Muscle Physiology

Question 1

Approximately how many nerve fibers innervate each muscle fiber making up a muscle?

Answer 1

• usually it is just one!

- (about 2% have more than one nerve fibers)

Question 2

What is the cell membrane of the muscle fiber called?

Answer 2

• the sarcolemma

Question 3

Explain the structure of a muscle fiber

Answer 3

• each fiber contains hundreds to thousands of myofibrils

- each myofibril contains about 3000 thin atin filaments and 1500 thick myosin filaments

Question 4

What makes up the light bands on imaging? The dark bands?

Answer 4

• light bands: AKA I bands; these contain only actin

- dark bands: AKA A bands; these contain actin and myosin

Question 5

What is a sarcomere?

Answer 5

• the functional contractile unit of myofibrils
• 1 sarcomere is the area between two successive I bands (technically between two Z-discs, but I bands contain the Z-discs)
• sarcomeres make up the visible striations on each myofibril

Question 6

What fluid lies between myofibrils? What is is rich in?

Answer 6

• the sarcoplasm fills the spaces between myofibrils
• it is rich in potassium, magnesium, and phosphate, and contains a massive number of mitochondria
• (note that this is the same fluid present in the sarcoplasmic reticulum)

Question 7

Explain the general pathway of muscle contraction.

Answer 7

• an action potential travels along the motor nerve to the muscle fiber (ACh is released at the NMJ)
• ACh binds to post-synaptic receptors (ACh-gated ion channels), causing large amounts of Na+ inflow to generate an action potential in the muscle fiber
• this depolarization causes the sarcoplasmic reticulum to release large amounts of Ca2+, which results in contraction
• (Ca2+ is then pumped back into the SR within a fraction of a second!)

Question 8

Which filaments move during contraction (ie which band(s) will shorten during contraction)?

Answer 8

• actin filaments move during contraction (they slide/pull along the myosin filaments)
• this means that during contraction, the I bands (those containing only actin) shorten, pulling the Z-discs closer together, resulting in a shortened sarcomere (contraction)
• A bands do NOT change length; H-zones will increase in length

Question 9

Explain the structure of a myosin filament.

Answer 9

(note that muscle contraction involves type II myosin; type I myosin are involved in microvili and vesicular transport)

• each myosin filament is made up of about 200 myosin molecules
• each myosin molecule contains 2 heavy chains in a double helix formation and 4 light chains
• the 2 heads of each myosin molecule have intrinsic ATPase (ATP hydrolysis) activity

Question 10

Explain the structure of an actin filament

Answer 10

• each actin filament is composed of actin molecules, tropomyosin, and troponin (troponin C isotype)
• actin molecules have 2 heavy chains in a double helix formation, and each contains several binding sites for ADP
• tropomyosin is wrapped around the the actin filament and covers the ADP binding sites during rest
• troponin complexes are attached to the tropomyosin and have a high affinity for Ca2+

Question 11

What is the role of tropomyosin and troponin in muscle contraction?

Answer 11

• these structures inhibit contraction at rest because tropomyosin is covering the actin’s active sites involved in contraction
• in the presence of Ca2+, however, troponin undergoes a change and moves tropomyosin off of the active sites, allowing their interaction with myosin to result in contraction

Question 12

Explain the interaction between actin and myosin during contraction.

Answer 12

• 1) at rest, myosin cross-bridges are bound to ATP and myosin’s ATPase activity generates ADP and Pi (myosin is “cocked”)
• 2) Ca2+ allows actin’s active site to be revealed, and myosin cross-bridges immediately bind
• 3) ADP an Pi are released, resulting in the myosin’s “power stroke” to cause contraction
• 4) a new ATP molecule binds to myosin, resulting in its release of actin and return to resting state

Question 13

Explain the different conformations of the myosin head when bound to different products.

Answer 13

• bound to ATP: resting, not attached to actin
• bound to ADP and Pi: head is extended towards the actin filament (“cocked”) and will bind as soon as the actin’s active sites are opened
• nothing: myosin pulls the actin, resulting in contraction (“power stroke”)
• bound to ATP: releases actin, returns to rest

Question 14

What is rigor mortis? Why does it occur?

