Lactate metabolism: historical context, prior misinterpretations, and current understanding

Ferguson, Blake; Rogatzki, Matthew J.; Goodwin, Matthew L.; Kane, Daniel A.; Rightmire, Zachary; Gladden, L. Bruce

doi:10.1007/s00421-017-3795-6

Cited by 268 publications

(327 citation statements)

References 431 publications

Supporting

Mentioning

270

Contrasting

Unclassified

Order By: Relevance

“…Investigators have substantially revised their ideas about lack of oxygen as responsible for lactate production during exercise (Ferguson et al. ). Originally regarded as a “hypoxic waste product”, many clinicians still view lactate in this manner.…”

Section: Discussionmentioning

confidence: 99%

Normobaric hypoxic conditioning in men with metabolic syndrome

et al. 2018

View full text Add to dashboard Cite

The evidence that physical exercise lowers metabolic and cardiovascular risk is undisputed. Normobaric hypoxia training has been introduced to facilitate the effects of exercise. We tested the hypothesis that hypoxia training augments exercise‐related effects. We randomized 23 men with metabolic‐syndrome to single‐blinded exercise at normoxia (FiO2 21%) or hypoxia (FiO2 15%). Six weeks endurance training on a treadmill, 3 days per week, over 60 min at 60% VO 2max was required. The study included the following: (1) metabolic phenotyping by indirect calorimetry and adipose and muscle tissue microdialysis to gain insight into effects on resting, postprandial, and exercise metabolism, (2) cardiac imaging, and (3) biopsies. Primary endpoint was the change in cardiorespiratory fitness; secondary endpoints were as follows: changes in body weight, waist circumference, blood pressure, cardiac dimensions, and adipose and muscle tissue metabolism and gene expression. Our subjects reduced waist circumference and improved several cardiovascular risk markers including blood pressure. However, these effects were similar in both training groups. Cardiac dimensions were not influenced. We focused on glucose metabolism. After an oral glucose load, adipose tissue metabolism was significantly shifted to a more lipolytic state under hypoxia, whereas muscle metabolism was similar under both conditions. Postprandial energy expenditure was significantly increased under hypoxia, whereas activity energy expenditure was improved under normoxia. Gene expression was not consistently influenced by FiO2. Adipose tissue triglyceride lipase, leptin, and hypoxia‐inducible factor‐alpha expression were increased by normoxia but not hypoxia.

show abstract

Section: Discussionmentioning

confidence: 99%

Normobaric hypoxic conditioning in men with metabolic syndrome

et al. 2018

View full text Add to dashboard Cite

show abstract

“…Among these metabolic changes, blood acidosis has been identified in several in vitro and in vivo studies as a strong potential triggering factor for RBC sickling (Greenberg & Kass, ; Greenberg, Kass, & Castle, ; Lange, Minnich, & Moore, ). Given that muscle exercise is tightly linked to intra‐ and extracellular acidosis resulting from the non‐oxidative glycolytic processes of energy production (Bangsbo et al., ; Bangsbo, Johansen, Graham, & Saltin, ; Brooks, ; Ferguson et al., ; Hermansen & Osnes, ; Juel, ; Marcinek, Kushmerick, & Conley, ; Osnes & Hermansen, ; Sahlin, ; Sahlin, Alvestrand, Brandt, & Hultman, ; Sahlin, Harris, Nylind, & Hultman, ), one can wonder whether physical activity could be deleterious for SCD patients. To prevent the occurrence of any associated risks, extending our knowledge about the potential deleterious effects of muscle exercise in SCD patients is of great interest, particularly given that rehabilitation based on physical activity is increasingly considered as a potential therapeutic strategy in this pathology (Liem, Akinosun, Muntz, & Thompson, ; Martin et al., ).…”

Section: Sickle Cell Diseasementioning

confidence: 99%

Do we have to consider acidosis induced by exercise as deleterious in sickle cell disease?

