Action potentials

Question 1

What had already been established in the early 20thc

Answer 1

Neurons respond to stimulation with ‘all-or-none’ spikes of electrical activity which self-propagate along axons

Question 2

What did Bernstein propose as the cause of action potentials

Answer 2

Bernstein (1902)- due to transient loss of selective membrane permeability, which would lead to membrane potential to shoot to 0mV

Question 3

Whydid the mechanisms underlying action potential generation remain obscure for a long time

Answer 3

It had not been possible to directly record the transmembrane potential in axons as they are so thin- electrophysiological studies on axons had relied on extracellular recordings

Question 4

Who got a Nobel prize for the functions of neurons

Answer 4

1932- Sherrington and Adrian

Question 5

Who got a Nobel prize for the function of single nerve fibres

Answer 5

1944- Erlanger and Gasser

Question 6

Who got a Nobel prize for the mechanisms of axonal excitability

Answer 6

1963- Hodgkin and Huxley

Question 7

Who got a Nobel prize for the study of single ion channels

Answer 7

1991- Neher and Sakmann

Question 8

How were the first intracelllular recordings of the action potential carried out

Answer 8

Hodgkin and Huxley (1945)-used the giant axon of a squid as it is big enough to enable the insertion of microelectrodes into the axoplasm

Question 9

What did the first intracellular recordings of action potential reveal

Answer 9

Hodgkin and Huxley (1945)- the membrane potential reversed during action potentials (overshot 0mV) then became transiently hyperpolarised below resting membrane potential following the action potential (after-hyperpolarisation)

Question 10

What did the first intracellular recordings of action potential reveal about their cause

Answer 10

Hodgkin and Huxley (1945)- Could not be explanied by loss of selective membrane permeability, but rather changes in the permeability to specific ions

Question 11

What is the sodium hypothesis

Answer 11

Suggested the upstroke of action potential could be explained by increased Na+ permeability- this could cause Na+ to diffuse into the cell, dragging the membrane potential towards the positive Nernst potential for Na+ ions (around 55mV)

Question 12

Study investigating the sodium hypothesis

Answer 12

Nastuk and Hodgkin (1950)- plotting action potential peak against the log of extracellular Na+ conc reveals a straight line with a slope predicted by Nernst for Na+, though the membrane potential never quite reaches E Na due to leak channels

Question 13

What increases the membrane permeability to Na+ in the action potential

Answer 13

Voltage-gated Na+ ion channels- if the membrane is depolarised the channels open and Na+ permeability increases, which increases membrane depolarisation, which increases Na+ permeability in a positive feedback loop

Question 14

What 3 membrane conductances can be multiple phases of the action potential be explained by

Answer 14

Leak conductance, voltage-dependent Na+ conductance, voltage-dependent K+ conductance that all try to clamp the membrane potential at their Nernst potential

Question 15

Which of the 3 membrae conductances determines the resting membrae potential

Answer 15

The leak conductance

Question 16

Which of the 3 membrane conductances is recruited whe the membrane is depolarised

Answer 16

Voltage-dependent Na+ conductance- the membrane potential shoots towards E Na as the Na+ conductance increases in a positive feedback loop, dominating leak conductance

Question 17

What happens to the Na+ conductance when the peak of the action potential is reached

Answer 17

Na+ conductance inactivates, and there is a delayed recruitement of voltage-dependent K+ conductance that drags the membrane potetial towards E K and rapidly repolarises the membrane

Question 18

Which of the 3 membrane conductances causes the undershoot/after-hyperpolarisation

Answer 18

The K+ conductance takes time to turn off after repolarisation, causing the undershoot as the membrane is more permeable to K+ ions than at rest
When the K+ conductance turns off, the membrane potential is again set by leak conductance

Question 19

What is it necessary to do in order to determine the properties of the ionic conductances underlying the action potential by manipulating membrane potential

Answer 19

Membrane potential affects membrane permeability which in turn affects membrane potential, so it is necessary to break this feedback loop in experiments

Question 20

How can the membrane potential/permeability feedback loop be broken

Answer 20

Axial voltage-clamp- a wire is inserted along the length of an axon and connected to an electronic feedback circuit to clamp the axon’s membrane potential and prevent further depolarisation, while recording the current required to achieve this voltage clamp (Hodgkin and Huxley, 1952)

Question 21

What does the axial voltage clamp allow the measurement of

Answer 21

Measurement of membrane currents as a function of time at any given voltage (Hodgkin and Huxley, 1952)

Question 22

Hodgkin and Huxley (1952)- what was the effect of stepping the membrane potential to a depolarised level (0mV)

