Neuronal Function Flashcards

Question 1

Q

What major system is involved in neuronal function

Answer

A

the nervous system

Question 2

Q

What are the main functions of the nervous system?

Answer

A

perception
learning and memory
decision making
sensing environment
motor signal delivery

Question 3

Q

Where are communication and information processing encoded?

Answer

A

in neuron activity and chemical signaling

Question 4

Q

What are the 2 parts of the nervous system?

Answer

A

central nervous system (CNS)
peripheral nervous system (PNS)

Question 5

Q

What are the components of the CNS?

Answer

A

the brain and spinal cord

Question 6

Q

What are the components of the PNS?

Answer

A

neurons and glia external to the CNS

Question 7

Q

T or F: neurons and glia are only found outside the CNS

Answer

A

false, they are also present in the CNS

Question 8

Q

What allows a large complexity of behaviours in humans?

Answer

A

the massive amount of neurons and synapses in our brains

Question 9

Q

What happens in the signal reception neural zone?

Answer

A

dendrites and cell body receive incoming signal and convert it into a change in membrane potential

Question 10

Q

How many neurons are in the human brain? How many synapses?

Answer

A

neurons: 10^11
synapses: 10^14-10^15

Question 11

Q

T or F: all neurons have the same structure and properties

Question 12

Q

T or F: all neurons use the same basic mechanisms to send signals

Question 13

Q

What are the 4 basic neural zones of a motor neuron?

Answer

A

signal reception:
- dendrites
- cell body (soma)

signal integration:
- axon initial segment

signal conduction:
- axon (some in myelin sheath)

signal transmission:
- axon terminals at the synapse

Question 14

Q

What happens in the signal integration neural zone?

Answer

A

at the axon initial segment, a signal (change in membrane potential) is converted into an action potential

Question 15

Q

What happens in the signal conduction neural zone?

Answer

A

the axon potential travels down the axon (sometimes covered in a myelin sheath)

Question 16

Q

What happens in the signal transmission neural zone?

Answer

A

the action potential reaches the axon terminals (presynaptic boutons) and causes the release of a neurotransmitter into the synapse

Question 17

Q

Where in a neuron is an action potential generated?

Answer

A

in axon initial segment where the membrane potential change is converted into an action potential

Question 18

Q

What are dendrites? What is their function?

Answer

A

fine, branching extensions projecting from the neuronal cell body

dendrites sense incoming signals and convert them into electrical signals by changing the membrane potential which is transmitted to the cell body

Question 19

Q

What is the cell body? what are its functions?

Answer

A

stores the nucleus, most organelles, and is the location of protein synthesis

functions in receiving incoming signals

Question 20

Q

What is the axon hillock? what are its functions?

Answer

A

the axon hillock is involved in signal integration

its located at the junction between the cell body and the axon

this is where an action potential can be generated
- if an incoming signal sent from the dendrites and cell body is large enough when it reaches the axon hillock, an action potential will occur in the axon

Question 21

Q

What is the axon? what are its functions?

Answer

A

extending from the axon hillock and cell body, a skinny extension is where the action potential is initiated if the signal at the axon hillock is large enough

Question 22

Q

What part of the neuron is specialized for signal conduction?

Question 23

Q

T or F: axons are usually really short, but some can be multiple meters long

Answer

A

true, most are only a few mm long but for ex. in blue whales, axons are 25m long

Question 24

Q

What is a myelin sheath? what is its function? what type of neurons have these?

Answer

A

a coating of Schwann cells that intermittently wrap axons of vertebrate motor neurons to increase the conduction speed of electrical signals to axon terminals

Question 25

Q

What are axon terminals? what are their functions?

Answer

A

specialize in signal transmission to target cells

axons usually have multiple axon terminal branches

converts the electrical signal (action potential) into a chemical signal (neurotransmitter)

Question 26

Q

What is the main property of neurons that allows them to store, recall, and distribute information?

Answer

A

their excitability (ability to alter their membrane potential rapidly)

Question 27

Q

What acts as an electrical signal for neurons?

Answer

A

changes in a neuron’s membrane potential

Question 28

Q

What do the axon terminals of one neuron form with the target cell?

Answer

A

a synapse

Question 29

Q

T or F: neurons are the only cells specialized to use changes in membrane potential as an electrical signal across long distances

Question 30

Q

What occurs at the synapse?

Answer

A

the synapse is the junction between a motor neuron’s axon terminal and a target cell

the action potential is converted into a chemical signal (neurotransmitter) at the axon terminal and is released into the synapse where it diffuses to receptors on the target cell

Question 31

Q

What is a resting membrane potential/when does this occur?