Chatel

Messonnier

Bendahan

2018

Experimental Physiology

View full text Add to dashboard Cite

Sickle cell disease (SCD) is an inherited haemoglobin (Hb) disorder and the most common monogenic disease in the world. The root cause of this pathology is the synthesis of an abnormal Hb (HbS) that polymerizes in deoxygenated conditions, leading to the sickling of red blood cells. Acidosis is well recognized as a promoter of HbS polymerization and therefore red blood cell sickling. Indeed, it has been shown in vitro that the relative amount of sickled red blood cells increases markedly from 1% at pH 7.4 to >90% at pH 7.0. Nevertheless, no study has directly tested whether exercise-induced acidosis could favour SCD complications. Greater knowledge of the effects of metabolic acidosis during exercise could be of importance given the conclusions reached in several studies that proposed regular physical exercise as a therapeutic strategy in the management of SCD. In this review, we discuss the potential consequences of exercise-induced acidosis for the pathophysiology of SCD. We also propose some potential therapeutic interventions with the aim of reducing the metabolic acidosis related to exercise.

show abstract

“…While these studies certainly highlight the importance of lactate uptake in brain function, additional work is needed to parse the directionality of lactate transport and underlying mechanisms of neuroprotection. Considering the widespread controversy over the existence of the ANLS (Chih et al, ; Chih & Roberts, ; Dienel, ; Dienel & Cruz, ; Ferguson et al, ; Riske et al, ; Yellen, ), it is worthwhile to consider the underlying assumptions and open questions regarding the hypothesized model in which axons rely on oligodendrocyte‐derived lactate. Specifically, the current model rests on three primary assumptions: (a) post‐myelination oligodendrocytes favor aerobic glycolysis, leading to a high intracellular lactate concentration relative to the periaxonal space; (b) myelinated axons exhibit a low intracellular lactate concentration relative to the periaxonal space; and (c) myelinated axons metabolize oligodendrocyte‐derived lactate.…”

Section: Energetic Coupling Of Glia and Axonsmentioning

confidence: 99%

“…In order for lactate to be imported into myelinated axons, axonal lactate concentration must be low relative to the periaxonal space. As discussed previously, whether neurons primarily utilize oxphos or glycolysis and under what activation states is a highly controversial matter (Chih et al, ; Chih & Roberts, ; Dienel, ; Dienel & Cruz, ; Ferguson et al, ; Riske et al, ; Yellen, ). Considering the heterogenous findings between intracellular compartments and resting versus stimulated nerve cells, it seems imperative to interpret results only within the context measured.…”

Section: Energetic Coupling Of Glia and Axonsmentioning

confidence: 99%

“…As the vast majority of ANLS literature is not focused on white matter per se, we refer the reader to alternative sources for more exhaustive consideration of this hypothesis (Alberini, Cruz, Descalzi, Bessieres, & Gao, 2018; Barros, 2013;Dienel & McKenna, 2014;Pellerin & Magistretti, 2012;Riske et al, 2017;Tang, 2018;Weber & Barros, 2015). It is important to note the widespread controversy over the existence of the ANLS, with substantial debate around whether neurons actually export lactate during heightened activity, leading to substantial lactate efflux from the brain (Chih, Lipton, & Roberts, 2001;Chih & Roberts, 2003;Dienel, 2017;Dienel & Cruz, 2015;Ferguson et al, 2018;Riske et al, 2017;Yellen, 2018). Overall, significantly more work is needed in order to parse the influence of white matter astrocytes on modulating axonal energy metabolism.…”

Section: Energ E Ti C Coupling Of G Lia and A Xo N Smentioning

confidence: 99%

See 1 more Smart Citation

Mechanisms for the maintenance and regulation of axonal energy supply

Chamberlain

Sheng

2019

J of Neuroscience Research

View full text Add to dashboard Cite

The unique polarization and high‐energy demand of neurons necessitates specialized mechanisms to maintain energy homeostasis throughout the cell, particularly in the distal axon. Mitochondria play a key role in meeting axonal energy demand by generating adenosine triphosphate through oxidative phosphorylation. Recent evidence demonstrates how axonal mitochondrial trafficking and anchoring are coordinated to sense and respond to altered energy requirements. If and when these mechanisms are impacted in pathological conditions, such as injury and neurodegenerative disease, is an emerging research frontier. Recent evidence also suggests that axonal energy demand may be supplemented by local glial cells, including astrocytes and oligodendrocytes. In this review, we provide an updated discussion of how oxidative phosphorylation, aerobic glycolysis, and oligodendrocyte‐derived metabolic support contribute to the maintenance of axonal energy homeostasis.

show abstract

Lactate metabolism: historical context, prior misinterpretations, and current understanding

Cited by 268 publications

References 431 publications

Normobaric hypoxic conditioning in men with metabolic syndrome

Normobaric hypoxic conditioning in men with metabolic syndrome

Do we have to consider acidosis induced by exercise as deleterious in sickle cell disease?

Mechanisms for the maintenance and regulation of axonal energy supply

Contact Info

Product

Resources

About