When a neuron's stimulated by something, electric potential difference changes immediately and inside of the neuron, becomes more potentially positive than the outside of it.

I've read that sodium-pottasiom pump returns membrane potential back to its resting potential at the end of action potential's process.

How sodium-pottasiom pump returns membrane potential back to its resting potential and makes inside of the neuron more potentially possitive when three sodium ions are transported to the out of the cell and just two potassiom ions are transported back into the cell?

I mean, in this condition, it is expected that inside of the cell is gonna be more potentially negative, not more positive.

(Sodium-pottasiom pump ➡ puts 3 Na+ outside - brings 2 K+ inside ➡ 1 negative charge inside...!??)

enter image description here


2 Answers 2


The issue is the permeability of the membrane to Potassium and how membrane potential is created in the first place. The resting membrane potential of the neuron is very close to the equilibrium potential of Potassium. Large fixed anions (proteins) in the cytosol are represented in the image below by [An-]: enter image description here

  1. If Potassium and cytosolic proteins were the only thing inside the cell and the outside were water (ignoring osmotic effects), then in Figure 1 there is an outward K+ concentration gradient.
  2. In Figure 2, we allow the membrane to become permeable to Potassium (as it is in the cell). The Potassium begins to leave [green arrow], but as it does, it begins to create a charge separation that sets up a negative voltage in the cell that pulls the Potassium cation back in [red arrow].
  3. In Figure 3, we see that enough K+ has left the cell to the point that the membrane potential has grown negative enough that the rates of K+ leaving and entering are equal, so no net change in K+ concentration occurs. This is the definition of chemical equilibrium, and so we call this voltage the equilibrium potential of this single-ion system (~-80mV for biologic concentrations of K+).

We could do a similar experiment with Na+ starting high outside in Figure 1, with the arrows reversed, and the equilibrium potential of the Sodium-only system would be ~+60mV.

So, if a real cell has both K+ and Na+ concentration gradients in opposite directions, why don't they just cancel each other out? Why is the resting membrane potential negative, and in fact, much closer to the equilibrium potential for Potassium alone? The answer is: permeability. Imagine if you had Figure 1 again, with [K+] high inside, and [Na+] high outside, as it is in the cell, but in Figure 2 you ONLY made the membrane permeable to K+. Would the Na+ gradient change at all? No, because there would be no pathway for it to move. Thus, if ALL the permeability is for K+, then K+ has all the influence on the membrane potential. If both are equally permeable, it would be their average (-10 mV, or about neutral).

However, the permeability for K+ AT REST is about 20 times the permeability for Na+, so we'd expect the cell's resting potential to be 1/20th of the 140mV "distance" between the equilibrium potentials for K+-only and Na+-only systems, or: -80mV + 1/20(140mV) = -73mV. The fact that it's not exactly -73mV is explained by the existence of a small amount of Cl- and other ion permeability. But, in essence, Potassium determines the resting potential, with a little offset due to sodium permeability.

Now that you understand that, understanding the action potential graph should be easy:

  1. Rising Phase: major increase in Na+ permeability, voltage rises almost to the equilibrium potential of Sodium.
  2. Falling Phase/Undershoot: Na+ permeability shuts down, major increase in K+ permeability, voltage drops back down to equilibrium potential of K+.
  3. Restoration: K+ permeability drops back to normal (not completely shut down), and the Na+/K+ pump just restores the concentration gradients that allow the resting potential in the first place.

So, really, your initial confusion about the electrical work done by the Na+/K+ pump existed because you didn't take it in context with the permeability. Yes, the pump by itself makes the voltage more negative, but some of the potassium it stuffs back into the cell immediately turns around and leaks right back out until it's 95% of the way to its own equilibrium point again, as determined by the membrane permeability.

  • $\begingroup$ So do you mean that after action potential some K+ channels are actually open and they allow K+ ions to come inside the neuron, and it is, therefore, returned to resting potential, and the neuron becomes more potentially positive in a way that it neutralizes the activity of Na+/K+ pump? $\endgroup$
    – a.RR
    Commented Sep 28, 2018 at 13:38
  • $\begingroup$ Yes, sort of. Remember: Without a concentration gradient in the first place, there would never be an electrical gradient. There are two transport proteins which are always on/open, and their actions combined make the resting membrane potential: the Na+/K+ ATPase and ungated K+channels. They perform their function even throughout the duration of the AP. [1/2 - trimmed for length, see next comment] $\endgroup$
    – vipatron
    Commented Sep 28, 2018 at 15:10
  • $\begingroup$ Neurons and striated muscle have other K+ channels that only open when the voltage gets to about ~0mV, near the end of the rising phase of the AP, and are thus voltage-gated. Their closure is what causes the change in slope during the overshoot phase. Like any other chemical process, the membrane potential then returns asymptotically to what the steady state is when all the voltage-gated channels are closed.[2/2] $\endgroup$
    – vipatron
    Commented Sep 28, 2018 at 15:11
  • $\begingroup$ But all in all I cannot find out this sentence I've read in lots of books: "Sodium-pottasiom pump returns membrane potential back to its resting potential at the end of action potential's process." It is K+ channels that does this action NOT Sodium-pottasiom pump, I suppose! $\endgroup$
    – a.RR
    Commented Sep 28, 2018 at 18:12
  • $\begingroup$ No. As I said in the above comment, It is BOTH the Na/K pump and the non-gated K+ channels that create the steady state (resting) membrane potential. Think of the AP as a disturbance, like a wave in a calm pond. Gravity is what made the water flat before the wave, and gravity will return it to the calm flat state. Gravity didn't stop pulling down on the water's surface while the disturbance occurred. Similarly, the Na/K pump creates the flat line in the above graph, keep trying to create it while the EPSP and voltage-gated disturbance happens, and they are responsible for re-flattening it. $\endgroup$
    – vipatron
    Commented Sep 28, 2018 at 19:46

The undershoot or afterhyperpolarization arises due to the increased K+ conductance at the end of the action potential. This is because K+ channels where open during depolarization and it takes some time to close again. Also Na+ channels are inactivated and getting out of this inactivated state also takes time.

So why the potential rises again after this undershoot? This is because K+ channels start closing and thus the membrane permeability for K+ decreases. This makes the membrane potential increase, until it gets back to the resting potential.

The role of the pump is to maintain the ionic gradients of the neuron helping to maintain this resting potential.


You must log in to answer this question.

Not the answer you're looking for? Browse other questions tagged .