Action potential

Question 1

What is the Golgi stain?

Answer 1

• a mixture of silver nitrate and potassium chromate that causes 2% of brain cells to darken in colour
• generates silver chromate, which can crystallize inside of neurons, highlighting every nook and cranny

Question 2

What is crystallization?

Answer 2

• process of atoms or molecules arranging into a well-defined, rigid crystal lattice in order to minimize their energetic state

Question 3

What is the basic structure of the neuron?

Answer 3

• cell body/soma
• dendrites
• axon

Question 4

What is the cell body of a neuron?

Answer 4

• where its nucleus is located

Question 5

What are dendrites?

Answer 5

• branched, treelike extensions from the soma
• collecting information relevant to the cell
• sense what’s outside the cell and receive information

Question 6

What is an axon?

Answer 6

• neuron has one
• can branch many times; axon collaterals
• axon terminal is end of axon
• send information to downstream cells by releasing signalling molecules (neurotransmitters) onto them from the axon terminal

Question 7

What is a synapse?

Answer 7

• junction between an axon terminal and a downstream cell

Question 8

What is voltage?

Answer 8

• difference in electric charge between two points – the electrostatic potential between two points

Question 9

How is voltage measured?

Answer 9

• voltmeter (oscilloscope)

Question 10

What do voltmeters do?

Answer 10

• let a negligible amount of electricity to pass through them (from one wire to the other)
• The amount of resistance needed to allow just a little bit of electricity to flow indicates the charge difference (the voltage) between the two wires
• measured in mV

Question 11

What happens when there is a voltage?

Answer 11

• makes charged particles want to move to neutralize the charge difference

Question 12

What is the charge of the extracellular fluid of the brain?

Answer 12

• 0 mV

Question 13

What is a neuron’s resting membrane potential?

Answer 13

• Membrane potential of a neuron when it is at rest
  -40 mV to -80 mV
  the voltage (the electrostatic pressure) across the membrane makes positively charged ions want to enter the cell and negatively charged ions want to leave the cell

Question 14

What is an ion?

Answer 14

• an atom or molecule that has a net electrical charge
• move around freely in water

Question 15

What are cations?

Answer 15

• positively charged

Question 16

What are anions?

Answer 16

• negatively charged

Question 17

What is electrostatic pressure?

Answer 17

• the attractive force between ions that are oppositely charged and the repulsive force between ions that are similarly charged

Question 18

What are ion channels?

Answer 18

• Proteins that form a pore (a hole) through which ions can pass/flow
• These proteins are placed in the cell membrane
• When open, they let specific ions freely flow in and out of the cell
• Most are bidirectional
• proteins that are encoded in a cell’s DNA

Question 19

What is a leak channel?

Answer 19

• An ion channel that permanently stays open

Question 20

What are the important monovalent cations?

Answer 20

• sodium
• potassium

Question 21

What are the important divalent cations?

Answer 21

• calcium
• magnesium

Question 22

What are the important monovalent anions?

Answer 22

• chloride

Question 23

Which ion is more abundant inside of cells?

Answer 23

• potassium

Question 24

What is the cell membrane?

Answer 24

• phospholipid bilayer
• impermeable to atoms and molecules that readily dissolve in water (nucleic acids, amino acids, ions)

Question 25

What does the intracellular fluid of cells contain?

Answer 25

• lots of negatively charged nucleic acids and amino acids

Question 26

What is the resting membrane potential of cells?

Answer 26

-20 mV

Question 27

What is the resting membrane potential of neurons?

Answer 27

-40 mV to -80 mV

Question 28

Why do neurons create this especially negative resting membrane potential?

Answer 28

• To be able to communicate very quickly from one end of the cell to the other

Question 29

How do neurons create this especially negative resting membrane potential?

Answer 29

Neurons create an electrical potential across their membrane using two proteins:
- sodium potassium pump
- potassium leak channel

Question 30

What is the action potential?

