Muscles

Question 1

What are the types of muscle?

Answer 1

Cardiac muscle is found only in the heart.
Smooth muscle is found in the walls of blood vessles and the gut.
Neither of these is under concious control.
Skeletal muscle is attached to bone, and acts under voluntary, concious control.

Question 2

What are myofibrils?

Answer 2

Individual muscles are made up of tiny muscle fibres called myofibrils.
Alone, they produce almost no force, but collectively can be extremely powerful.
The myofibrils are arranged to give maximum force.
Muscle is composed of smaller units bundled into progressively larger ones.

Question 3

Why is the structure of muscles not regular?

Answer 3

If muscle was individual cells joined end to end, the junction inbetween would be a point of weakness that would reduce the overall strength.

Question 4

What is the structure of the muscle?

Answer 4

The separate cells have become fused together into muscle fibres.
The muscle fibres share a nuclei and cytoplasm, the sarcoplasm, mainly found around the circumference of the fibre.
There is a large concentration of mitochondria and endoplasmic reticulum here.

Question 5

What are myofibrils made up of?

Answer 5

Two types of protein filament:
Actin, thinner and consists of two strands twisted around one another.
Myosin, thicker and consists of long, rod-shaped tails with bulbous heads that project to the side.

Question 6

What are the myofibril bands?

Answer 6

Myofibrils appear striped due to alternating light-coloured and dark-coloured bands.
The light bands are I-bands (isotropic), and are lighter because the thick and thin filaments don’t overlap here.
The dark bands are A bands (anisotropic), and the thick and thin bands overlap here.

Question 7

What is the structure inside the myofibril bands?

Answer 7

At the centre of each A band is a lighter coloured region the H-zone.
At the centre of each I band is the Z-line.
The distance between adjacent Z-lines is the sarcomere.
When a muscle contracts, the sarcomere shortens, and the pattern of light and dark bands changes.

Question 8

What is tropomyosin?

Answer 8

An important protein in the muscle which forms a fibrous strand around the actin filament.

Question 9

What are slow-twitch muscle fibres?

Answer 9

Slower, less powerful contractions but over a longer period that fast twitch.
Adapted to endurance work.
Adapted for aerobic respiration to avoid lactic acid build up, which would effect functionality, and prevent long-duration contraction.

Question 10

How are slow twitch fibres adapted for aerobic respiration?

Answer 10

A large store of myoglobin (red molecule that stores oxygen).
A rich supply of blood vessels to deliver oxygen and glucose.
Numerous mitochondria to produce ATP.

Question 11

What are fast twitch muscle fibres?

Answer 11

Contract more rapidly and powerfully, but for a short period.
Adapted for intense exercise - weight lifting.

Question 12

How are fast twitch fibres adapted for anaerobic activity?

Answer 12

Thicker and more numerous myosin filaments.
A high concentration of glycogen.
A high concentration of enzymes involved in anaerobic respiration, which provides ATP rapidly.
A store of phosphocreatine, which rapidly regenerates ATP in anaerobic conditions.

Question 13

What are neuromuscular junctions?

Answer 13

The point where a motor neurone meets a skeletal muscle fibre.
There are many junctions along the muscle, to ensure the muscle fibres contract simultaneously and the movement not slow.

Question 14

What is a motor unit?

Answer 14

All muscle fibres supplied by a single motor neurone act together as a single functional unit.
This arrangement gives control over the force that the muscle exerts.
For small force, only a few units are stimulated.

Question 15

How does a nerve impulse travel in a neuromuscular junction?

Answer 15

When a nerve impulse is recieved, the synaptic vesicles fuse with the presynaptic membrane, and release acetylcholine.
The acetylcholine diffuses to the postsynaptic membrane (of the muscle fibre), altering its permeability to sodium ions, which enter rapidly, depolarising the membrane.

Question 16

How does acetylcholinesterase work?

Answer 16

The acetylcholine is broken down by acetylcholinesterase to ensure the muscle is not over-stimulated.
The resulting choline and ethanoic acid diffuse back into the neurone, where they are recombined to form acetylcholine using energy from ATP.

Question 17

What are the similarities of the neuromuscular junction and a synapse?

Answer 17

They both have neurotransmitters that are transported by diffusion.
Both have receptors, that on binding with the neurotransmitter, cause an influx of sodium ions.
Both use a sodium-potassium pump to repolarise the axon.
Both use enzymes to breakdown the neurotransmitter.

Question 18

What are the characteristics of the neuromuscular junction?

Answer 18

Only excitory.
Only links muscles to neurones.
Only motor neurones are involved.
The action potential ends here (end of a neural pathway).
Acetylcholine binds to receptors on membrane of muscle fibre.

Question 19

What are the characteristics of the cholinergic synapse?

Answer 19

May be excitory or inhibitory.
Links neurones to neurones, or neurones to other effectors.
Motor, sensory and intermediate neurones may be involved.
A new action potential may be produced along another neurone.
Acetylcholine binds to receptors on the membrane of post-synaptic neurone.

Question 20

What are antagonistic pairs?

Answer 20

The skeletal muscle pairs pull in opposite directions and when one is contracted the other is relaxed.

Question 21

What is the evidence of the sliding filament mechanism?