Answer 22

Reveals a transient inward current of Na+, followed by a sustained outward current of K+

Question 23

Hodgkin and Huxley (1952)- how could the current for each ion be independently measured WITHOUT using pharmacological blockers

Answer 23

Removing Na+ from the extracellular fluid eliminates the inward current, leaving the delayed and sustained outward current mediated by the voltage-dependent K+ conductance.. subtraction can calculate the current mediated by the Na+ conductance

Question 24

Hodgkin and Huxley (1952)- how could the current for each ion be independently measured using pharmacological blockers

Answer 24

Tetrodotoxin (TTX) blocks the Na+ conductance, while tetraethylammonium ions (TEA+) block the delayed K+ conductance

Question 25

Hodgkin and Huxley (1952)- what is the effect of increasingly large voltage steps on K+ conductance

Answer 25

K+ current is larger and faster to activate with increasingly large depolarisation steps due to an increase in K+ conductance and an increase in driving force- once fully activated, the K+ conductance is sustained throughout the voltage step

Question 26

Hodgkin and Huxley (1952)- how can conductance be calculated from the current over time

Answer 26

Ohm’s law can be used to calculate conductance

Question 27

Hodgkin and Huxley (1952)- what is the effect in Na+ conductance of a a given voltage step compared to the effect on K+ conductance

Answer 27

Na+ conductance activates more quickly than K+ conductance, and the rate of activatino increases with depolarisation

Question 28

Hodgkin and Huxley (1952)- what is the size of the effect of voltage increase on Na+ conductance

Answer 28

Na+ conductance increases monotonically as a function of voltage

Question 29

Hodgkin and Huxley (1952)- what happens to Na+ current as the membrane potential approaches the Nernst potential for Na+

Answer 29

Na+ current decreases due to the decrease in driving force

Question 30

Hodgkin and Huxley (1952)- what is the effect on Na+ of voltage steps above Na+’s Nernst potential

Answer 30

Na+ current reverses, and Na+ ions are driven out of the cell (situation would not happen during an action potential))

Question 31

Hodgkin and Huxley (1952)- what happens to Na+ conductance followig activation

Answer 31

It shows rapid inactivation, even if the membrane remains depolarised
The rate of inactivation increases with depolarisation

Question 32

What is subthreshold Na+ conductance

Answer 32

Weak inputs may be sufficient to active voltage-gated Na+ conductances, without evoking an action potential

Question 33

How can weak inputs activate voltage-gated Na+ conductances without evoking an action potential

Answer 33

The increases in the K+ leak current (due to increased driving force from depolarisation) and voltage-gated K+ current can counterbalance the depolarising Na+ current, preventing entry into the positive feedback loop

Question 34

What does action potential threshold reflect

Answer 34

A point at which the outward currents can no longer counterbalance the inward currents- not an intrinsic property of the Na+ conductance, but dynamic

Question 35

What happens if voltage-gated K+ conductance is blocked during an action potential

Answer 35

The membrane can still repolarise, as the Na+ conductance deactivates, just more slowly

Question 36

What is the role of the voltage-gated K+ conductance

Answer 36

Speeding up repolarisation enabling the axon to fire again with a shorter delay, maximal firing rate

Question 37

Why does the refractory period occur

Answer 37

It takes time for the Na+ conductance to de-inactivate, and for the voltage-gated K+ conductance to de-activate- in this time, the membrane is hypoexcitable

Question 38

What is the absolute refractory period

Answer 38

The time where it is impossible to evoke another action potential no matter how large the stimulus, because the fraction of Na+ conductance available for activation is not sufficient to overcome the leak/K+ conductance

Question 39

What is the relative refractory period

Answer 39

The time when a higher threshold is required for another action potential to be fired, as only a limited proportion of the Na+ conductance has recovered from inactivation and voltage-gated K+ conductance has not been fully deactivated

Question 40

What technique allows us to record the activity of single ion channels

Answer 40

Patch-clamp techniques

Question 41

What is the behaviour of single voltage-dependent ion channels following the onset of a voltage step

Answer 41

The current flowing through single channels flips ‘on’ and ‘off’ in a stochastic manner, with the currents looking different from trial to trial- it does not show a smooth increase

Question 42

What do the macroscopic currents recorded by Hodgkin and Huxley represent

Answer 42

The statistical behaviour of a large no of channels, which shows stereotypical patterns from trial to trial

