rewiring is functionally important as we found interference with these metabolic processes to reduce to various degrees AMPK-induced RALDH activity as well as the tolerogenic capacity of moDCs. Altogether, our findings reveal a key role for AMPK signaling in shaping DC tolerogenicity and suggest AMPK as a target to direct DC-driven tolerogenic responses in therapeutic settings., (© 2024 Brombacher et al.)

Published

2024