Coordination 2

Question 1

What is a synaptic cleft?

Answer 1

A very small gap between two neurones at a synapse

Question 2

What is a synapse?

Answer 2

A point at which two neurones meet but do not touch; the synapse is made up of the end of the presynaptic neurone, the synoptic cleft and the end of the postsynaptic neurone

Question 3

How do impulses travel across a membrane?

Answer 3

• Impulses cannot ‘jump’ across a synapse

- Instead molecules of a transmitter substance or neurotransmitter are related to stimulate the next neurone

Question 4

What is a transmitter substance?

Answer 4

A chemical that is released from a presynaptic neurone when an action potential arrives, and that then diffuses across the synaptic cleft and may initiate an action potential in the postsynaptic neurone

Question 5

What is a postsynaptic neurone?

Answer 5

The neurone on the opposite side of a synapse to the neurone in which the action potentials arrives

Question 6

What is a presynaptic neurone?

Answer 6

A neurone ending at a synapse from which neurotransmitter is secreted when an action potentials arrives

Question 7

Describe an impulse travelling across a synapse

Answer 7

1. An action potential occurs at the cell surface membrane of the first neurone or presynaptic neurone
2. The action potential causes the release of molecules of transmitter substance into the cleft
3. The molecules of transmitter substance diffuse across the cleft and bind temporarily to receptors on the postsynaptic neurone
4. The post synaptic neurone responds to all the impulses arriving at any one time by depolarising; if the overall depolarisation is above its threshold, then it will send impulses

Question 8

What is acetylcholine (ACh)?

Answer 8

A transmitter substance found, for example in the presynaptic neurone at neurotransmitter junctions

Question 9

What is noradrenaline?

Answer 9

A neurotransmitter substance

Question 10

What are examples of different transmitter substances?

Answer 10

-Nonadrenaline and Acetylcholine (ACh) are found through the nervous system

Question 11

What are examples of different transmitter substances?

Answer 11

• Nonadrenaline and Acetylcholine (ACh) are found through the nervous system
• Dopamine, glutamic acid and gamma-aminobutyric acid (GAMA) occur only in the brain

Question 12

What are cholingeric synapses?

Answer 12

A synapse at which the transmitter substance is acetylcholine

Question 13

Describe action potentials in more detail

Answer 13

1. As an action potential occurs at one place on an axon, local circuits depolarise the next piece of membrane, stimulating the opening of sodium ion voltage gated channel and so propagating the action potential
2. In the part of the membrane of the presynaptic neurone that is next to the synaptic cleft, the arrival of the action potential causes calcium ion voltage gated channels to open

Question 14

What is the significant of the calcium ion voltage gated channels to open in the membrane of the presynaptic neurone?

Answer 14

1. Therefore the action potentials causes not only sodium ions but also calcium ions to diffuse out of the cytoplasm of the presynaptic neurone
2. There are virtually no calcium ions in the cytoplasm, but many in the tissue fluid surrounding the synapse
3. This means that there is a very steep electrochemical gradient for calcium ions

Question 15

What happens as a result of the influx of calcium ions?

Answer 15

1. The influx of calcium ions stimulate vesicles contain ACh to move to the presynaptic membrane and fuse with it, emptying their contents into the synaptic cleft
2. Each action potential causes just a few vesicles to do this and each vesicle contains up to 10,000 molecules of ACh
3. The ACh diffuses across the synaptic cleft, usually in less than 0.5ms

Question 16

Describe the cell surface membrane of the postsynaptic neurone

Answer 16

The cell surface membrane of the postsynaptic neurone contains receptor proteins

Question 17

What is significant about the receptor proteins in the cell surface membrane of the postsynaptic neurone?

Answer 17

1. Part of the receptor protein molecule has a complementary shape to part of the ACh molecule, so that ACh molecules can temporarily bind with the receptors
2. This changes the shapes of the protein, opening channels through which sodium ions can pass
3. Sodium ions diffuse into the cytoplasm of the postsynaptic neurone and depolarise the membrane

Question 18

What is different about these receptor proteins?

