After a pre-perfusion
period of 10 min, juglone was infused during 30 min, followed by additional 20 min of drug-free perfusion. Four parameters AZD6738 molecular weight were measured: glucose release, lactate and pyruvate productions and oxygen consumption. As revealed by Fig. 2A all parameters were stable before the initiation of juglone infusion. Upon juglone infusion, oxygen uptake increased and remained so during the entire infusion period. Glucose release was increased with a peak value 50% above the basal values. Lactate production was also increased with peak values 60% above the basal rates. Pyruvate production increased slowly and at the end of the juglone infusion (40 min perfusion time) it was 90% above the basal value. After removing the drug from the perfusion liquid, stimulations of oxygen consumption and pyruvate production were maintained for at least 20 min, but glucose release and lactate production returned to their basal levels. Experiments like those illustrated in Fig. 2A were repeated with 10 and
20 μM juglone in order to establish concentration dependences for the effects. The mean values for each parameter at the end of the juglone infusion period (40 min perfusion time) were evaluated. Oxygen consumption, glycogenolysis [glucose release plus ½(pyruvate plus lactate productions)] and glycolysis (pyruvate plus lactate productions) were represented against the juglone concentration Selleck SB431542 in Fig. 2B. All stimulations present saturation, with little changes after 20 μM juglone. In Fig. 2C, the lactate to pyruvate ratio, second an indicator for the cytosolic NADH/NAD+ ratio (Scholz and Bücher, 1965), was plotted against the drug concentration. Juglone up to 20 μM increased the NADH/NAD+ ratio, but with 50 μM it returned to the value in the absence of juglone. Since juglone affects mitochondrial energy metabolism (Makawiti et al., 1990) it should also affect ATP-dependent pathways, such as gluconeogenesis and ureogenesis. Figs. 3A and B show results of experiments in which the action of juglone on lactate gluconeogenesis was measured. Livers from 18 h
fasted rats were used in order to minimize interference by glycogen catabolism. Fig. 3A illustrates the response of the perfused liver to juglone infusion at the concentration of 50 μM and it also represents a typical experimental protocol. After a pre-perfusion period of 10 min in the absence of substrate, 2 mM lactate was infused during 20 min, followed by additional 30 min of juglone plus lactate infusion. In the absence of juglone the infusion of 2 mM lactate produced rapid and sustained increases in both glucose production and oxygen uptake. The infusion of 50 μM juglone caused a progressive and, at the end, very strong decrease in glucose production. No recovery occurred during the 20 min following cessation of the drug infusion. Initially no changes in oxygen consumption were apparent when the juglone infusion was started.
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