Answer

A

the voltage difference (mV) of a neuron’s membrane when the cell is not sending an electrical signal (at rest)

Question 32

Q

What is the most common resting membrane potential (Vm) for neurons? what does this mean in relation to the internal and external cell environment

Answer

A

-70 mV

the inside of the cell membrane is 70mV more negative than the outside of the membrane

it’s expressed relative to the external voltage

Question 33

Q

What 3 ways can a neuron change its membrane potential?

Answer

A

depolarization
repolarization
hyperpolarization

Question 34

Q

Define depolarization

Answer

A

when the membrane potential becomes more positive than resting

Question 35

Q

Define repolarization

Answer

A

when the membrane potential returns to resting potential

Question 36

Q

Define hyperpolarization

Answer

A

when the membrane potential becomes more negative than resting

Question 37

Q

What determines the membrane potential/establishes the potential difference across a membrane?

Answer

A

the relative permeabilities of the membrane to specific ions and the concentration gradients of those ions

Question 38

Q

How are the concentration gradients of ions influenced when the membrane potential is resting?

Answer

A

there’s no net ion movement across the membrane because the RMP counteracts the chemical gradients

Question 39

Q

What is an equilibrium potential for an ion?

Answer

A

the membrane potential at which an ion is distributed equally across a membrane

ex.
K+ inside cell high, K+ outside cell low
K+ leaves cell along chemical gradient, but this makes inside the cell more negative, so the electrical difference brings more K+ ions back in
eventually the driving force pushing K+ out the cell and the electrical force bringing K+ back into the cell balance out = the membrane potential here is the equilibrium potential

Question 40

Q

What is the Nernst equation used for?

Answer

A

calculating the equilibrium potential for an ion

Question 41

Q

What is the Nernst equation?

Answer

A

Eion = (RT/zF) ln ([X outside] / [X inside]

where:
R is the gas constant (8.31 joules/moleK)
T is temperature in K
z is the valence of the ion
F is the Faraday constant (96,485 joules/Voltmol)
[X] is the concentration (M) of the ion

units need to be converted from volts into mV

Question 42

Q

Explain what it means for K+ to have an equilibrium potential of -60mV?

Answer

A

the driving force that moves K+ out of the cell (chemical gradient) is balanced by an additional 60mV of negative charge inside the membrane

so membrane potential has to be hyperpolarized by 60mV to balance the chemical gradient of K+

Question 43

Q

What is the reversal potential?

Answer

A

Also the equilibrium potential of an ion because the direction of the ion movement is reversed when the equilibrium potential is reached

Question 44

Q

Use the Nernst equation to calculate the equilibrium potential for K+ when:
20 degrees C
intracellular K+ = 140 mM
extracellular K+ = 2.5 mM

Answer

A

should equal -101 mV

Question 45

Q

Use the Nernst equation to calculate the equilibrium potential for Na+ when:
20 degrees C
intracellular Na+ = 10 mM
extracellular Na+ = 120 mM

Answer

A

should be +63 mV

Question 46

Q

Use the Nernst equation to calculate the equilibrium potential for Cl- when:
20 degrees C
intracellular Cl- = 1.5 mM
extracellular Cl- = 77.5 mM

Answer

A

should be -99 mV

Question 47

Q

What’s the z value for K+?

Answer

A

valence of K+ = +1

Question 48

Q

What’s the z value for Na+?

Answer

A

valence of Na+ = +1

Question 49

Q

What’s the z value for Cl-?

Answer

A

valence of Cl- = -1

Question 50

Q

why are Na+, K+, and Cl- important ions to understand their equilibrium potential?

Answer

A

because all 3 have leak channels in a neuron membrane and contribute to the changes in the membrane potential

Question 51

Q

What factors contribute to membrane potential?

Answer

A

distribution of ions across membrane

relative permeability of the ions controlled by leak channels

charges of the ions

Question 52

Q

How is the membrane potential calculated?

Answer

A

the Goldman-Hodgkin-Katz equation for Vm

Question 53

Q

what is the Goldman-Hodgkin-Katz equation for membrane potential?

Answer

A

Vm = (RT/F)ln* (Pk[K+out] + PNa[Na+out] + PCl[Cl-in]) / (PK[K+in] + PNa[Na+in] + PCl[Cl-out])

it’s the sum of the equilibrium potentials for the ions considered while considering the relative permeabilities of each ion (Pion)

Question 54

Q

What is g in the Goldman formula?

Answer

A

conductance which is similar to permeability

Question 55

Q

How can the Goldman equation be simplified?

