106 Increasing AMPK activity in human T cells enhances memory subset formation without sacrificing in vitro expansion

Braverman, Erica; Dobbs, Andrea; Monlish, Darlene; Byersdorfer, Craig A.

doi:10.1136/jitc-2020-sitc2020.0106

Cited by 1 publication

(2 citation statements)

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“…For instance, deletion of the AMPK gene can cause defective CD8 + T M generation, or an increased level of AMPK promotes the T fitness, expansion and formation of T M cells. 48,49 Recently, Mayer et al showed that AMPK deficiency does not affect T cell fate, clonal diversity, the number of activated T cells and survival in vivo, rather it reduces the magnitude of T cell activation, expansion and protein translational capacity. 50 Conversely, others showed that reducing AMPK signaling via miR17-92 (indirect effect) or shRNA targeting of AMPK promotes metabolic reprogramming to aerobic glycolysis and restores T cell proliferation in senescent cells.…”

Section: Metabolic Regulatorsmentioning

confidence: 99%

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MicroRNA‐mediated metabolic reprogramming of chimeric antigen receptor T cells

et al. 2022

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Advances made in chimeric antigen receptor (CAR) T cell therapy have revolutionized the treatment and management of certain cancers. Currently, B cell malignancies have been among the few cancers to which CAR T cells have shown persistent and resilient anti‐tumor responses. A growing body of evidence suggests that the persistence of CAR T cells within patients following infusion is linked to the mitochondrial fitness of the CAR T cell, which could affect clinical outcomes. Analysis of CAR T cells from patients undergoing successful treatment has shown an increase in mitochondrial mass and fusion events, and a reduction in aerobic metabolism, highlighting the importance of mitochondria in CAR T cell function. Consequently, there has been recent interest and investment in approaches that focus on mitochondrial programming. In this regard, miRNAs are promising agents in mitochondrial reprogramming for several reasons: (1) natural and artificial miRNAs are non‐immunogenic, (2) one miRNA can simultaneously modulate the expression of multiple genes within a pathway, (3) the small size of a sequence required for producing mature miRNA is ideal for use in viral vectors and (4) different precursor miRNAs (pre‐miRNAs) hairpins can be incorporated into a polycistronic miRNA cluster to create a miRNA cocktail. In this perspective, we describe the latest genetic engineering strategies that can be used to achieve the optimal expression of candidate miRNAs alongside a CAR construct. In addition, we include an in silico analysis of rational candidate miRNAs that could promote the mitochondrial fitness of CAR T cells.

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Section: Metabolic Regulatorsmentioning

confidence: 99%

“…Some of the metabolic regulators have a controversial function in T cell development. For instance, deletion of the AMPK gene can cause defective CD8 + T M generation, or an increased level of AMPK promotes the T fitness, expansion and formation of T M cells 48,49 . Recently, Mayer et al .…”

Section: Introductionmentioning

confidence: 99%