Question 43

How do neurons encode information

Answer 43

In the rate and/or timing of action potentials

Question 44

Why is fast conductance important for behaviour

Answer 44

For the CNS to function, signals must be conducted from the periphery, processed, and transmitted back to effector organs over behaviourally relevant timescles (eg sufficient to catch a prey, remove a hand from a hot plate before tissue damage)

Question 45

What range does the speed of action potential conduction vary over

Answer 45

<1ms/s to over 100m/s

Question 46

What physical properties of axonal fibres affect their conductance velocity

Answer 46

Diameter and myelination

Question 47

Study showing that conduction velocity is not a hard-wired property of an axon

Answer 47

There is continued remodelling of myelination throughout life and learning can induce white matter plasticity (Scholz et al, 2009)

Question 48

Why will changes in conductance velocity alter the synchronisation across multiple inputs

Answer 48

The inputs arriving onto neurons have to travel over a variety of distances so will experience different conduction delays
Changes in conduction velocity will thus alter synchronisation and modulate how info is processed

Question 49

What may axonal plasticity be an importatnt process during

Answer 49

Brain development and learning

Question 50

How dos membrane capacitance affect the response of the membrane

Answer 50

It slows it down, as it takes time to charge up the membrane to its new value

Question 51

What is the speed of response of the membrance characterised by

Answer 51

Time constant T- the amount of time it takes for the change in potential to reach 63% of its final value

Question 52

What is the effect of capacitance and membrane resistance on the time constant

Answer 52

The lower the capacitance and membrane resistance, the shorter the time constant aka the faster the membrane responds to a stimulus

Question 53

What is the equation for the time constant

Answer 53

Tau = 𝒓𝒎*𝑪𝒎

rm is membrane resistance, Cm is membrane capacitance

Question 54

What happens to the speed of response as the signal propagates along the cable

Answer 54

The membrane is leaky, so as the current gradually leaks across the membrane the response decays exponentially

Question 55

What is the length constant

Answer 55

The distance along a cable over which the steady-state signal decays to 37% of its original value

Question 56

What is the equation for length constant

Answer 56

(𝝀 =+√(rm/ri ))

rm and ri are membrane and internal resistances

Question 57

What is the effect of membrane and and internal resistance on length constant

Answer 57

The higher the membrane resistace and the lower the internal resistance, the longer the signal can travel without decaying as much (higher length constant)

Question 58

What happens to the current flowing across the membrane as the membrane charges up

Answer 58

It will decrease, thus the current flowing down the axon will increase correspondingly

Question 59

What is λ for cortical axons

Answer 59

A few hundred microns

Question 60

How does the action potential curve map onto an action potential moving along an axon length

Answer 60

The sharp peak is at the point at which the action potential is being actively generated, with a leading edge of subthreshold depolarisation and a wake of refractory axon showing Na+ channel inactivation/after-hyperpolarisation

Question 61

What does the refractory wake of the action potential curve ensure

Answer 61

Ensures that the action potential only propagates in one direction

Question 62

What does conduction velocity relate to in terms of the axon

Answer 62

How fast the active site of generation moves along the axon, aka how quickly the next segment of axon can be depolarised to threshold

Question 63

How does conduction velocity relate to length constant

Answer 63

Conduction velocity is proportionate to length constant

Question 64

How does conduction velocity relate to time constant

Answer 64

Conduction velocity is proportional to 1/tau

Question 65

Why do large diameter fibres have faster conductio velocities

Answer 65

Less internal resistance due to greater space for current to travel among organelles, decreased capacitance

Question 66

How does increasing axon diameter affect membrane capacitance

Answer 66

Increased membrane diamater increases membrane area which increases linearly with membrane capacitance as there is more capacitive membrane to charge up

Question 67

How does increasing diameter affect membrane resistance

Answer 67

Increased diameter means higher membrane area which means more channels, so decreased membrane resistance

Question 68

How does increasing diameter affect internal resistance

Answer 68

The square of the diameter is proportional to decreased internal resistance

Question 69

Formula showing the relationship between length constant and d

Answer 69

λ is proportional to√𝑑

Question 70

Why is time constant independent of diameter

Answer 70

Increased diameter increases membrane capacitance (increases time constant) but decreases membrane resistance (decreases time constant), so the 2 cancel each other out

Question 71

Considering the effect of diameter on time and length constant, how does diameter affect conduction velocity

Answer 71

Conduction velocity increases according to √𝑑, so an 100 fold increase in axon diameter will yield a 10 fold increase in conduction velocity

Question 72

How does myelination help enable high conduction velocities in relatively small diameter fibres