Answer

A

by using g = conductance instead

Vm = (EKgK + ENagNa + ECl*gCl)/ (gK + gNa + gCl)

Question 56

Q

What two major ion pumps are involved in mediating membrane potential changes?

Answer

A

Na+ / K+ ATPase pump

Question 57

Q

How does the Na+ / K+ ATPase pump function?

Answer

A

it maintains the concentration gradient of Na+ and K+ across the membrane = maintains the membrane potential

for every ATP hydrolyzed:
3 Na+ ions pumped out cell
2 K+ ions pumped into the cell

Question 58

Q

For every ATP hydrolyzed, how many Na+ ions are pumped into or out of the cell?

Answer

A

3 Na+ out of the cell

Question 59

Q

For every ATP hydrolyzed, how many K+ ions are pumped into or out of the cell?

Answer

A

2 K+ ions into the cell

Question 60

Q

What does electrogenic mean?

Answer

A

a current is produced

Question 61

Q

What is the result of the Na+ / K+ ATPase pump?

Answer

A

it is electrogenic and produces a current

Question 62

Q

what is the major role of the Na+/K+ ATPase pump?

Answer

A

to maintain membrane potential by pumping the major contributors to membrane potential (Na+ and K+) across the membrane

Question 63

Q

Why do membranes have an intrinsic permeability to ions?

Answer

A

presence of leak channels

Question 64

Q

How does the membrane counteract the constant flow of ions along their chemical gradients?

Answer

A

the Na+ and K+ ATPase pump

Answer 61

A

to cause a change in their membrane potential to act as an electrical signal

Answer 62

A

by opening and closing certain ion channels

Answer 63

A

the charge difference between the inside and outside of the cell membrane decreases = membrane potential becomes less negative

Answer 64

A

either positive ions entering the cell or negative ions leaving the cell will cause the membrane potential to become less negative

Answer 65

A

the difference between the inside and outside of the membrane increases and the membrane potential becomes more negative

Answer 66

A

either negative ions enter the cell or positive ions move into the cell

Answer 67

A

either after a depolarization or hyperpolarization

Answer 68

A

the Nernst and Goldman equations

Answer 69

A

Na+ channels open and the membrane potential becomes less negative and approaches the Na+ equilibrium potential

Answer 70

A

K+ channels open and the membrane potential becomes more negative to reach the K+ equilibrium potential

Answer 71

A

Na+ flows into the cell to make the membrane potential less negative (depolarize)

Answer 72

A

K+ flows out of the cell to make the membrane potential more negative (hyperpolarize)

Answer 73

A

membrane potential will approach that ion’s equilibrium potential

this is predicted by the Nernst equation

Answer 74

A

Na+, K+, Ca2+

Answer 75

A

glutamate receptors (NMDA, AMPA, kainate)

GABAa receptors, glycine recpetors

nicotinic acetylcholine receptors

5-HT3, P2X

ligands are neurotransmitters

Answer 76

A

approximates permeability
the reciprocal of resistance

g= 1/resistance

Answer 77

A

changes to the membrane potential that vary depending on the stimulus intensity

caused by the opening and closing of ion channels

ex. a higher concentration of neurotransmitters increases the chances that an ion channel will open which results in more ion channels opening and staying open for longer = larger change to the membrane potential

Answer 78

A

Na+ and Ca2+

Answer 79

A

K+ and Cl-

Answer 80

A

false, they are short-distance - they degrade over time/distance

Answer 81

A

when the positive charge from an influx of positive ions spreads along the membrane to cause depolarization

this is caused by positive charged ions attracting negative ones and repeling positive ones - pushing them along the membrane

Answer 82

A

false, it decreases in strength

Answer 83

A

conductance is 0
infinite resistance

Answer 84

A

the conductance will be a positive value and the resistance will be its inverse reciprocal

Answer 85

A

it’s how far the membrane potential is from the equilibrium potential of an ion - it determines if an ion will flow across the membrane

Vm - Eion

Answer 86

A

I ion = gion (Vm - Eion)

Answer 87

A

the flow of ions per given time

Answer 88

A

(V) is the difference in electrical potential

Answer 89

A

the force opposing the flow of electrical current

Answer 90

A

Voltage (V) = current (I) * resistance (R)

Answer 91

A

the ability of a membrane to store a charge (Q) when there’s a voltage difference between 2 surfaces

C = Q / V

Answer 92

A

material properties of cell membrane
area of 2 conducting surfaces (larger surface area = larger capacitance)
thickness of insulating layer (greater thickness = lower capacitance)

Answer 93

A

they convert the change to membrane potential to another electrical signal, the action potential

