Abstract
In contrast to long-term metabolic reprogramming, metabolic rewiring represents an instant and reversible cellular adaptation to physiological or pathological stress. Ca2+ signals of distinct spatio-temporal patterns control a plethora of signaling processes and can determine basal cellular metabolic setting, however, Ca2+ signals that define metabolic rewiring have not been conclusively identified and characterized. Here, we reveal the existence of a basal Ca2+ flux originating from extracellular space and delivered to mitochondria by Ca2+ leakage from inositol triphosphate receptors in mitochondria-associated membranes. This Ca2+ flux primes mitochondrial metabolism by maintaining glycolysis and keeping mitochondria energized for ATP production. We identified citrin, a well-defined Ca2+-binding component of malate-aspartate shuttle in the mitochondrial intermembrane space, as predominant target of this basal Ca2+ regulation. Our data emphasize that any manipulation of this ubiquitous Ca2+ system has the potency to initiate metabolic rewiring as an instant and reversible cellular adaptation to physiological or pathological stress.
Highlights
In contrast to long-term metabolic reprogramming, metabolic rewiring represents an instant and reversible cellular adaptation to physiological or pathological stress
In the remaining two-thirds of the cells perfused with Ca2+ free buffer, mitochondrial ATP production was significantly diminished (Fig. 2c)
We have deployed a common protocol of extracellular Ca2+ removal that allowed us to distinguish differential regulation of mitochondrial metabolism by basal subcellular Ca2+ homeostasis
Summary
In contrast to long-term metabolic reprogramming, metabolic rewiring represents an instant and reversible cellular adaptation to physiological or pathological stress. We reveal the existence of a basal Ca2+ flux originating from extracellular space and delivered to mitochondria by Ca2+ leakage from inositol triphosphate receptors in mitochondria-associated membranes This Ca2+ flux primes mitochondrial metabolism by maintaining glycolysis and keeping mitochondria energized for ATP production. Thereby Ca2+ passes the outer mitochondrial membrane (OMM) through voltage-dependent anion channels (VDACs)[11] into the mitochondrial inter-membrane space (IMS), where it needs to surpass a certain threshold to be taken up to mitochondrial matrix by mitochondrial calcium uniporter complex (MCUC)[12,13,14,15] This flux of Ca2+ from ER to mitochondria is known to regulate vital processes in the mitochondrial matrix, including the activity of Ca2+ sensitive mitochondrial dehydrogenases[16].
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