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Combined in vivo and in silico investigations of activation of glycolysis in contracting skeletal muscle

Schmitz, J. P. J., Groenendaal, W., Wessels, B., Wiseman, R. W., Hilbers, P. A. J., Nicolay, K., Prompers, J. J., Jeneson, J. A. L. & van Riel, N. A. W., Jan-2013, In : American journal of physiology-Cell physiology. 304, 2, p. C180-C193 14 p.

Research output: Contribution to journalArticleAcademicpeer-review

  • J. P. J. Schmitz
  • W. Groenendaal
  • B. Wessels
  • R. W. Wiseman
  • P. A. J. Hilbers
  • K. Nicolay
  • J. J. Prompers
  • J. A. L. Jeneson
  • N. A. W. van Riel

Schmitz JP, Groenendaal W, Wessels B, Wiseman RW, Hilbers PA, Nicolay K, Prompers JJ, Jeneson JA, van Riel NA. Combined in vivo and in silico investigations of activation of glycolysis in contracting skeletal muscle. Am J Physiol Cell Physiol 304: C180-C193, 2013. First published October 31, 2012; doi:10.1152/ajpcell.00101.2012.-The hypothesis was tested that the variation of in vivo glycolytic flux with contraction frequency in skeletal muscle can be qualitatively and quantitatively explained by calcium-calmodulin activation of phosphofructokinase (PFK-1). Ischemic rat tibialis anterior muscle was electrically stimulated at frequencies between 0 and 80 Hz to covary the ATP turnover rate and calcium concentration in the tissue. Estimates of in vivo glycolytic rates and cellular free energetic states were derived from dynamic changes in intramuscular pH and phosphocreatine content, respectively, determined by phosphorus magnetic resonance spectroscopy (P-31-MRS). Computational modeling was applied to relate these empirical observations to understanding of the biochemistry of muscle glycolysis. Hereto, the kinetic model of PFK activity in a previously reported mathematical model of the glycolytic pathway (Vinnakota KC, Rusk J, Palmer L, Shankland E, Kushmerick MJ. J Physiol 588: 1961-1983, 2010) was adapted to contain a calcium-calmodulin binding sensitivity. The two main results were introduction of regulation of PFK-1 activity by binding of a calcium-calmodulin complex in combination with activation by increased concentrations of AMP and ADP was essential to qualitatively and quantitatively explain the experimental observations. Secondly, the model predicted that shutdown of glycolytic ATP production flux in muscle postexercise may lag behind deactivation of PFK-1 (timescales: 5-10 s vs. 100-200 ms, respectively) as a result of accumulation of glycolytic intermediates downstream of PFK during contractions.

Original languageEnglish
Pages (from-to)C180-C193
Number of pages14
JournalAmerican journal of physiology-Cell physiology
Volume304
Issue number2
Publication statusPublished - Jan-2013

    Keywords

  • glycolysis, skeletal muscle, calcium regulation, P-31-MRS, computational modeling, systems biology, HIGH-INTENSITY EXERCISE, CALMODULIN ANTAGONISTS, METABOLIC PATHWAYS, ANTERIOR MUSCLE, CELL VIABILITY, MELANOMA-CELLS, BINDING-SITES, PHOSPHOFRUCTOKINASE, RECOVERY, ATP

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