TY - JOUR
T1 - CARMIL2 deficiency disrupts activation-induced metabolic reprogramming in T cells and is partially rescued by glutamine supplementation
AU - Kabha, Mona
AU - Liaks-Bohnick, Maya
AU - Zagairy, Fadia
AU - Atar, Orna
AU - Hamed, Mira
AU - Ziv, Michael
AU - Danial-Farran, Nada
AU - Khayat, Morad
AU - Ishach, Orly
AU - Dinur-Schejter, Yael
AU - Molho-Pessach, Vered
AU - Somekh, Ido
AU - Frizinsky, Shirly
AU - Bar-Ilan, Efrat
AU - Greenberger, Shoshana
AU - Adeeb, Naser Eddin
AU - Somech, Raz
AU - Stepansky, Polina
AU - Ron-Harel, Noga
AU - Cohen-Barak, Eran
N1 - Publisher Copyright:
© 2025 The Authors
PY - 2025
Y1 - 2025
N2 - Background: T-cell activation requires signaling through the T-cell receptor and costimulatory molecules, including CD28, triggering metabolic reprogramming to support growth and proliferation of the activating T cell. CARMIL2, a scaffold protein, facilitates CD28-mediated signaling. Individuals with CARMIL2 mutations experience inborn errors of immunity, leading to T-cell dysfunction and severe infectious and inflammatory comorbidities. However, how CARMIL2 deficiency impacts T-cell metabolic reprogramming remains unknown. Objective: We sought to investigate how CARMIL2 deficiency affects activation-induced metabolic reprogramming in T cells. Methods: CD4+ T cells were isolated from patients with CARMIL2 deficiency and matched healthy controls. A transcriptomic profile was analyzed by bulk RNA sequencing and whole-cell metabolomics by LC-MS/MS. Activation markers and signaling pathways were measured by flow cytometry. These approaches informed identification of specific amino acids for rescue experiments. Results: Nine patients with CARMIL2 deficiency and 16 age- and sex-matched healthy controls were recruited. RNA sequencing of CD4+ T cells revealed decreased expression of genes associated with metabolic activity, including mTOR signaling, glycolysis, 1-carbon metabolism, and glutamine metabolism. Whole-cell metabolomics reinforced these results and highlighted glutamine deficiency as a potential driver of the observed metabolic phenotype. Glutamine supplementation restored NF-κB and mTOR activity, as measured by p-65 and RPS6 phosphorylation, respectively, and upregulated the expression of IL17A in CARMIL2-mutated CD4+ T cells. Conclusion: CARMIL2 deficiency disrupts T-cell metabolic reprogramming and was partially rescued ex vivo with glutamine supplementation. These findings highlight a potential therapeutic approach targeting metabolism to improve immune function in individuals with CARMIL2 deficiency.
AB - Background: T-cell activation requires signaling through the T-cell receptor and costimulatory molecules, including CD28, triggering metabolic reprogramming to support growth and proliferation of the activating T cell. CARMIL2, a scaffold protein, facilitates CD28-mediated signaling. Individuals with CARMIL2 mutations experience inborn errors of immunity, leading to T-cell dysfunction and severe infectious and inflammatory comorbidities. However, how CARMIL2 deficiency impacts T-cell metabolic reprogramming remains unknown. Objective: We sought to investigate how CARMIL2 deficiency affects activation-induced metabolic reprogramming in T cells. Methods: CD4+ T cells were isolated from patients with CARMIL2 deficiency and matched healthy controls. A transcriptomic profile was analyzed by bulk RNA sequencing and whole-cell metabolomics by LC-MS/MS. Activation markers and signaling pathways were measured by flow cytometry. These approaches informed identification of specific amino acids for rescue experiments. Results: Nine patients with CARMIL2 deficiency and 16 age- and sex-matched healthy controls were recruited. RNA sequencing of CD4+ T cells revealed decreased expression of genes associated with metabolic activity, including mTOR signaling, glycolysis, 1-carbon metabolism, and glutamine metabolism. Whole-cell metabolomics reinforced these results and highlighted glutamine deficiency as a potential driver of the observed metabolic phenotype. Glutamine supplementation restored NF-κB and mTOR activity, as measured by p-65 and RPS6 phosphorylation, respectively, and upregulated the expression of IL17A in CARMIL2-mutated CD4+ T cells. Conclusion: CARMIL2 deficiency disrupts T-cell metabolic reprogramming and was partially rescued ex vivo with glutamine supplementation. These findings highlight a potential therapeutic approach targeting metabolism to improve immune function in individuals with CARMIL2 deficiency.
KW - CARMIL2
KW - glutamine
KW - metabolism
KW - mTOR
KW - T cell
UR - https://www.scopus.com/pages/publications/105013973536
U2 - 10.1016/j.jaci.2025.07.018
DO - 10.1016/j.jaci.2025.07.018
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C2 - 40738287
AN - SCOPUS:105013973536
SN - 0091-6749
JO - Journal of Allergy and Clinical Immunology
JF - Journal of Allergy and Clinical Immunology
ER -