skeletal muscle structure and function Flashcards
give the 4 pieces of evidence for the sliding filament theory during contraction of sarcomere
how do these pieces of evidence support the sliding filament theory
- H zone shortens
- I band shortens
- Z lines move closer together
- A band stays the same length (as the myosin filament)
this provides evidence that the filaments do not contract but do slide over each other
why does the A band not change length in the contraction of a sarcomere
the A band is the same width as the myosin filament
what 3 proteins are involved in muscle contraction
myosin
actin
tropomyosin
how does myosins structure allow it to perform its role in muscle contraction
filaments contain many globular heads attached by a hinge (tail) - this enables them to move back and forth
each globular head has a binding site for actin and one for ATP
how many binding sites does each myosin head have and what binds to them
each myosin globular head has a binding site for actin and one for ATP
how does actins structure allow it to perform its role in muscle contraction
filaments have binding sites for myosin heads called actin - myosin binding site
how does tropomyosins structure allow it to perform its role in muscle contraction
it is a protein found between actin molecules
it blocks the binding sites when muscle isn’t contracting
what are the 3 stages to muscle contraction
- stimulation
- contraction
- relaxation
explain the process of stimulation of muscle contraction
- action potential reaches neuromuscular junction
- causes Ca2+ ion channels to open
- Ca2+ diffuses into the synaptic knob causing synaptic vesicles to fuse with presynaptic membrane
- release ACh into the synaptic cleft
- ACh diffuses across cleft and binds to receptors on muscle fibre causing depolarisation due to influx of Na+
- action potential spreads through transverse tubules (T) causing Ca2+ ions to be released from sarcoplasmic reticulum into sarcoplasm
state 2 functions of Ca2+ in stimulation of muscle contraction
- causes synaptic vesicles to fuse with presynaptic membrane
- diffuse out of sarcoplasmic reticulum into sarcoplasm
what happens to ACh after it has bound to receptors on sarcolemma
(2 marks)
- hydrolysed by acetylcholinesterase into ethanoic acid (acetic acid) and choline
- reabsorbed into presynaptic membrane and reformed into ACh using ATP
state the structure through which an action potential travels within muscle cell fibres
Tranverse (T) tubules
name 2 types of transport involved in movement of ACh at neuromuscular junction
diffusion
exocytosis
binding of ACh causes influx of which ions causing depolarisation
Na+
explain the process of muscle contraction
- (Ca2+ in sarcoplasmic reticulum diffuse into sarcoplasm)
Ca2+ bind to tropomyosin causing it to change shape and expose myosin binding site on actin filament - the globular heads of myosin molecules bind to actin forming cross bridges (actinomyosin complex) between the 2 filaments
- myosin heads move together and pull actin filaments toward the middle of the sarcomere causing it to contract - “power stroke”
this causes ADP to be released - another ATP binds to the myosin head and Ca2+ ions activate ATPase to hydrolyse it to ADP and Pi
- this provides the energy for myosin heads to detach from actin and move back to their original position
- myosin heads then bind to a new site further along actin, pulling it and causing further shortening of sarcomere
this process is repeated causing sarcomere to shorten
