Metabolic and hormonal responses to exercise in partially hepatectomised rats

The contribution of afferent signals from the liver to metabolic regulation during exercise

The crucial role of the liver as the only organ to produce glucose used by skeletal muscle during exercise is well known. Since hepatic glucose production is central to blood glucose homeostasis during exercise, it has been postulated that the liver may inform the central nervous system and other organs of its diminishing capacity to produce glucose from glycogen, before blood glucose falls. The sensory role of the liver during exercise would be similar to its role in the control of food intake. As a consequence, the experimental approaches used to test the hypothesis that afferent signals from the liver contribute to metabolic regulation during exercise are inspired by those used to test the same hypothesis in the regulation of food intake. In the present review, two questions are addressed. The existing evidence for the liver's sensory influence on metabolic adjustments to exercise is first reviewed; the nature of the initiating stimuli for the afferent contribution of the liver to physical exercise is discussed thereafter. The hypothetical construct upon which rests the contribution of the liver's afferent signals to metabolic regulation during exercise is that a decrease in liver glycogen or a related metabolic intermediate is sensed by the liver, and the signal is transduced to the central nervous system, most likely through the afferent activity of the hepatic vagus nerve, where it contributes to the orchestration of the metabolic and hormonal responses to exercise. Support in favour of this construct comes mainly from the demonstration that sectioning of the hepatic vagus nerve attenuates the normal hormonal response to exercise. It seems that the liver-glucagon axis is particularly responsive to this reflex activation. In other respects, the hepatic mechanism responsible for linking the metabolic activity in the liver to an afferent signal capable of regulating the metabolic response to exercise remains speculative. Substrates or derivatives of substrate oxidation, energy-related compounds (ATP and Pi), or changes in cell volume may all be related to changes in transmembrane potential in the liver cell, which according to the "potentiostatic" theory would determine the afferent vagal activity.

Evidence that the decrease in liver glycogen is associated with the exercise-induced increase in IGFBP-1

The purpose of the present study was to test the hypothesis that the exercise-induced increase in insulin-like growth factor binding protein (IGFBP)-1 is not always linked to a decrease in blood glucose level and to examine whether the decreasing levels of liver glycogen during exercise may be associated with the increase in IGFBP-1. Three groups of rats were submitted to a 70-min treadmill exercise. One group of rats was fed normally, and the two other groups had their food intake restricted by 50% (50% fast) the night before the experiment. One of these two 50% fasted groups of rats was infused (intravenously) with glucose throughout exercise to maintain euglycemia. Exercise in noninfused 50% fasted rats, compared with the normally fed rats, resulted in significantly lower blood glucose (minute 70) and insulin levels, significantly lower liver glycogen content, no change in IGF-I, and significantly higher increases in free fatty acid, glycerol, beta-hydroxybutyrate, and IGFBP-1. Maintenance of euglycemia during exercise in glucose-infused 50% fasted rats reduced to a large extent the decrease in insulin levels but only slightly attenuated the lipid response and the IGFBP-1 response seen in noninfused 50% fasted rats. Comparisons of all individual liver glycogen and IGFBP-1 values revealed that liver glycogen values were highly (P < 0.001) predictive of the IGFBP-1 response during exercise (R = 0.564). The present results indicate that the IGFBP-1 response during exercise is not always linked to a decrease in plasma glucose and suggest that the increase in IGFBP-1 during exercise may be related to the decrease in liver glycogen content.

Effects of phosphate injection on metabolic and hormonal responses to exercise in fructose-injected rats

The purpose of the present study was to evaluate the effects of an intraperitoneal injection of sodium phosphate on the metabolic and hormonal responses to exercise. Fructose-injected rats were either injected with sodium phosphate (Na2HPO4) or NaCl, either in a fed or in a food-restricted state (24 h), and evaluated at rest or after a 30-min exercise period (26 m/min; 0% grade). Liver ATP, phosphate (Pi), and glycogen concentrations were, on the whole, significantly (p < 0.05) higher in Na2HPO4 than in NaCl groups. Exercise resulted in a significant (p < 0.01) decrease in liver ATP and glycogen levels in fed and food-restricted rats whether injected with NaCl or Na2HPO4. Exercise, after NaCl and Na2HPO4 injection, resulted in a significant (p < 0.01) increase in liver phosphate and Pi/ATP ratio, and in a decrease in glucose and an increase in glucagon levels in food-restricted rats only. The normal exercise-induced increase in plasma FFA, glycerol, and norepinephrine levels (p < 0.05), observed in both fed and food-restricted NaCl-injected rats, was abolished by the injection of phosphate. The data are in line with the new concept that in addition to blood glucose levels, the increase in liver Pi/ATP ratio could also contribute to the increase in glucagon response during exercise.