Muscle Physiology

Question 1

structure of skeletal muscle

Answer 1

Question 2

structure of skeletal muscle

Answer 2

Question 3

structure of skeletal muscle

Answer 3

Question 4

skeletal muscle cells

Answer 4

skeletal muscle cells are long and cylindrical - length = 1-12 cm

they are striated (banding pattern under light microscopy)

striations caused by the arragement of the thin and thick myofilaments

they are multinucleated and contain a lot of mitocondria

number of cells depends on size of muscle

Question 5

structure of skeletal muscle fiber

Answer 5

Question 6

myofibrils and myofilaments

Answer 6

a muscle cell/fiber is composed of a bundle of myofibrils

myofibril = organelle composed of bundles of myofilaments

striated appearance - darker and lighter bands

composed of repeating units of contractile proteins = sarcomeres = contractile unit of myofibril

~100,000 sarcomeres in bicep branchii from one end to the other

Question 7

thin myofilaments

Answer 7

actin (G-actin) - globular protein linked to form helical strands

• each has one myosin binding site
• associated with two regulatory proteins

tropomyosin - rod-shaped protein composed of two alpha helical chains wrapped in a supercoil

• found in grooves made by actin
• partically covers the myosin binding site

troponin - three-protein complex attatched to both actin and tropomyosin

• holds tropomyosin over myosin binding site on actin

Troponin A - binds to actin

Troponin C - binds calcium

Troponin T - binds tropomyosin

Question 8

thick myofilaments

Answer 8

myosin - protein made of two polypeptide strands, each forming part of the tail, hinge, arm and head

• thick myofilaments are made of many individual myosin molecules
• head has an actin binding site and an ATP binding site (location of ATPase)
• undergoes conformational change to generate contraction

Question 9

myosin molecule

Answer 9

each myosin molecule is made of 2 long polypeptide chains each forming part of the tail and one head of the myosin molecule

each myosin head contains:

• a binding site for actin and ATP (ATPase)

Question 10

thin and thick myofilament in sarcomere

Answer 10

Question 11

sliding filament theory

Answer 11

myosin binds to actinm forming a cross-bridge

myosin heads undergo power-strokes

thin filament slides over thick filament

sarcomere shortens - muscle contracts

thin and thick myofilament length do not change

sarcomere length does change

Question 12

neuromuscular junction

Answer 12

Question 13

neuromuscular junction

Answer 13

1. action potential travels down motor neuron, to presynaptic terminal
2. activation and opening of the voltage-gated Ca²⁺ channels
3. ACh-containing vesicles fuse with the post-synaptic membrane and release ACh
4. binding of neurotransmitter to ligand-gated ion channels on muscle
   - change in membrane permeability
   - opening of ion channels
5. ACh broken down by acetylcholinesterase

Question 14

excitation-contraction coupling

Answer 14

where an action potential on the sarcolemma of the muscle cell leads to the release of Ca⁺⁺ from the sarcoplasmic reticulum (SR), leading to crossbridge activity and muscle contraction

Question 15

the neuromuscular junction

Answer 15

step 1 - the neuromuscular junction (NMJ)

1. action potential travels down motor neuron, to presynaptic terminal
2. activation and opening of the voltage-gated Ca²⁺ channels
3. Ach-containing vesicles fuse with the post-synaptic membrane and release ACh
4. binding of neurotrasmitter to ligand-gated ion channels on muscle
   - change in membrane permeability
   - opening of ion channels
5. ACh broken down by acetylcholinesterase

Question 16

excitation contraction coupling (step 1,2)

Answer 16

1. AP generated at end plate of the muscle cell (End Plate Potential)
2. AP propagates over sarcolemma and down T-tubules

Question 17

excitation contraction coupling (step 3,4,5)

Answer 17

3. voltage sensors on T-tubule detects AP and changes shape
4. Voltage sensor opens Ca2+ release channels on lateral sac of SR, Ca2+ is released from SR
5. Ca2+ binds to troponin pulling tropomyosin off the myosin binding sites found on actin

Question 18

excitation contraction coupling (step 6,7)

Answer 18

6. myosin attaches to actin (crossbridge formation) and power stroke occurs
7. thin filaments slides over thick filament and muscle contracts (sliding filaments - sarcomeres shorten)

Question 19

How the muscle contraction stops

Answer 19

8. Ca²⁺ is actively pumped back into SR by Ca²⁺ ATPase
9. when Ca²⁺ is “removed”, tropomyosin covers myosin binding sites
10. muscle relaxes

Question 20

from NMJ signaling to muscle contraction

Answer 20

1. AP travels down the motor neuron, causing ACh release
2. AP travels down the T-tubule, to voltage sensor
3. Voltage sensor changes conformation (shape)
4. voltage sensor opens Ca²⁺ channel on SR and Ca²⁺ is released
5. Ca²⁺ binds to troponin C, exposing the myosin binding site on actin
   5a. myosin attaches to actin, forming a crossbridge and power stroke
   5b. filaments slide past each other, shortening sarcomere - muscle contraction
6. Ca²⁺ is recycled back into the SR through the Ca²⁺ ATPase

Question 21

actin-myosin-ATP cycle

Answer 21

1. ATP has just attached to myosin, myosin is not attached to actin
2. ATP is hydrolyzed to ADP and P_i; energy is transferred to myosin head; myosin now has high affinity for actin; myosin head is repositioned

between 2-3. AP causes Ca^₂₊ release from SR; Ca²⁺ binds to troponin -> pulls tropomyosin off myosin binding sites; myosin binding sites; myosin attaches to actin forming crossbridge; no powerstroke yet

3. P_i is released; powerstroke is triggered; muscle contraction occurs
4. ADP is released; crossbridges still formed
5. new molecule of ATP attaches to myosin; cross-bridge breaks; cycle repeats

the cycle keeps going as long as there is ATP and Ca²⁺

Question 22

rigor mortis

Answer 22

the stiffening of muscles after death

• begins 3-4 hrs after death; reaches a maximum at 12 hrs; slowly disappears over next 24-48 hrs

cause

• no oxygen -> no ATP; no ATP -> Ca²⁺ cant be pumped back into SR -> crossbridges form
• no ATP -> actin and myosin cant dissociate -> muscle permanently fused until muscle decomposition

Question 23

the motor unit

Answer 23

motor unit - one motor neuron + muscle fibers it innervates

one AP in motor neuron results in one ATP in all the muscle fibers it innervates

Question 24

muscle twitch

Answer 24

twitch - muscle contraction in response to one action potential on the motor neuron

latency - time between an AP and the initiation of contraction

Contraction time (CT) vs relaxation time (RT)

duration of twitch 10-100 ms - depends on fiber type

Question 25

grading muscle contraction

Answer 25

grading muscle contration: increased force of contraction

motor unit recuitment: as more motor units are recuited, more muscle fibers contract - higher contractile force

summation of twitch contractions: increased stimulus frequency

Question 26

motor unit recuitment

Answer 26

motor unit recuitment - as more motor units are recuited, more muscle fibers contract - higher contractile force

Question 27

summation

Answer 27

as summation (AP) frequency is increased, each muscle twitch has less “time” to relax before the next one occurs

-> twitch start to “stack up” on one another causing a more forceful contraction

Question 28

unfused tetanus

Answer 28

increasing AP frequency increases the force of contraction

medium - high frequency - still some time to relax before next twitch

-> unfused tetanus

Question 29

complete tetanus

Answer 29

at very high frequencies

• no time to relax between twitches
• all twitches summate to produce smooth sustained contraction called complete tetanus