Answer 18

These receptor proteins with their channels are chemically gated ion channels as they are stimulated to open by chemicals (neurotransmitters) and not by a voltage change

Question 19

What would happen if the ACh remained bound to the postsynaptic receptors? How is this avoided?

Answer 19

1. The sodium channels would remain open, and the postsynaptic neurone would be permanently depolarised
2. The ACh is recycled to prevent this from happening and also to avoid wasting it

Question 20

What does the synaptic cleft contain?

Answer 20

The synaptic cleft contains an an enzyme, acetylcholinesterase, which catalyses the hydrolysis of each ACh molecule into acetate and choline

Question 21

What is acetylcholinesterase?

Answer 21

An enzyme that rapidly breaks down acetylcholine at synapses

Question 22

What is an action potential dependent on?

Answer 22

1. The depolarisation of the postsynaptic neurone only leads to the generation of an action potential if the potential difference is above the threshold for that neurone
2. If not then there is not action potential
3. The chance that an action potential is generated and an impulse sent in the postsynaptic neurone is increased if more than one presynaptic neurone relates ACh at the same time or over a short period of time

Question 23

Where is research on synapses?

Answer 23

1. Much often research on synapses has been done at synapses between motor neurone and a muscle, not those between two neurones
2. The motor neurone forms a more end plate with each muscle fibre and the synapse is called a neuromuscular junction
3. Such synapses function in the same way as describe above
   - An action potential is produced in the muscle fibre which may cause it to contract

Question 24

What is the disadvantage of synapses?

Answer 24

1. Synapses slow down the rate of transmission of a nerve impulse that has to travel along two or more neurones
2. Responses to a stimulus would be much quicker if action potentials generated in a receptor travelled along an unbroken neuronal pathway from receptor to effector, rather than having to cross synapses not the way

Question 25

What is a motor end plate?

Answer 25

The ending of an axon of a motor neurone where it forms a synapse with a muscle

Question 26

What is a neuromuscular junction?

Answer 26

A synapse between the axon of a motor neurone and a muscle

Question 27

How do synapses allow integration of impulses?

Answer 27

1. Each sensory neurone has many branches at the end of its axon that form synapses with many relay (intermediate) neurones
2. The cell body of each motor neurone is covered with the termination of many relay neurones
3. Motor neurones only transmit impulses if the net effect of the relay neurones is above the threshold at which it initiates action potentials
4. If the depolarisation of the postsynaptic membrane does not reach the threshold, no impulse is sent in that neurone
5. One advantage of this is that impulses with low frequencies do not travel from sensory neurones to reach the brain
6. This means that the brain is not overloaded with sensory information

Question 28

How do synapses allow the interconnection of nerve pathways?

Answer 28

1. Synapses allow a wider range of behaviour than could be generated in a nervous system in which neurones were directly ‘worded up’ to each other
2. They do this by allowing the interconnection of many nerve pathways

Question 29

What is one way that synapses allow the interconnection of many nerve pathways?

Answer 29

1. Individual sensory and relay neurone have axons that brach to form synapses with many different neurones
2. This means that information from one neurone can spread out throughout the body to reach many relay neurones and many effectors as happens when we respond to dangerous situations

Question 30

What is another way that synapses allow the interconnection of many nerve pathways?

Answer 30

1. There are many neurones that terminate on each relay and motor neurone as they have many dendrites to give a large surface area for many synapses
2. This allows one neurone to integrate the information coming from many different parts of the body, something that is essential for decision making in the brain

Question 31

How are synapses involved in memory and learning?

Answer 31

• If your brain frequently receives information about two things at the same time, say the sound of particular voice and the sight of a particular face then it is thought that new synapses form in your brain that link the neurone involved in the passing of information along the particular pathways from your ears and eyes
• In future when you hear the voice, information flowing from your ears along the pathway automatically flows into the other pathway room, so that your brain ‘pictures’ the face which goes with the voice

Question 32

What is the appearance in the light microscope of striated muscle?

Answer 32

Stripes (striations) at regular intervals

Question 33

What is the appearance in the light microscope of cardiac muscle?