Answer 30

• The rapid propagation of information down the length of an axon
• brief electrical impulse that propagates down the axon
• rapid change in membrane potential
• involves 2 proteins: voltage gated sodium channel and voltage gated potassium channel
• end of the action potential trigger the release of neurotransmitter

Question 31

What is the protein involved in the release of neurotransmitter?

Answer 31

• voltage gated calcium channel

Question 32

What is the sodium potassium pump?

Answer 32

• Neurons fill their cell membrane with the protein
• continually pumps sodium ions out of the cell and potassium ions into the cell
• uses ATP for energy
• makes the concentration of K+ ions 30x higher inside the cell than out
• makes the concentration of Na+ ions 15x more concentrated outside the cell than in

Question 33

What are the steps for the sodium potassium pump?

Answer 33

• at rest, pump is open to inside of cell
• pump binds 3 sodium ions and a molecule of ATP
• splitting of ATP provides energy to change shape of channel; pump switches to outside of cell and sodium ions are driven through and out of cell
• potassium ions bind
• phosphate (molecule of ATP) releases and pump reverts to original form; open inside
• potassium ions released inside cell

Question 34

What are the concentration gradients of a neuron?

Answer 34

• Potassium is concentrated in
• Sodium is concentrated out
• these concentration gradients generate a force: the force of diffusion

Question 35

What is diffusion?

Answer 35

• if there is a concentration gradient and no forces or barriers in the way, then atoms and molecules will move, on average, from regions of high concentration to regions of low concentration

Question 36

What are potassium leak channels?

Answer 36

• Neurons fill their cell membrane with the protein
• permanently open ion channels that freely let K+ ions enter or leave the cell
• more likely to leave the cell than enter it
• force of diffusion competes with force of electrostatic pressure
• K+ ions leave the cell because of diffusion, but they enter the cell because it is negatively charged inside relative to outside
• forces become equal and opposite when the membrane potential falls to -90 mV

Question 37

What happens when the membrane potential is less negative than -90mV?

Answer 37

• force of diffusion wins
• more K+ ions leave

Question 38

What happens when the membrane potential is more negative than -90mV?

Answer 38

• electrostatic pressure wins
• more K+ ions enter

Question 39

Why is the resting membrane potential not -90 mV?

Answer 39

• other ions (primarily Na+) continuously flow into neurons
• permeability of the membrane to K+ ions that largely determines the resting membrane potential
• When a neuron opens up more K+ channels, the membrane potential falls closer to -90 mV
• When a neuron removes some K+ channels from the membrane, the membrane potential becomes less negative

Question 40

What is a membrane potential?

Answer 40

• Electrical charge across a cell membrane
• The difference in electrical potential inside and outside the cell

Question 41

Which proteins are responsible for setting up and maintaining the resting membrane potential of neurons?

Answer 41

• sodium potassium pumps
• potassium leak channels

Question 42

What are receptors?

Answer 42

• sensitive to some aspect of the extracellular environment
• detect and pull in nutrients from the extracellular space
• gain a better understanding of the world around them

Question 43

What are ion channel receptors?

Answer 43

• receptors that are ion channels
• gated
• when activated, change shape and open a pore through which specific ions can flow

Question 44

What is depolarization?

Answer 44

• When the membrane potential of a cell becomes less negative than it normally is at rest

Question 45

What happens when there are changes in the membrane potential?

Answer 45

• changes are transient (short lived)
• neurons quick to return to resting state because K+ leak channels are always open

Question 46

Why is a change in membrane potential never long?

Answer 46

• because of the abundance of K+ leak channels

Question 47

Why are changes in membrane potential important?

Answer 47

• because neurons express a variety of voltage-gated ion channels
• gate on these channels is electrically charged, so it opens (and closes) in response to changes in the membrane potential

Question 48

What is the voltage gated sodium channel?

Answer 48

• used to initiate and propagate the action potential
• protein encoded in the genome
• line the entire length of the axon

Question 49

What is the voltage gated potassium channel?

Answer 49

• to quickly restore the resting membrane potential
• protein encoded in the genome
• line the entire length of the axon

Question 50

What is the voltage gated calcium channel?