Answer 14

• rigor mortis is a condition of intense muscle contraction seen in recently deceased patients
• it is caused by the lack of ATP needed to release the myosin heads from the actin filaments (relaxation can’t occur without the next binding of ATP)

Question 15

What rephosphorylates the released ADP back into ATP during prolonged contraction?

Answer 15

• (note that the ATP reserves are VERY small)
• anaerobic 1st responders are phosphocreatine (degraded by creatine kinase to transfer phosphate to ADP) and glycogen (converted to pyruvate and made into lactate via LDH to regenerate NAD+ needed for more glycogen breakdown into pyruvate) (type II slow fibers main this)
• glycolysis and glycogenolysis (and oxidative phosphorylation) are then used; aerobic (type I slow fibers main this)

Question 16

Compare fast muscle fibers to slow muscle fibers.

Answer 16

• fast: type II; large, extensive SRs, large amounts of glycolytic enzymes; less extensive blood supply and less mitochondria (white muscle); anaerobic
• slow: type I; small, extensive blood supply and many mitochondria (red muscle); also contains lots of myoglobin (myoglobin stores excess O2); aerobic

Question 17

What are the two ways the body can increase the force of contraction?

Answer 17

• multiple fiber summation: increase the number of motor units firing and contracting
• frequency summation: increase the frequency of firing and contraction ofeach motor unit

Question 18

What is tetanization? What follows tetanization?

Answer 18

• tetanization is when the frequency of a motor unit’s firing and contraction becomes so rapid that the separate contractions fuse into one larger uniform contraction
• shortly after tetanization, maximum contractile strength will be achieved

Question 19

What goes on within the neuromuscular junction?

Answer 19

• ACh is released by the pre-synaptic nerve’s axon terminal and binds to receptors on the post-synaptic muscle fiber (these receptors are ion channels, and, when bound to TWO molecules of ACh, allow Na+ influx to generate the end-plate potential needed to spark contraction)
• shortly after ACh’s release, acetylcholinesterase rapidly destroys ACh (some is also lost just by diffusion away)

Question 20

How is ACh released from the pre-synaptic nerve into the NMJ?

Answer 20

• the action potential of the neuron results in voltage-gated Ca2+ channels to open and the resulting Ca2+ influx at the axon terminal causes exocytosis of the ACh synaptic vesicles

Question 21

What is curare? What about botulinum toxin?

Answer 21

• curare is a drug that blocks the ACh-gated ion channel receptors via competitive inhibition
• botulinum toxin is a bacterial poison that decreases the amount of ACh released by synaptic vesicles at the axon terminal
• (both will therefore prevent muscle contraction)

Question 22

Which types of drugs stimulate muscle contraction?

Answer 22

• cholinergic drugs/molecules: act in the same way as ACh, but usually aren’t cleared as readily by the acetylcholinesterase (nicotine, carbachol, methacholine)
• acetylcholinesterase inhibitors: allows accumulation of ACh in the NMJ to prolong contraction (neostigmine and physostigmine inhibit the enzyme for a few hours; diisopropyl flurophosphate AKA nerve gas inhibits it for WEEKS!)
• note that ACh inhibitors are very dangerous

Question 23

Explain subcellular/microscopic movement.

Answer 23

• myosin interacting with actin is an example of this
• others include kinesins moving towards the microtubule’s plus end (growing end) and dyneins moving towards the microtubule’s minus end (stable end)

Question 24

What are T-tubules?

Answer 24

• T-tubules are how the end-plate potential reaches the sarcoplasmic reticulum (resulting in Ca2+ release and contraction)
• these are networks throughout muscles that allow depolarization to reach many cells instead of just a few

Question 25

What are calreticulin and calsequestrin?

Answer 25

• these are Ca2+ binding proteins found in the sarcoplasmic reticulum
• they ensure that the Ca2+ gradient always favors Ca2+ re-uptake into the SR

Question 26

What is the dystroglycan complex?

Answer 26

• this complex connects the cytoskeleton of muscle cells to the ECM; this anchor is essential for movement to actually occur
• mutations to these complexes result in muscular dystrophy