Answer 33

Stripes (striations) at regular intervals

Question 34

What is the appearance in the light microscope of smooth muscle?

Answer 34

No striations

Question 35

What is the cell structure of striated muscle?

Answer 35

Multinucleate (syncytium)

Question 36

What is the cell structure of cardiac muscle?

Answer 36

Uninucleate cells joined by intercalated discs

Question 37

What is the cell structure of smooth muscle?

Answer 37

Uninucleate cells

Question 38

What is the shape of cells in striated muscle?

Answer 38

Long, unbranched cylinder

Question 39

What is the shape of cells in cardiac muscle?

Answer 39

Cells are shorter with branches that connect to adjacent cells

Question 40

What is the shape of cells in smooth muscle?

Answer 40

Long unbranched cells that taper at either end

Question 41

What is the organisation of contractile proteins inside the cell of striated muscle?

Answer 41

Organised into parallel bundles of myofibrils

Question 42

What is the organisation of contractile proteins inside the cell of cardiac muscle?

Answer 42

Organised into parallel bundles of myofibrils

Question 43

What is the organisation of contractile proteins inside the cell of smooth muscle?

Answer 43

Contractile proteins not organised into myofibrils

Question 44

What is the distribution in the body of striated muscle?

Answer 44

Muscles attached to the skeleton

Question 45

What is the distribution in the body of cardiac muscle?

Answer 45

Heart

Question 46

What is the distribution in the body of smooth muscle?

Answer 46

Tubular structures e.g. blood vessels (arteries, arterioles and veins), airways, gut, Fallopian tubes (oviducts), uterus

Question 47

What is the control of striated muscle?

Answer 47

neurogenic

Question 48

What is the control of cardiac muscle?

Answer 48

myogenic

Question 49

What is the control of smooth muscle?

Answer 49

neurogenic

Question 50

Describe striated muscle

Answer 50

• This type of muscle makes up the many muscles in the body that are attached to the skeleton
• Striated muscle only contracts when it is stimulated to do so by impulses that arrive via motor neurones and muscle tissue like this is described as being neurogenic

Question 51

What is myogenic?

Answer 51

The cardiac muscle in the heart is myogenic as it contracts and relaxes automatically with no need for impulses arriving from neurones

Question 52

Where is smooth muscle found?

Answer 52

Throughout the body in areas such as in the gas exchange system alimentary canal and in the walls of arteries, arterioles and veins

Question 53

How does most smooth muscle contract?

Answer 53

• When it receives impulses in motor neurones
• However smooth muscle in arteries also constricts when it is stretched by the pressure of blood surging through them and this happens without any input from the nervous system and this type of muscle is called smooth, because unlike the other two types of muscle tissue it has no striations
• Smooth muscle does NOT form smooth linings of tubular structure such as the trachea and arteries; the lining of these structures is always formed by an epithelium

Question 54

What happens when a muscle contracts?

Answer 54

• It exerts a force on a particular part of the body, such as a bone
• This results in a particular response
• The enormous system ensures that the behaviour of each muscle is coordinated with all the other muscles, so that together they can bring about the desired movement without causing damage to any parts of the skeletal or muscular system

Question 55

What is the sarcolemma?

Answer 55

The cell surface membrane of a muscle fibre

Question 56

What is the sarcoplasm?

Answer 56

The cytoplasm of the muscle fibre

Question 57

What are the transverse system tubules or T-tubules?

Answer 57

(also know as T-system tulle or T-tuble) infolding of the sarcolemma that goes deep into a muscle fibre

Question 58

What are myofibrils?

Answer 58

One of many cylindrical bundles of this and thin filaments inside a muscle fibre

Question 59

What is a muscle made up of?

Answer 59

1. A muscle such as a bicep is made up of thousands of muscle fibres
2. Each muscle fibre is a very specialised ‘cell’ with a highly organised arrangement of contractile proteins in the cytoplasm, surrounded by a cell surface membrane
3. Some biologists prefer not to call it a cell because it contains many nuclei
4. Instead they prefer the term syncytium to describe the multinucleate muscle fibre

Question 60

What are the different parts of the muscle fibre?