Answer 21

When a muscle contracts, in the sarcomere:
The I-band becomes narrower.
The Z-lines move close together / the sarcomere shortens.
The H-zone becomes narrower.

Question 22

What is the evidence that discounts against other mechanisms?

Answer 22

The A-band remains the same width.
As the width of this is determined by the length of the myosin filaments, it followed that the myosin filaments have not shortened.
This discounts the theory that muscle contraction is due to the filaments themselves shortening.

Question 23

What is myosin?

Answer 23

Made up of two types of protein:
A fibrous protein arranged into a filament made up of several hundred molecules (tail).
A globular protein formed into two bulbous structures at one end (head).

Question 24

What is actin?

Answer 24

A globular protein whose molecules are arranged into long chains that are twisted around one another to form a helical strand.
Tropomyosin forms long thin threads that are wound around actin filaments.

Question 25

What is the sliding filament mechanism of muscle contraction?

Answer 25

The bulbous heads of the myosin filaments form cross-bridges with the actin filaments.
They do this by attaching themselves to binding sites on the actin filaments, and then flexing in unison, pulling the actin filaments along the myosin filaments.
They then become detached and, using ATP for energy, return to their original angle and re-attach themselves further along the actin filaments.
This is repeated 100 times per second.

Question 26

What is the muscle stimulation of the sliding filament mechanism?

Answer 26

An action potential reaches many neuromucular junctions simultaneously, causing calcium ion protein channels to open, and calcium to diffuse into the synaptic knob.
This causes the synaptic vesicles to fuse with the presynaptic membrane and release acetylcholine into the synaptic cleft.
Acetylcholine diffuses across the synaptic cleft and binds with receptors on the muscle cell surface membrane, depolarisation.

Question 27

What is the muscle contraction of the sliding filament mechanism?

Answer 27

The action potential travels deep into the fibre through a system of t-tubules that are extensions of the cell surface membrane and branch through the sarcoplasm.
The tubules are in contact with the sarcoplasmic reticulum which has actively transported calcium ions from the cytoplasm leading to very low calcium ion concentration in the cytoplasm.
The action potential opens the calcium ion protein channels on the endoplasmic reticulum and calcium ions diffuse into the muscle cytoplasm down a concentration gradient.

Question 28

What is the calcium ions in the muscle contraction of sliding filament mechanism?

Answer 28

The calcium ions cause the tropomyosin molecules that were blocking the binding sites on the actin filament to pull away.
ADP molecules attached to the myosin heads mean they can bind to the actin filament and form a cross-bridge.
Once attached, the myosin heads change their angle, pulling the actin filament along as they do so and release an ADP molecule.

Question 29

What is the ATP in muscle contraction of the sliding filament mechanism?

Answer 29

An ATP molecule attaches to each myosin head, causing it to become detached from the actin filament.
The calcium ions then activate ATPase, which hydrolyses ATP to ADP. This provides the energy for the myosin head to return to its original position.
The myosin head, once more with an attached ADP molecule, then reattaches itself further along, and the cycle is repeated as long as the concentration of calcium ions in myofibrils remains high.

Question 30

What is opposite directions in the muscle contraction of the sliding filament mechanism?

Answer 30

As the myosin molecules are joined tail to tail in oppositely facing sets, the movement of one set of heads is in the opposite direction to the other. This means the actin filaments also move in opposite directions.
The movement of actin filaments in opposite directions pulls them towards each other, shortening the sarcomere.

Question 31

What is the basic muscle contraction of sliding filament mechanism?

Answer 31

Tropomyosin molecule prevents myosin head from attaching to the binding site on the actin molecule.
Calcium ions released from the endoplasmic reticulum cause the tropomyosin molecule to change shape and so pull away from the binding site on actin.
Myosin head now attaches to the binding site on actin.
The head of myosin changes angle, moving the actin filament along as it does so. ADP is released.
ATP molecule fixes to myosin head, so it detaches from the actin filament.
Hydrolysis of ATP to ADP by ATPase provides the energy for myosin heads to return to normal.
Head of myosin reattaches to a binding site further along the actin filament, and repeat.

Question 32

What is muscle relaxation of the sliding filament mechanism?

Answer 32

When nervous stimulation ceases, calcium ions are actively transported back into the endoplasmic reticulum, using energy from ATP hydrolysis.
This allows tropomyosin to block the actin filament again.
Myosin heads cannot bind to actin, so the muscle relaxes.
The antagonistic muscles can pull actin filaments out from between myosin.

Question 33

What is energy supply in muscle contraction?

Answer 33

Energy is supplied from hydrolysis of ATP to ADP and Pi.
The energy is needed for movement of myosin heads, and the reabsorption of calcium ions into the endoplasmic retciulum by active transport.

Question 34

Why is phosphocreatine needed?

Answer 34

In a very active muscle the demand for ATP, and therefore oxygen (for aerobic respiration) is greater than the rate which blood can supply oxygen.
So a means of rapidly generating ATP anaerobically is required, partly by phosphocreatine, partly by glycolysis.

Question 35

What is phosphocreatine?

Answer 35

It cannot supply energy directly to the muscle, so it regenerates ATP.
Phosphocreatine is stored in the muscle and acts as a reserve for phosphate, which combines with ADP to form ATP.
The phosphocreatine store is replenished using phosphate from ATP when the muscle is relaxed.