Eukaryotic cells modulate their metabolism by organizing metabolic components in response to varying nutrient availability and energy demands. In rat axons, mitochondria respond to glucose levels by halting active transport in high glucose regions. We employ quantitative modeling to explore physical limits on spatial organization of mitochondria and localized metabolic enhancement through regulated stopping of processive motion. We delineate the role of key parameters, including cellular glucose uptake and consumption rates, that are expected to modulate mitochondrial distribution and metabolic response in spatially varying glucose conditions. Our estimates indicate that physiological brain glucose levels fall within the limited range neces...
National audienceEnergy intake is usually well regulated and finely adjusted to energy expenditure. ...
Although all brain cells bear in principle a comparable potential in terms of energetics, in reality...
<div><p>Although all brain cells bear in principle a comparable potential in terms of energetics, in...
Eukaryotic cells modulate their metabolism by organizing metabolic components in response to varying...
Neurons are large eukaryotic cells with high metabolic demands. Intracellular transport plays an imp...
Neurons are large eukaryotic cells with high metabolic demands. Intracellular transport plays an imp...
In this paper, we combined several mathematical models of cerebral metabolism and nutrient transport...
Neurons depend on mitochondria more than any other cell type for their growth and survival. Mitochon...
Many hereditary diseases are characterized by region-specific toxicity, despite the fact that diseas...
SummaryCells allocate substantial resources toward monitoring levels of nutrients that can be used f...
Neurons depend on mitochondria more than any other cell type for their growth and survival. Mitochon...
Synapses consume large amounts of energy, and energy supply to synaptic sites is critical for their...
Many hereditary diseases are characterized by region-specific toxicity, despite the fact that diseas...
<div><p>Many hereditary diseases are characterized by region-specific toxicity, despite the fact tha...
SummaryCells allocate substantial resources toward monitoring levels of nutrients that can be used f...
National audienceEnergy intake is usually well regulated and finely adjusted to energy expenditure. ...
Although all brain cells bear in principle a comparable potential in terms of energetics, in reality...
<div><p>Although all brain cells bear in principle a comparable potential in terms of energetics, in...
Eukaryotic cells modulate their metabolism by organizing metabolic components in response to varying...
Neurons are large eukaryotic cells with high metabolic demands. Intracellular transport plays an imp...
Neurons are large eukaryotic cells with high metabolic demands. Intracellular transport plays an imp...
In this paper, we combined several mathematical models of cerebral metabolism and nutrient transport...
Neurons depend on mitochondria more than any other cell type for their growth and survival. Mitochon...
Many hereditary diseases are characterized by region-specific toxicity, despite the fact that diseas...
SummaryCells allocate substantial resources toward monitoring levels of nutrients that can be used f...
Neurons depend on mitochondria more than any other cell type for their growth and survival. Mitochon...
Synapses consume large amounts of energy, and energy supply to synaptic sites is critical for their...
Many hereditary diseases are characterized by region-specific toxicity, despite the fact that diseas...
<div><p>Many hereditary diseases are characterized by region-specific toxicity, despite the fact tha...
SummaryCells allocate substantial resources toward monitoring levels of nutrients that can be used f...
National audienceEnergy intake is usually well regulated and finely adjusted to energy expenditure. ...
Although all brain cells bear in principle a comparable potential in terms of energetics, in reality...
<div><p>Although all brain cells bear in principle a comparable potential in terms of energetics, in...
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