Answer 72

Oligodendrocytes/Schwann cells provide insulating sheaths around axons to enhance the passive propagation of electrical signals

Question 73

How does myelination affect membrane resistace

Answer 73

Membrane resistance increases in proportion to thickness of the myelin sheath, meaning less leakage of current of current across the membrane and faster passive propagation

Question 74

How does myelination affect membrane capacitance

Answer 74

Membrane capacitance decreases in proportion to thickness of the myelin sheath as increased space between the 2 conducting solutions either side of the membrane decreases the capacitance

Question 75

How does myelination affect the length and time constant

Answer 75

The length constant is increase proportional to √m, while tau is unaffected

Question 76

Why are the Nodes of Ranvier necessary

Answer 76

Myelin is not a perfect insulator, so as the signal propagates passively along the axon it decays- the Nodes of Ranvier are necessary to regenerate the action potential

Question 77

What are the Nodes of Ranvier

Answer 77

Regular interruptions of the myelin sheath, contain high densities of voltage-gated Na+ channels to regenerate the action potential

Question 78

What term describes the way the action potential jumps from node to ndoe

Answer 78

Salutatory conduction

Question 79

How does the amount of nodal membrane (length and membrane) affect rate of conduction

Answer 79

The greater the amount of nodal membrane (length and number) the slower conduction will be, as propagation in the ndoel region operates the same way as in unmyelinated axons

Question 80

What enables longer internodal regions (and fewer nodes) to increase salutaotry conduction speed

Answer 80

Higher velocity of passive conductance aka increased length constant

Question 81

What effect will increased total axon diameter of a myelinated axon have on myelin thickness

Answer 81

Increased axon AND myelin sheath thickness (as there is a fixed ratio between axon diameter and that of the total nerve)

Question 82

What is the effect of increased diameter increasing both axon and myelin thickness

Answer 82

Conductino velocity increases approximately linearly with total nerve diameter, as increased axon diameter and increased myelination both boost velocity

Question 83

What would be the effect of stripping away the segments of myelin sheath

Answer 83

Would leave a bare section of axon with low expression of voltage-gated Na+ channels- conduction can still occur even if 2-3 myelin segments are removed, but increased conduction delay eventually causes current to be shunted by the exposed membrane, causing conduction failure

Question 84

What is the difference in channels between demyelinated axons and unmyelinated axons

Answer 84

Unmyelinated axons have high densities of voltage-gated Na+ channels along their length (are meant to be unmyelinated)

Question 85

Examples of unmyelinated fibres

Answer 85

Slow conduction fibres, C fibres in periphery, local projections within grey matter

Question 86

What are unmyelinated fibres more efficient for and why

Answer 86

Myelination costs space and energy, so unmyelinated fibres are more efficient for signals that don’t need to be propagated quickly

Question 87

What diamater of unmyelinated axons are likely to conduct faster than myelinated fibres

Answer 87

Total diameters below 1um, as myelin takes up space

Question 88

What is an action potential

Answer 88

An all or nothing signal that conveys information by its rate and duration of firing over distances in the nervous system

Question 89

What does it mean that action potentials are all or nothing

Answer 89

They can only be generated if the cell becomes depolarised enough to reach the threshold, and always follow the same shape/duration/reaches the same peak voltage’sa

Question 90

What is an osscilloscope

Answer 90

A special type of voltmeter that can be used to study action potentials by recording the voltage across the membrane as it changes over time

Question 91

What identifiable parts does each action potential have

Answer 91

Threshold, rising phase where membrane is depolarised, overshoot, falling phase where rapidly repolarisation occurs, then the undershoot/after-hyperpolarisation, then a gradual restoration of the resting potential

Question 92

How long do action potentials last

Answer 92

Around 2msec

Question 93

How is the action potential triggered

Answer 93

Na+ voltage-gated sodium channels open at the axon hillock in response to a stimulus eg membrane stretching or the binding of neurotransmitters

Question 94

How do we generate multiple successive action potentials

Answer 94

Passing continuous current into a neuron with a microeelctrode

Question 95

What does the rate of action potential generation depend on (current)

Answer 95

The magnitude of the continuous depolarising current- if threshold is just reached the cell may generate 1 action potential per second (1Hz), but if current is increased the rate may increase to 50Hz

Question 96

How can stimulation intensity be encoding by action potential firing

Answer 96

A higher depolarising current means a higher rate of action potential firing

Question 97

What is the maximum firing frequency for a neuron and why

Answer 97

About 1000Hz, as the absolute refractory period is about 1msec

Question 98

How are the voltage-gated Na+ channels selective for Na+

Answer 98

They have pore loops assembeld into a selectivity filter, making the channel 12x more permeable to Na+ than K+

