Therapeutic targeting of BCL-2 during CART cell production augments potency through non-apoptotic adaptive changes
Summary
Targeting the BCL-2 family of proteins, key regulators of cellular apoptosis, with BH3-mimetics has been a major therapeutic goal to overcome cancer cell death resistance. However, beyond their canonical roles in apoptosis, BCL-2 proteins also play vital roles in cellular metabolism, signaling, and, increasingly, immune cell regulation. T cells in particular depend heavily on BCL-2 family proteins during ontogeny and maintenance, yet the broader consequences of pharmacologically inhibiting
Content
# Therapeutic targeting of BCL-2 during CART cell production augments potency through non-apoptotic adaptive changes
*Published: 2026 Apr 27*
Targeting the BCL-2 family of proteins, key regulators of cellular apoptosis,
with BH3-mimetics has been a major therapeutic goal to overcome cancer cell
death resistance. However, beyond their canonical roles in apoptosis, BCL-2
proteins also play vital roles in cellular metabolism, signaling, and,
increasingly, immune cell regulation. T cells in particular depend heavily on
BCL-2 family proteins during ontogeny and maintenance, yet the broader
consequences of pharmacologically inhibiting anti-apoptotic BCL-2 proteins in T
cells remain underexplored. Our group has previously demonstrated that BCL-2
inhibition with the BH3-mimetic venetoclax induces gene expression and
plasticity changes in murine T cells. Building upon this, we here investigate
whether venetoclax-driven T cell reprogramming can be leveraged to enhance
adoptive cell therapies, specifically using chimeric antigen receptor (CAR) T
cells targeting CD19 as a model system. Our findings reveal that venetoclax
treatment during ex vivo expansion of CART cells, prepared from T cells from
healthy donors or chemotherapeutically pretreated patients, potently augments
antitumor efficacy in a BCL-2-dependent manner. Transcriptomic and functional
analyses demonstrate that venetoclax reprograms CART cells by regulating
signaling pathways (e.g., IL-2/STAT5 and PI3K/AKT) and metabolic programs (e.g.,
OXPHOS and glycolysis), yielding CART cells with superior fitness and effector
functionalities. These results highlight a novel therapeutic approach using
anti-apoptotic drugging to enhance the performance of adoptive T cell therapies
and support further examination of venetoclax and other BH3-mimetics as immune
modulators.
DOI: 10.1038/s41392-026-02655-y