Emilia A. Bober scite author profile

The susceptibility of human CD4+ and CD8+ T cells to senesce differs, with CD8+ T cells acquiring an immunosenescent phenotype faster than the CD4+ T cell compartment. We show here that it is the inherent difference in mitochondrial content that drives this phenotype, with senescent human CD4+ T cells displaying a higher mitochondrial mass. The loss of mitochondria in the senescent human CD8+ T cells has knock‐on consequences for nutrient usage, metabolism and function. Senescent CD4+ T cells uptake more lipid and glucose than their CD8+ counterparts, leading to a greater metabolic versatility engaging either an oxidative or a glycolytic metabolism. The enhanced metabolic advantage of senescent CD4+ T cells allows for more proliferation and migration than observed in the senescent CD8+ subset. Mitochondrial dysfunction has been linked to both cellular senescence and aging; however, it is still unclear whether mitochondria play a causal role in senescence. Our data show that reducing mitochondrial function in human CD4+ T cells, through the addition of low‐dose rotenone, causes the generation of a CD4+ T cell with a CD8+‐like phenotype. Therefore, we wish to propose that it is the inherent metabolic stability that governs the susceptibility to an immunosenescent phenotype.

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Divergent mechanisms of metabolic dysfunction drive fibroblast and T-cell senescence

Callender

Carroll

Bober

et al. 2018

Ageing Research Reviews

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Mitochondrial mass governs the extent of T cell senescence

Callender

Carroll

Bober

et al. 2019

Preprint

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show abstract

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Emilia A. Bober

Mitochondrial mass governs the extent of human T cell senescence

Divergent mechanisms of metabolic dysfunction drive fibroblast and T-cell senescence

Mitochondrial mass governs the extent of T cell senescence

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