Muscle glycogen unavailability and fat oxidation rate during exercise: Insights from McArdle disease

Abstract: Carbohydrate availability affects fat metabolism during exercise; however, the effects of complete muscle glycogen unavailability on maximal fat oxidation (MFO) rate remain unknown. Our purpose was to examine the MFO rate in patients with McArdle disease, comprising an inherited condition caused by complete blockade of muscle glycogen metabolism, compared to healthy controls. Nine patients (three women, aged 36 ± 12 years) and 12 healthy controls (four women, aged 40 ± 13 years) were studied. Several molecular… Show more

“…The study by Rodriguez‐Lopez et al. (2022) provides important additional observations to this understanding by showing that the patients with McArdle disease demonstrate very high fat oxidation rates at exercise intensities close to their maximal. The patients reached a maximal fat oxidation rate of 0.53 g min −1 , which was around 60% higher than the healthy controls (0.33 g min −1 ) included in the study.…”

“…The study by Rodriguez‐Lopez et al. (2022) clearly demonstrates that, despite a low aerobic capacity, patients with McArdle disease possess a very high maximal fat oxidation rate. To understand this phenomenon better, Rodriguez‐Lopez et al.…”

“…To understand this phenomenon better, Rodriguez‐Lopez et al. (2022) included assessments of key regulatory proteins in fat metabolism in muscles from a validated mouse model of McArdle disease and found no increase in a fatty acid transporter protein (CD36) or in lipolytic capacity (hormone‐sensitive lipase), and even found a decreased mitochondrial capacity (as suggested by lower levels of 3‐hydroxyacyl‐CoA dehydrogenase). Therefore, the results from the study by Rodriguez‐Lopez et al.…”

“…Therefore, the results from the study by Rodriguez‐Lopez et al. (2022) pave the way for investigating other potential regulatory steps in fat metabolism, such as carnitine palmitoyl transferase I and the mobilization of fatty acids from intramuscular lipid droplets to mitochondria, which is probably influenced by lipid droplet–mitochondrial interactivity and regulatory proteins as perilipins.…”

“…2022) included assessments of key regulatory proteins in fat metabolism in muscles from a validated mouse model of McArdle disease and found no increase in a fatty acid transporter protein (CD36) or in lipolytic capacity (hormone-sensitive lipase), and even found a decreased mitochondrial capacity (as suggested by lower levels of 3-hydroxyacyl-CoA dehydrogenase). Therefore, the results from the study by Rodriguez-Lopez et al (2022) pave the way for investigating other potential regulatory steps in fat metabolism, such as carnitine palmitoyl transferase I and the mobilization of fatty acids from intramuscular lipid droplets to mitochondria, which is probably influenced by lipid droplet-mitochondrial interactivity and regulatory proteins as perilipins. The results conform with findings from healthy individuals, where a low muscle glycogen level is strongly associated with a high fat oxidation rate (Arkinstall et al, 2004).…”

An experiment of nature links muscle glycogen unavailability with very high fat oxidation rates despite low aerobic fitness

“…The study by Rodriguez‐Lopez et al. (2022) provides important additional observations to this understanding by showing that the patients with McArdle disease demonstrate very high fat oxidation rates at exercise intensities close to their maximal. The patients reached a maximal fat oxidation rate of 0.53 g min −1 , which was around 60% higher than the healthy controls (0.33 g min −1 ) included in the study.…”

“…The study by Rodriguez‐Lopez et al. (2022) clearly demonstrates that, despite a low aerobic capacity, patients with McArdle disease possess a very high maximal fat oxidation rate. To understand this phenomenon better, Rodriguez‐Lopez et al.…”

“…To understand this phenomenon better, Rodriguez‐Lopez et al. (2022) included assessments of key regulatory proteins in fat metabolism in muscles from a validated mouse model of McArdle disease and found no increase in a fatty acid transporter protein (CD36) or in lipolytic capacity (hormone‐sensitive lipase), and even found a decreased mitochondrial capacity (as suggested by lower levels of 3‐hydroxyacyl‐CoA dehydrogenase). Therefore, the results from the study by Rodriguez‐Lopez et al.…”

“…Therefore, the results from the study by Rodriguez‐Lopez et al. (2022) pave the way for investigating other potential regulatory steps in fat metabolism, such as carnitine palmitoyl transferase I and the mobilization of fatty acids from intramuscular lipid droplets to mitochondria, which is probably influenced by lipid droplet–mitochondrial interactivity and regulatory proteins as perilipins.…”

“…2022) included assessments of key regulatory proteins in fat metabolism in muscles from a validated mouse model of McArdle disease and found no increase in a fatty acid transporter protein (CD36) or in lipolytic capacity (hormone-sensitive lipase), and even found a decreased mitochondrial capacity (as suggested by lower levels of 3-hydroxyacyl-CoA dehydrogenase). Therefore, the results from the study by Rodriguez-Lopez et al (2022) pave the way for investigating other potential regulatory steps in fat metabolism, such as carnitine palmitoyl transferase I and the mobilization of fatty acids from intramuscular lipid droplets to mitochondria, which is probably influenced by lipid droplet-mitochondrial interactivity and regulatory proteins as perilipins. The results conform with findings from healthy individuals, where a low muscle glycogen level is strongly associated with a high fat oxidation rate (Arkinstall et al, 2004).…”

An experiment of nature links muscle glycogen unavailability with very high fat oxidation rates despite low aerobic fitness

Dose–response effect of pre-exercise carbohydrates under muscle glycogen unavailability: Insights from McArdle disease

Metabolic aspects of glycogenolysis with special attention to McArdle disease