Chronic Alcohol Consumption, but not Acute Intoxication, Decreases In Vitro Skeletal Muscle Contractile Function.

Abstract

Skeletal muscle myopathy accompanying chronic alcohol misuse results in part from a decrease in protein synthesis typically observed in type II-rich muscles that leads to muscle weakness. However, there is a paucity of studies investigating whether the alcohol-induced weakness is intrinsic to the muscle or results primarily from the loss of muscle mass. The present study determines whether acute alcohol (ethanol) intoxication or chronic alcohol consumption decreases the intrinsic contractile function of muscle. Adult male mice were randomly assigned to the chronic alcohol group or given a binge dose of alcohol, and contractile characteristics of the extensor digitorum longus (EDL) were determined in vitro. The weight and physiological cross-sectional area (PCSA) of the EDL were decreased in alcohol-fed mice. Maximum twitch and tetanic tension were also reduced, and there was a downward shift of the absolute force-frequency curve in alcohol-fed mice. However, no alcohol-induced changes were noted when these contractile parameters were normalized for the lower PCSA. Alcohol-fed mice demonstrated greater fatigability, and alcohol-induced decreases in postfatigue specific twitch and tetanic force were independent of a decreased PCSA. Furthermore, postfatigue recovery of muscle force over time was reduced. While alcohol did not alter the content of high-energy phosphates or oxidative phosphorylation complexes I-V, it did reduce myosin heavy chain and troponin-T content. In contrast, contractile properties were not altered when examined 2hours after binge alcohol. These data demonstrate chronic alcohol consumption decreases isometric and tetanic tension development due to a reduction in muscle CSA, whereas the increased fatigability observed was independent of muscle mass. As none of the functional changes were produced by acute alcohol, which produced higher blood alcohol levels than chronic ingestion, our data suggest defects in intrinsic muscle contractility require sustained intake and appear independent of defects in basal energy production.