inosinic-acid and fructose-6-phosphate

The alterations in muscle metabolism were investigated in response to repeated sessions of heavy intermittent exercise performed over 16 h. Tissue samples were extracted from the vastus lateralis muscle before (B) and after (A) 6 min of cycling at approximately 91% peak aerobic power at repetitions one (R1), two (R2), nine (R9), and sixteen (R16) in 13 untrained volunteers (peak aerobic power = 44.3 +/- 0.66 mL.kg-1.min-1, mean +/- SE). Metabolite content (mmol.(kg dry mass)-1) in homogenates at R1 indicated decreases (p < 0.05) in ATP (21.9 +/- 0.62 vs. 17.7 +/- 0.68) and phosphocreatine (80.3 +/- 2.0 vs. 8.56 +/- 1.5) and increases (p < 0.05) in inosine monophosphate (IMP, 0.077 +/- 0.12 vs. 3.63 +/- 0.85) and lactate (3.80 +/- 0.57 vs. 84.6 +/- 10.3). The content (micromol.(kg dry mass)-1) of calculated free ADP ([ADPf], 86.4 +/- 5.5 vs. 1014 +/- 237) and free AMP ([AMPf], 0.32 +/- 0.03 vs. 78.4 +/- 31) also increased (p < 0.05). No differences were observed between R1 and R2. By R9 and continuing to R16, pronounced reductions (p < 0.05) at A were observed in IMP (72.2%), [ADPf] (58.7%), [AMPf] (85.5%), and lactate (41.3%). The 16-hour protocol resulted in an 89.7% depletion (p < 0.05) of muscle glycogen. Repetition-dependent increases were also observed in oxygen consumption during exercise. It is concluded that repetitive heavy exercise results in less of a disturbance in phosphorylation potential, possibly as a result of increased mitochondrial respiration during the rest-to-work non-steady-state transition.

Topics: Adenine Nucleotides; Adenosine Triphosphate; Adult; Bicycling; Chromatography, High Pressure Liquid; Creatine; Electron Transport Complex IV; Exercise; Female; Fructosephosphates; Glucose-6-Phosphate; Glycogen; Glycolysis; Humans; Inosine Monophosphate; Lactates; Male; Muscle, Skeletal; Oxygen Consumption; Phosphocreatine; Physical Exertion; Pyruvates; Rest; Succinate Dehydrogenase; Time Factors

In this study we have revised our original procedure of yeast metabolites extraction. We showed that: (a) less than 5% of intracellular metabolites leaks out during the step of rapid arrest of cellular metabolism by quenching yeast cells into a 60% methanol solution kept at -40 degrees C; and (b) with a few exception, the stability of metabolites were not altered during the 3 min boiling procedure in a buffered ethanol solution. However, there was a loss of external added metabolites of 5-30%, depending on the type of metabolites. This was mainly attributable to their retention on cellular debris after ethanol treatment, which prevented centrifugation of the cellular extracts before evaporation of ethanol. We further simplified our previous high-performance ionic chromatography (HPIC) techniques for easier, more reliable and robust quantitative measurements of organic acids, sugar phosphates and sugar nucleotides, and extended these techniques to purine and pyrimidine bases, using a variable wavelength detector set at 220 and 260 nm in tandem with a pulsed electrochemical or suppressed conductivity detector. These protocols were successfully applied to a glucose pulse to carbon-limited yeast cultures on purines metabolism. This study showed that glucose induced a fast activation of the purine salvage pathway, as indicated by a transient drop of ATP and ADP with a concomitant rise of IMP and inosine. This metabolic perturbation was accompanied by a rapid increase in the activity of the ISN1-encoded specific IMP-5'-nucleotidase. The mechanism of this activation remains to be determined.

Topics: Adenine Nucleotides; Analytic Sample Preparation Methods; Fructosephosphates; Fumarates; Glucose; Glucose-6-Phosphate; Glucosephosphates; Inosine; Inosine Monophosphate; Pyruvic Acid; Saccharomyces cerevisiae; Sugar Phosphates; Trehalose

The relationship between muscle glycogen concentration and the rate of glycogen breakdown during short, intense contraction has been investigated in man. Prior to the experiment, muscle glycogen content was manipulated by a combination of exercise and diet, and varied from 155 +/- 19 to 350 +/- 25 mmol kg-1 dry muscle (36-81 mmol kg-1 wet wt). The quadriceps femoris muscle was stimulated electrically at a frequency of 20 Hz for 1 min. The blood flow to the leg was occluded during the experiment and muscle biopsies were taken before and after 10, 30 and 60 s stimulation. Force development and glycogenolytic rate were maintained constant during electrical stimulation and similar in all conditions, irrespective of the initial glycogen concentration. The phosphorylase a fraction was increased after 10 s stimulation, but returned to the initial values at the end of the stimulation. Muscle ATP was unaltered during the first 30 s stimulation, but decreased thereafter. The decrease in ATP was accompanied by a stoichiometric increase in inosine monophosphate. Phosphocreatine decreased during stimulation and was almost depleted at the end of stimulation. Muscle lactate and glucose 6-phosphate (Glu 6-P) increased during stimulation. None of these changes was significantly affected by the reduced glycogen contents. It is concluded that the rate of muscle glycogen breakdown is not affected by the initial glycogen level in the range of 155 +/- 19 to 350 +/- 25 mmol kg-1 dry muscle.

Topics: Adenosine Triphosphate; Adolescent; Adult; Electric Stimulation; Fructosephosphates; Glucose-6-Phosphate; Glucosephosphates; Glycogen; Humans; Inosine Monophosphate; Lactates; Lactic Acid; Male; Muscles; Phosphocreatine; Phosphorylase a