Answer 60

• The cell surface membrane is the sarcolemma
• The cytoplasm is sarcoplasm
• The endoplasm reticulum is the sarcoplasmic reticulum (SR)
• The cell surface membrane has many deep infolding into the interior of the muscle fibre called transverse system tubules and these run close to the sarcoplasmic reticulum

Question 61

What do the membranes of the sarcoplasmic reticulum have?

Answer 61

Huge numbers of protein pumps that transport calcium ions into the cisternae of the SR

Question 62

What does the sarcoplasm have?

Answer 62

• It contains large number of mitochondria, often packed tightly between the myofibrils
• These carry out aerobic respiration, generating the ATP required for muscle contraction

Question 63

How is a muscle organised?

Answer 63

1. An individual muscle is composed of hundreds of muscle fibres
2. Each muscle fibre is composed of many myofibrils
3. A myofibril has a distinctive banding pattern due to microfilmanets

Question 64

What are the different types of muscle?

Answer 64

1. Voluntary muscle aka as striated or skeletal muscle (these muscles are neurogenic and so it only contracts when it is stimulated by impulses
2. Involuntary muscle aka smooth muscle, also neurogenic
3. Cardiac muscle is myogenic and so contracts without needing an impulse from neurones

Question 65

What is voluntary muscle?

Answer 65

1. An individual muscle is made up of hundreds of muscle fibres
2. Each muscle fibre is bounded by an membrane called the sarcolemma
3. The sarcolemma has many deep infolding not the interior of the muscle fibre called transverse system tubules or T tubules
4. The endoplasmic reticulum inside the muscle ‘cell’ is called sarcoplasmic reticulum SR
5. The cytoplasm is called sarcoplasm
6. The T-tubules run close to the SR
7. The membranes of the SR have high numbers of proteins pumps that transport Ca2+ ions into the cisternae of the SR

Question 66

Why does a muscle fibre have stripes?

Answer 66

• These are produced by a very regular arrangement of many myofibrils in the sarcoplasm
• Each myofibril is striped in the exact same way and is lined up precisely against the next one producing a pattern

Question 67

What is a myofibril composed of using an electron microscope?

Answer 67

• Made up of filaments
• Parallel groups of thick filaments lie between groups of thin ones
• Both thick and thin filaments are made up of protein

Question 68

What are thick filaments made up of?

Answer 68

Myosin

Question 69

What are thin filaments made up of?

Answer 69

Actin

Question 70

What is the A band? What colour is it?

Answer 70

• The whole length of myosin filament with the overlap of actin
• A dark band has both actin and myosin microfilaments

Question 71

What is the H zone?

Answer 71

Consists of myosin only

Question 72

What is the I band?

Answer 72

• Consists of actin only

- Light band and has only actin microfilaments

Question 73

What is the Z line?

Answer 73

Dark vertical lines through the centre of each actin filament

Question 74

What is the M line?

Answer 74

Provides an attachment for the myosin filament

Question 75

How do you define a sarcomere?

Answer 75

It is from 1 Z line to another (the part of a myofibril between two Z lines)

Question 76

What is the shape of a myofibril?

Answer 76

Myofibrils are cylindrical in shape and so the Z line is in fact a disc seriating one sarcomere from another and is also called the Z disc

Question 77

What happens to the lines and bands during muscle contraction?

Answer 77

1. I band is reduced as actin slides between myosin
2. A band remains the same size: myosin length is unchained
3. H one is reduced as overlap between actin and myosin increases

Question 78

What happens to the lines and bands during muscle contraction?

