The potential mechanisms of lactate in mediating exercise-enhanced cognitive function: a dual role as an energy supply substrate and a signaling molecule

The potential mechanisms of lactate in mediating exercise-enhanced cognitive function: a dual role as an energy supply substrate and a signaling molecule

Lactate has previously been considered a metabolic waste and is mainly involved in exercise-induced fatigue. However, recent studies have found that lactate may be a mediator of the beneficial effects of exercise on brain health. Lactate plays a dual role as an energy supply substrate and a signalin...

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Published in:Nutrition & metabolism Vol. 19; no. 1; pp. 1 - 52
Main Authors: Xue, Xiangli, Liu, Beibei, Hu, Jingyun, Bian, Xuepeng, Lou, Shujie
Format: Journal Article
Language:English
Published: London BioMed Central Ltd 30-07-2022
BioMed Central
BMC
Subjects:
Adenosine triphosphate
Aging
Alzheimer's disease
Anaerobic threshold
Angiogenesis
Astrocyte-neuron metabolic coupling
Astrocytes
Brain
Brain research
Cellular signal transduction
Cognition
Cognitive ability
Cognitive function
Dehydrogenases
Dementia
Energy
Energy metabolism
Enzymes
Exercise
Exercise intervention
Glucose
Glycogen
Glycolysis
Health aspects
Health care
Hypotheses
Immediate-early proteins
Kinases
Lactate receptor HCAR1/GPR81
Lactate shuttle
Lactates
Lactic acid
Metabolic regulation
Metabolism
Metabolites
Musculoskeletal system
Neural plasticity
Neurons
Physical fitness
Physiological aspects
Physiological research
Review
Signal transduction
Skeletal muscle
China
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Summary:Lactate has previously been considered a metabolic waste and is mainly involved in exercise-induced fatigue. However, recent studies have found that lactate may be a mediator of the beneficial effects of exercise on brain health. Lactate plays a dual role as an energy supply substrate and a signaling molecule in this process. On the one hand, astrocytes can uptake circulating glucose or degrade glycogen for glycolysis to produce lactate, which is released into the extracellular space. Neurons can uptake extracellular lactate as an important supplement to their energy metabolism substrates, to meet the demand for large amounts of energy when synaptic activity is enhanced. Thus, synaptic activity and energy transfer show tight metabolic coupling. On the other hand, lactate acts as a signaling molecule to activate downstream signaling transduction pathways by specific receptors, inducing the expression of immediate early genes and cerebral angiogenesis. Moderate to high-intensity exercise not only increases lactate production and accumulation in muscle and blood but also promotes the uptake of skeletal muscle-derived lactate by the brain and enhances aerobic glycolysis to increase brain-derived lactate production. Furthermore, exercise regulates the expression or activity of transporters and enzymes involved in the astrocyte-neuron lactate shuttle to maintain the efficiency of this process; exercise also activates lactate receptor HCAR1, thus affecting brain plasticity. Rethinking the role of lactate in cognitive function and the regulatory effect of exercise is the main focus and highlights of the review. This may enrich the theoretical basis of lactate-related to promote brain health during exercise, and provide new perspectives for promoting a healthy aging strategy.
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ISSN:1743-7075
1743-7075
DOI:10.1186/s12986-022-00687-z