Week 2

Question 1

What is meant by a voltage-gated ion channel

Answer 1

• V = I*R, and in this case resistance is not constant (it is a function of membrane potential)
• The more positive the membrane potential, the more conductive the ion channel.

Question 2

What structural features underlie the voltage-dependence of a “voltage-gated ion channel”?

Answer 2

The S4 sub-unit is:
- POSITIVELY charged and voltage sensitive
- full of argenine amino acids
- As membrane is hyperpolarised, argenine in the S4 rushes inward, gate closes, no longer conductive

Question 3

Describe the kinetics of a typical axonal voltage-gated SODIUM channel opening in response to a voltage step from -80mV to 0mV

Answer 3

– +ve reversal potential –
at zero membrane potential, we have -ve current = INward

at -ve potential, we have no current (no conductivity)
at +ve potential, we have outflow trending linearly with potential

Looks like GELU function

When the membrane potential goes from -80 mV to 0 mV, Na+
channels rapidly open with a short delay of ~10 µs, but then, Na+ channels close again after ~200 µs and remain closed as long as the membrane potential is depolarized.

Question 4

Describe the kinetics of a typical axonal voltage-gated POTASSIUM channel opening in response to a voltage step from -80mV to 0mV

Answer 4

– -ve reversal potential –
at zero membrane potential, we have +ve current = OUTward

at -ve potential, we have no current (no conductivity)
at +ve potential, we have outflow trending linearly with potential

Looks like a ReLU function (R in ReLU ~= the P in potassium)

When the membrane potential goes from -80 mV to 0 mV, K+ channels open, but with a longer delay of ~200 µs, and remain open as long as the membrane potential is depolarized.

Question 5

Is Na or K flow explosive or stabilising? Why?

Answer 5

Think of the voltage-dependent current vs voltage plots of Na/K as we move up to -40mV - the activation point of these channels

Na+:
More voltage => INward current => more voltage [EXPLOSIVE]

K+:
More voltage => OUTward current => less voltage voltage [STABLE]

Question 6

What are the reversal potentials of N+, K+, Cl-, Ca2+

Answer 6

Na+: +60mV
K+: -90mV
Cl-: -85mV
Ca: +123mV

Question 7

What is the timescale of ion channels vs voltage-gated ion channels?

Answer 7

Ion channels is on microsecond timescale, voltage gated kinetics is hundreds of microseconds

Question 8

Describe the recovery from inactivation of a typical axonal voltage-gated sodium channel.

Answer 8

It takes about 2-3ms to recover from inactivation

VG Na+ channels are activated by depolarization but
rapidly inactivate. To recover, the membrane potential
needs to return to hyperpolarized values. The
recovery time course can be measured by imposing 2
depolarizing voltage steps to the membrane and
varying the time interval between the two steps.
When the time interval is very short, VG Na+ channels
do not have time to fully recover from inactivation,
therefore the transient current evoked by the second
voltage step is reduced. As the time-interval increases,
VG Na+ channels recover more from inactivation and
the current evoked by the second step increases, until
it reaches the same amplitude as the for the first
voltage step.

Question 9

Describe Na+ vs K+ ion channel diversity

Answer 9

Na+:
- encoded by one of 9 genes
- these genes will individually encode all 4 sub-units (and 6 transmembrane domains/proteins of each) starting with C terminal, ending with N
- beta subunit is small, bonds tightly with alphas

K+:
- one gene (of ~80 possible) encodes all 6 proteins for a given subunit, but different genes per subunit.

Question 10

Describe the sequence of events underlying the action potential?

Answer 10

• Voltage goes up to above -40mV
• Inward current of Na+ leads to depolarisation, which becomes explosive
• ~200us later this slows
• When the current of Na+ slows, and 2us delay since voltage activation threshold is met, K+ is outflowed to restore the membrane potential.
• Repolarisation, refractory period (for some ms)

Question 11

What determines the amplitude and time-course of the AP?

Answer 11

• The pace of the opening and closing of voltage-gated channels
• Conductances of the sodium and potassium ion channels
• density along axons of “”
• types of “”

Question 12

Different classes of neurons can fire at different maximal frequencies. Why might that be?

Answer 12

Different refractory periods, as defined by pace of K+ channel kinetics
- GABAergic allows for rapid repolarisation, and so quicker refractory
- Glutamatergic is slower

Question 13

Where does the action potential usually initiate? Why?

Answer 13

Initial segment. The protein Ankyrin G binds to both the neuron cytoskeleton (internals of an axon) and Na+ ion channels. This anchors the channels, and ensures their being clustered together in the initial segment so to LOWER the voltage activation threshold for APs.

Question 14

What underlies action potential PROPOGATION?

Answer 14

a strong I_Na+ that will depolarize that part of the cell membrane
but also the nearby areas, where other VG Na+ channels will be activated, thus driving a new regenerative spike. Refractory period ensures unidirectionality

Question 15

What are the key determinants of action potential propagation velocity?

Answer 15

• Membrane resistance must be high to ensure escape of current
• Axon resistance must be low
• Membrane capacitance must be low (charge isn’t lost to membrane)
  these are ensured by MYELINATION:
• Increases axonal membrane resistance by ~500x
• Increases AP speed from 1m/s to 100m/s
  Myelin sheath is made from Glial cells / Schwann cells
  Also high Na+ concentrations in Nodes of Ranvier

Question 16

What are the time and space constants?

Answer 16

Space = sqrt(R_membrane / R_axial) [large = longer]
Time = R_m * C_m [small = quick]

Question 17

Salut ambreee

Answer 17