Answer 78

1. I band is reduced as actin slides between myosin (decreased in length and disappear completely in fully contracted muscle)
2. A band remains the same size: myosin length is unchanged (stay the same length and appear darker due to the overlap)
3. H one is reduced as overlap between actin and myosin increases (decreased in length and disappear completely in fully contracted muscle)

Question 79

Describe thick filaments

Answer 79

1. Thick filaments are composed of many molecules of myosin, which is a fibrous protein with a globular head
2. The fibrous portion helps to anchor the molecule into the thick filament
3. Within the thick filament many myosin molecules all lie together in a bundle with their globular heads all posting away from the M line
   - Each myosin molecule, tail and two protruding heads
   - Each thick filament, many myosin molecules

Question 80

Describe thin filaments

Answer 80

1. The main component of thin filaments, actin is a globular protein
2. Many actin molecules are linked together to form a chain
3. Two of these chains are twisted together to form a thin filament
4. Also twisted around the actin chains is a fibrous protein called tropomyosin
5. Another protein, troponin is attached to the actin chain at regular intervals
   - Two chains of actin filament twisted together to form a chain and this is held together by a protein called tropomyosin
   - Another protein troponin is attached to the actin

Question 81

What happens to the sarcomere is muscle contraction?

Answer 81

Decreases in length, the whole muscle shortens and pull on the bone

Question 82

How do muscles cause movement?

Answer 82

• Muscles cause movement by contracting

- The sarcomeres get shorter as the z discs are pulled closer together

Question 83

Describe the muscle at rest

Answer 83

1. At rest actin myosin binding site is blocked by tropomyosin, held in place by troponin and myosin heads cannot bind to actin filaments
2. When the muscle is relaxed, tropomyosin and troponin are sitting in a position in the actin filament that prevents myosin from binding

Question 84

What happens with the calcium ions?

Answer 84

1. Ca2+ binds to the troponin changing its shape which causes tropomyosin to unblock the binding site for the myosin head
2. Myosin head binds to the actin forming a cross bridge

Question 85

Where does the energy for the the sliding filament model of muscle contraction start?

Answer 85

• The energy for the movement comes from ATP molecules that are attached to the myosin heads
• Each myosin head is an ATPase

Question 86

What happens with the calcium ions?

Answer 86

1. When a muscles contracts Ca2+ ions are released from stores in the SR
2. Ca2+ binds to the troponin changing its shape which causes tropomyosin to unblock the binding site for the myosin head
   - The troponin and tropomyosin proteins move to a different position on the thin filaments, so exposing parts of the actin mooches which act as binding sites for myosin
3. Myosin head binds to the actin forming a cross bridge

Question 87

What happens once the cross bridge between the two types of filament is formed?

Answer 87

1. The myosin head bends, pulling the action filament along towards the centre of the sarcomere, overlapping more with the myosin
2. This is the power stroke releasing the ADP and Pi

Question 88

What happens with free ATP?

Answer 88

1. Free ATP then binds to the myosin head and is hydrolysed providing enough energy to force the head to detach from the actin, and thus breaking the cross bridge
2. The head top back to their previous position and binds gains to another exposed site on the actin
   - With continued stimulation the cycle is repeated

Question 89

What happens if stimulation ceases?

Answer 89

• When there is no longer any stimulation from the motor neurone, there are no impulses conducted along the T-tubules
• Released from stilton, the calcium ion channels in the SR close and the calcium pumps move calcium ions back into stories in the SR
• As calcium ions leave their bonding sites on troponin, tropomyosin move back to cover the myosin binding sites on the thin filaments
  1. If stimulation ceases Ca2+ is pumped back into sarcoplasmic reticulum
  2. Troponin and tropomyosin return to original positions
  3. Muscle fibre is relaxed

Question 90

How does skeletal muscle contract?

Answer 90

1. Skeletal muscle contracts when it receives an impulse from a neurone
2. An impulse moves along the axon of a motor neurone and arrives at the presynaptic membrane
3. A neurotransmitter, generally acetylcholine, tissues across the neuromuscular junction and binds to receptor proteins on the postsynaptic membranes which is the sarcolemma (the cell surface membrane of the muscle fibre)

Question 91

What does the binding of acetylcholine stimulate?

Answer 91

The ion channels to open, so that sodium ions enter to depolarise the membrane and generate an action potential in the sarcolemma

Question 92

What happens to the impulses?