Answer 50

• to trigger the release of neurotransmitter
• protein encoded in the genome
• found at the axon terminal

Question 51

What are the steps in the voltage gated sodium channel?

Answer 51

• At rest, the electrically charged gate is pulled closed by the negatively charged interior of the cell
• gate opens when membrane is depolarized to -40 mV (by activated receptor)
• open pore allows Na+ to rush in, further depolarizing
• open for half millisecond before it is clogged with ball and chain
• clog until membrane potential back at rest (half millisecond)
• chain reaction that propagates down length of axon

Question 52

What is the axon hillock?

Answer 52

• where axon connects to soma
• where the action potential starts

Question 53

When do forces of diffusion and electrostatic pressure balance for sodium?

Answer 53

+60 mV

Question 54

When the membrane is at rest, what do sodium ions want to do?

Answer 54

• enter because of diffusion and electrostatic pressure

Question 55

Why do neurons not reach +60 mV?

Answer 55

• because neurons voltage-gated sodium channels get clogged by the ball and chain
• In the 1⁄2 millisecond they are open, the membrane potential reaches +40 mV

Question 56

What are the 2 ways to prevent current flow through a voltage gated sodium channel?

Answer 56

• The pore closes whenever the membrane potential is more negative than -40 mV (at rest)
• the pore gets clogged within a 1⁄2 millisecond after opening; receptor is said to be inactivated until membrane potential returns to rest

Question 57

What is the threshold of excitation?

Answer 57

• value the membrane potential must reach to trigger an action potential

Question 58

What is the initial depolarization that starts an action potential?

Answer 58

• driven by a small influx of Na+ ions through an activated receptor on a dendrite

Question 59

How long would it take for resting membrane potential to be restored with potassium leak channels?

Answer 59

• ten milliseconds
• too long to support rapid action potential firing

Question 60

What are the steps in the voltage gated potassium channel?

Answer 60

• open on upward swing of action potential
• outward flow of K+ ions through both leak channels and voltage-gated potassium channels restores the resting membrane potential within a 1⁄2 millisecond
  -when at rest, close and reset
• extra potassium outside diffuses away

Question 60

What speeds up the restoration of membrane potential?

Answer 60

• the voltage-gated potassium channel

Question 61

What is the refractory period?

Answer 61

• post action potential hyperpolarization
• membrane potential fallen below what it normally is at rest

Question 62

How many action potentials can be fired per second?

Answer 62

• some neurons are capable of firing 400 action potentials per second

Question 63

What happens at the end of the action potential?

Answer 63

• when it reaches the axon terminal, it triggers the opening of voltage gated calcium channels

Question 64

What are the steps to the voltage gated calcium channel?

Answer 64

• action potential arrives at axon terminal
• voltage gated calcium channels open and calcium enters the axon terminal
• calcium triggers the fusion of neurotransmitter filled vesicles with cell membrane
• neurotransmitters are released into the synapse; activate receptors on downstream (postsynaptic) neuron

Question 65

Why does calcium enter the cell with the action potential?

Answer 65

• Calcium is 1000x more concentrated outside the cell than in, so it rushes into the cell, when the gate opens

Question 66

What is synaptic transmission?

Answer 66

• primary means of communication between neurons
• transmission of chemical messages (neurotransmitters) from one neuron to another via synaptic connections
• diffusion of molecules from one neuron to another over synaptic space
• Released neurotransmitters activate receptor proteins on downstream neurons (muscles), which can allow Na+ ions to enter those cells; trigger action potential

Question 67

How does the action potential travel?

Answer 67

• unidirectional
• start in axon hillock and travel down the axon toward axon terminals

Question 68

What prevents the action potential from reversing direction?

Answer 68

• ball and chain inactivation mechanism of the voltage-gated sodium channel

Question 69

What is the all or none law?

Answer 69

• An action potential can occur or not, but once triggered it propagates down the length of the axon without growing or diminishing in size
• no such thing as a strong or weak action potential

Question 70

What is the rate law?

Answer 70

• the strength of the “message” is represented by the rate of firing (the number of action potentials per second, not size or speed)