Hyperglutaminolysis drives senescence and aging through arginine-mTORC1 axis activation
Summary
The catabolism of glutamine is essential for living organisms, so that its first step, driven by glutaminase 1 (GLS1), generally referred to as glutaminolysis, plays important roles in physiological metabolism. However, the status and impact of glutaminolysis in pathological contexts such as aging and age-related diseases remain elusive. In this study, through metabolomics analysis and different aging models, we verified the hyperactivation status of glutaminolysis in senescent cells and a
Content
# Hyperglutaminolysis drives senescence and aging through arginine-mTORC1 axis activation
*Published: 2026 Feb 19*
The catabolism of glutamine is essential for living organisms, so that its first
step, driven by glutaminase 1 (GLS1), generally referred to as glutaminolysis,
plays important roles in physiological metabolism. However, the status and
impact of glutaminolysis in pathological contexts such as aging and age-related
diseases remain elusive. In this study, through metabolomics analysis and
different aging models, we verified the hyperactivation status of glutaminolysis
in senescent cells and aged Drosophila and mice, which we term
"hyperglutaminolysis". We further confirmed the aging-promoting role of this
hyperglutaminolysis by addition and removal intervention experiments.
Intriguingly, a novel signaling axis connecting to senescence-associated
persistent mTORC1 activation was found. This pathway begins with
glutaminase-catalyzed production of ammonium and glutamate, which drives
arginine biosynthesis and is subsequently sensed by CASTOR1, leading to
persistent mTORC1 activation. The regulatory roles of two key enzymes within
this cascade, GLS1 and argininosuccinate lyase (ASL), were specifically
investigated and verified by cellular and in vivo experiments, including those
using stress-promoted and naturally aged animals, combined with GLS1 and ASL
knockdown, and multiple rounds of metabolite analysis. In conclusion, our work
positions dysregulated glutaminolysis as a key driver of aging and delineates a
previously unrecognized molecular cascade that directly links glutaminolysis,
arginine biosynthesis, and mTORC1 activation. These findings significantly
expand our understanding of the relationship between glutamine catabolism and
aging and are valuable for identifying novel intervention targets aimed at
mitigating aging-related processes.
DOI: 10.1038/s41392-026-02576-w