Answer 92

1. Impulses pass along the sarcolemma and along the T-tubules towards the centre of the muscle fibre
2. The membranes of the sarcoplasmic reticulum are very close to theT-tubules
3. The arrival of the impulses causes calcium ions channels in membrane to open
4. Calcium ions diffuse out down a very steep concentration gradient into the sarcoplasm surrounding the myofibrils

Question 93

What do the calcium ions do?

Answer 93

1. The calcium ions bind with the troponin molecules that are part of the thin molecules, which cause

Question 94

What happens when there are no cross-bridges between thick and thin filaments?

Answer 94

• The muscle is in a relaxed state
• There is nothing to hold the filaments together so nay pulling force applied to the muscle will lengthen the sarcomeres that they are ready to contract (and shorten again)
• Each skeletal muscle in the body has an antagonist (a muscle that restores sarcomeres to their original lengths when it contract e.g. the triceps is the antagonist of the biceps)

Question 95

Summarise the power stroke

Answer 95

1. Myosin head groups attached to surrounding actin filaments forming cross bridge
2. Head group bends; thin filament moves along and overlaps thick filament more; this is the power stroke; ADP and Pi released
3. Cross bridge broke as now ATP attached to myosin head
4. Head group moves backwards as ATP is hydrolysed to ADP and Pi and then repeat 1 and 2

Question 96

Why do muscles need ATP and where does it come from?

Answer 96

• A contracting muscle uses a lot of ATP and the very small quantity of ATP in the muscle fibres in a resting muscle is used up rapidly once the muscle starts to contract
• More ATP is produced by reparation, both aerobic respiration inside the mitochondria and when that cannot be supplied fast enough, also by lactic fermentation in the sarcoplasm

Question 97

What other source of ATP do muscles have? Where is it kept?

Answer 97

1. Muscles also have another sources of ATP; produced from as substance called creatine phosphate
2. They keep stores of this substance in their sarcoplasm

Question 98

What is creatine phosphate?

Answer 98

-It is their intermediate source of energy once they have used the small quantity of ATP in the sarcoplasm
-A phosphate group can quckily and easily be removed from each creatine phosphate molecule and combined with ADP to produce more ATP
creatine phosphate + ADP –> creatine + ATP

Question 99

What happens to the creatine later on?

Answer 99

1. Later when the demand for energy has slowed down or stopped, ATP molecules produced by respiration can be used to ‘recharge’ the creatine
   creatine + ATP –> creatine phosphate + ADP
2. In the meantime, however if energy is still being demanded by the muscles and there is no ATP spare to regenerate the creatine phosphate, the creatine is converted to creatinine and excreted in urine

Question 100

Summarise the events at the neuromuscular junction

Answer 100

1. An action potential arrives
2. The action potential causes the diffusion of calcium ions into the neurone
3. The calcium ions cause vesicles containing acetylcholine to fuse with the presynaptic membrane
4. Acetylcholine is released and diffuses across the synaptic cleft
5. Acetylcholine molecules bond with the receptors in the sarcolemma, causing them to open channel proteins for sodium ions
6. Sodium ions diffuse in through the open channels in the sarcolemma. This depolarises the membrane and initiates an action potential which spreads along the membrane

Question 101

Summarise the events in the muscle fibre

Answer 101

7. The depolarisation got the sarcolemma spreads down T-tubules
8. Channel proteins for calcium ions open and calcium ions diffuse out of the sarcoplasmic reticulum,
9. Calcium ions bind to troponin. Tropomyosin moves to expose myosin-binding sites on the actin filaments. Myosin heads form cross-bridges with thin filaments and the sarcomere shortens

Question 102

Why is myosin?

Answer 102

The contractile protein that makes up the thick filaments in striated muscle

Question 103

What is actin?

Answer 103

The protein that makes up the thin filaments in striated muscle

Question 104

What is a sarcomere?

Answer 104

The part of the myofibril between to Z discs

Question 105

What is tropomyosin?

Answer 105

A fibrous protein they is part of the thin filaments in myofibrils in striated muscle

Question 106

What is troponin?

Answer 106

A calcium-binding proton that is part of the thin filaments in myofibrils in striated muscle