Sliding Filament Theory

Subdecks (1)

structure of myosin 
hinged, globular heads with binding sites for actin and ATP; filament formed by tails of several hundred myosin molecules
structure of actin 
molecules wrapped around each other, myosin binding sites blocked by tropomyosin, so filaments cannot slide without impulse
what is the structure of a myofibril 
actin molecules wrapped around each other, with a molecule of tropomyosin, which is held in place by troponin
1 - Ca2+ ions move in from sarcoplasmic reticulum, due to electrical impulse, and bind to troponin molecules
2 - troponin changes shape, which displaces the tropomyosin and exposes the myosin binding sites
3 - heads of myosin attach to the newly exposed binding sites on actin, called crossbridging
4 - myosin heads change position, causes the actin filament to slide, ADP released
5 - ATP binds to myosin heads, causing them to detach from the actin
6 - ATP then hydrolysed into ADP and a phosphate molecule, allowing the heads to resume resting position
creatine phosphate is a reserve supply of phosphate to bind with ADP, which is quickly used up
why is glucose needed for skeletal muscle contraction
glucose respired to form ATP
ATP needed to break cross-bridges between actin and myosin
ATP hydrolysed into ADP and Pi - to reset myosin heads
ATP for active transport of Ca 2+ ions back into sarcoplasmic reticulum