Intramembranous charge movements observed in frog twitch and slow muscle fibers are believed to play a role in contractile-activation. In both fiber types, charge movement consists of two components, the main Q-beta and a secondary Q-gamma. Both Q-beta and Q-gamma disappear when a twitch fiber is paralyzed by D600, and reappear when the fiber is revived. Three-microelectrode voltage clamp experiments will be performed to measure Q-beta and Q-gamma in a partially paralyzed or a revived twitch fiber in order to correlate these charge components with the contractile state of the fiber. Experiments using D890, TMB8 and other Ca++ blockers will also be performed to probe the site-of-action of the paralyzing agents and to see whether an entry of Ca++ is involved in paralysis. Results from these experiments might give clues concerning the physiological role of Q-beta and Q-gamma and, hopefully, help us understand how charge movement triggers calcium release. Injection of metallochromic calcium-indicators into twitch fibers have enabled muscle physiologists to monitor the rise in myoplasmic calcium level in the fibers during an action potential or a voltage clamp pulse. Experiments are planned to apply this optical technique to voltage-clamped slow fibers. Intensities of light beams at four different wavelengths and two states of polarization will be monitored simultaneously to give information about dye concentration, movement artifact and calcium transient. A direct comparison of the characteristics of calcium transient in slow fibers with that in twitch fibers might give additional support to the hypothesis that Q-gamma is responsible for triggering calcium release and, more importantly, help us to understand the comparative contractile behavior of the two types of fibers. Simultaneous measurements of charge movement and calcium signal will be performed on twitch fibers when they are either chronically depolarized, fatigued, partially paralyzed or revived. Pharmacological experiments will be done to investigate how Q-beta, Q-gamma and calcium signal simultaneously respond to the application of dantrolene sodium, tetracaine, dibucaine, intracellular EGTA, caffeine, perchlorate, formamide or hypertonicity. A few of these experiments will also be tried on slow fibers. The results will hopefully provide a direct link between charge movement and calcium signal, which is just the first step in my long term project designed to elucidate the complete sequence of events underlying excitation-contraction coupling in normal muscle so that ultimately we can understand what causes the diseases in striated muscles.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Modified Research Career Development Award (K04)
Project #
5K04NS000976-02
Application #
3074840
Study Section
Physiology Study Section (PHY)
Project Start
1985-07-01
Project End
1989-06-30
Budget Start
1986-07-01
Budget End
1987-06-30
Support Year
2
Fiscal Year
1986
Total Cost
Indirect Cost
Name
Indiana University-Purdue University at Indianapolis
Department
Type
Schools of Medicine
DUNS #
005436803
City
Indianapolis
State
IN
Country
United States
Zip Code
46202
Hui, C S; Chen, W (1992) Separation of Q beta and Q gamma charge components in frog cut twitch fibers with tetracaine. Critical comparison with other methods. J Gen Physiol 99:985-1016
Hui, C S; Chen, W (1992) Effects of conditioning depolarization and repetitive stimulation on Q beta and Q gamma charge components in frog cut twitch fibers. J Gen Physiol 99:1017-43
Hui, C S; Chandler, W K (1991) Q beta and Q gamma components of intramembranous charge movement in frog cut twitch fibers. J Gen Physiol 98:429-64
Hui, C S (1991) Factors affecting the appearance of the hump charge movement component in frog cut twitch fibers. J Gen Physiol 98:315-47
Hui, C S (1991) Comparison of charge movement components in intact and cut twitch fibers of the frog. Effects of stretch and temperature. J Gen Physiol 98:287-314
Maylie, J; Hui, C S (1991) Action of 2,3-butanedione monoxime on calcium signals in frog cut twitch fibres containing antipyrylazo III. J Physiol 442:551-67
Hui, C S; Maylie, J (1991) Multiple actions of 2,3-butanedione monoxime on contractile activation in frog twitch fibres. J Physiol 442:527-49
Chandler, W K; Hui, C S (1990) Membrane capacitance in frog cut twitch fibers mounted in a double vaseline-gap chamber. J Gen Physiol 96:225-56
Hui, C S (1990) D600 binding sites on voltage-sensors for excitation-contraction coupling in frog skeletal muscle are intracellular. J Muscle Res Cell Motil 11:471-88
Hui, C S; Chandler, W K (1990) Intramembranous charge movement in frog cut twitch fibers mounted in a double vaseline-gap chamber. J Gen Physiol 96:257-97

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