Question 99

What mechanism underlies the voltage-gating of the Na+ channel

Answer 99

A voltage sensor in segment s4 of the molecule that contains +ve amino acid residues regularly spaced along the helix coils, meaning the entire S4 coil can be twisted by a change in membrane potential, opening the gate

Question 100

What is the threshold for neurons

Answer 100

-40mV

Question 101

How long do the Na+ channels stay open for following threshold

Answer 101

Stay open for 1msec then inactivate when the membrane is depolarised

Question 102

Disorder demonstrating the importance of the Na+ channels closing quickly

Answer 102

Single amino acid mutations in the extracellular region of one sodium channel cause generalised epilepsy with febrile seizures which involves explosive electrical activity in the brain- the mutation slows the inactivation of Na+ channels, prolonging the action potential

Question 103

What is a channelopathy

Answer 103

A human genetic disease caused by alterations in the structure and function of ion channels

Question 104

Effect of TTX on voltage-gated sodium chael

Answer 104

Tetrodotoxin is a pufferfish toxin that is fatal if ingested- binds tightly to a site outside the channel blocking the pore and blocking all sodium-dependent action potentials

Question 105

Effect of frog toxin on voltage-gated sodium channel

Answer 105

Batrachotoxin causes sodium channels to open at more negative potentials and stay open much longer than usual, scrambling the info encoded by the action potentials

Question 106

What do voltage-gated potassium channels oepn in response to

Answer 106

Depolarisation of the membrane- there is a 1msec delay in them opening

Question 107

Why did Hodgkin and Huxley call the voltage-gated K+ conductance the delayed rectifier

Answer 107

There is a 1msec delay, and the K+ conductance out the cell due to the electrical driving force resets the membrane potential

Question 108

What voltage does the membrane potential rise to in an action potential

Answer 108

Around 40mV, around E Na

Question 109

How is the action potential actively propagated along the axon

Answer 109

The influx of positive charge at one region of the axon spreads inside the axon to depolarise the adjacent segment of membrane and continue the propogation

Question 110

What is orthodromic conduction

Answer 110

Action potential conduction from soma to axon terminal

Question 111

What is antidromic conduction

Answer 111

Action potential propagating backwards, elicited experimentally

Question 112

What is the typical rate of action potential velocity

Answer 112

10m/sec

Question 113

How does Lidocaine (local anaesthetic work)

Answer 113

Prevents action potentials by binding to the voltage-gated sodium channels, preventing the flow of Na+ that usually depolarises the channel

Question 114

Why are smaller axons affected by local anaesthetics before larger axons

Answer 114

In smaller axons, more of the voltage-gated sodium are required to work to ensure the action potential doesn’t fizzle out as it conducts down the axons

Question 115

Demyelinatnig disease thats not MS

Answer 115

Guillain-Barre syndrome- attacks the myelin of peripheral nerves that innervate muscle and skin, causing slowed/failed action potential firing in the axons innervatnig the muscles, causing profoundly slowed response times

Question 116

What is the axon hillock often called

Answer 116

The spike-initiation zone

Question 117

How does the spike initiation zone in sensory neurons differ fro typical neurons in the brain/spinal cord

Answer 117

In most sensory neurons, the spike initiation zone occurs near the sensory nerve endings, where depolarisation caused by sensory stimulation leads to the geenration of action potentials that propagate along the sensory nerves

Question 118

How does synaptic input cause generation of action potentials in typical neurons in the brain/spinal cord

Answer 118

Depolarisation of the dendrites and some caused by synaptic input leads to the generation of action potentials if the membrane of the axon hillock is depolarised beyond threshold

Question 119

How can the gating of voltage-sensitive channels be influenced by intracellular ion concentration eg Ca2+

Answer 119

In some cels, increased intracellular Ca2+ conc increases the probability that calcium-sensitive K+ channels open, but can also inactivate Ca2+ channels, so can have opposing effects

Question 120

How can excitability propertirs vary among differenr neurons

Answer 120

Some cellsshow a constant firing frequency in response to constant excitatory input, while some show decelerating/accelerating trains
Some neuron firing rates increase with small changes in input, while some require large input changes

Question 121

How does the spatial distribution of channel types in different regions of neurons vary with a direct bearing on function

Answer 121

eg dendrites/cell body/axon hillock/nerver terminal contain a greater variety of channels than the axon, because the input and output zones actively transform the signals they receive, while the axon is a simple relay line between these zones