Answer 94

A

action potentials

Answer 95

A

the net amount of graded potential at the axon hillock

Answer 96

A

the value that the membrane potential must reach in order to trigger an action potential (depolarized)

Answer 97

A

resting membrane potential is -70 mV
threshold potential is -55mV

so the membrane has to be depolarized by more than 15 mV to cause an action potential

Answer 98

A

a membrane potential that is not sufficient enough to cause an action potential

Answer 99

A

a membrane potential that is above the threshold potential needed to initiate an action potential

Answer 100

A

a depolarizing graded potential that brings the membrane potential at the axon hillock closer to the threshold potential

Answer 101

A

a hyperpolarizing graded potential that brings the membrane potential at the axon hillock farther from the threshold potential

Answer 102

A

the time it takes for the membrane potential to decay to 37% of its maximal value

basically it’s how well the membrane maintains its charge

Answer 103

A

when the membrane potential decays to 37% of its maximum value

Answer 104

A

cell membrane resistance
cell membrane capacitance

Answer 105

A

tau = rm*cm

time constant = membrane resistance * membrane capacitance

Answer 106

A

time constant is low

Answer 107

A

the membrane capacitor fills up faster
depolarization occurs faster
conduction is faster

Answer 108

A

conduction decreases over distance

Answer 109

A

membrane resistance, extracellular resistance, intracellular resistance

Answer 110

A

the distance it takes for a change in membrane potential to decay to 37% of its original value

Answer 111

A

the change in membrane potential decreases less over distance (more slowly)

Answer 112

A

the change in membrane potential decreases quickly over distance

Answer 113

A

lambda = square root of rm/(ri + ro)

length constant = square root of membrane resistance divided by the sum of the intracellular resistance and the extracellular resistance

Answer 114

A

the extracellular resistance

Answer 115

A

lambda = square root of membrane resistance / intracellular resistance

the extracellular resistance is negligible

Answer 116

A

when membrane resistance is high and intracellular resistance is low

Answer 117

A

resistance ie., conduction with decrement

Answer 118

A

the change in membrane potential (voltage) decreases over distance because of resistance

Answer 119

A

high intracellular and extracellular resistance

and low membrane resistance

Answer 120

A

K+ leak channels are always open so there’s always some positive charge flowing out of the membrane

the extent to which this occurs will depend on the number of leak channels

Answer 121

A

voltage
resistance

Answer 122

A

Ohm’s Law: V = I*R

Answer 123

A

the electrotonic conduction along the axon + the action potential which is produced at specific points on the axon

Answer 124

A

faster, action potential generation requires the opening and closing of voltage-gated ion channels

Answer 125

A

short

electrotonic current flow is only effective for short distances (2-3 mm)

Answer 126

A

action potentials are required because voltage is degraded over time and distance and an action potential ‘boosts’ the signal

Answer 127

A

while it maintains the voltage of the signal, it’s slower because it relies on the opening and closing of voltage-gated ion channels to activate

Answer 128

A

the membrane

Answer 129

A

the membrane has a thin insulating layer that causes negative charges to build up on one side of the layer because they cannot flow through the insulating layer

this causes the repelling of negative charges and the pulling of positive charges towards the capacitor which creates a current along the membrane

Answer 130

A

current flowing through the membrane resistors is equal to the current flowing into the capacitor

= membrane voltage will change slowly

Answer 131

A

most of the current initially flows into the capacitor until it is fully charged, then the current will flow into the resistors to change the membrane potential

slow change to membrane potential

Answer 132

A

glutamate receptors (NMDA, AMPA, Kainate)

nicotinic acetylcholine receptors

5-HT3, P2X

Answer 133

A

GABAa receptors
glycine receptors

they do this either by shunting a current or hyperpolarizing

Answer 134

A

protrusions on dendrites that are the post-synaptic structures of excitatory glutamatergic synapses

Answer 135

A

false, they can be generated simultaneously

Answer 136

A

there’s multiple receptor types

some cause depolarizations, some keep the membrane potential hyperpolarized

Answer 137

A

excitatory post-synaptic potential

it causes depolarization

Answer 138

A

inhibitory post-synaptic potential

it causes hyperpolarization

Answer 139

A

ion leak channels
resistance of cytoplasm
resistance of membrane

Answer 140

A

by net graded potential at the axon initial segment

Answer 141

A

membrane:
depolarization
repolarization
hyperpolarization

Answer 142

A

membrane potential is resting at -70mV

Na+ channels open and Na+ flows into membrane, depolarizing the membrane potential to the threshold potential around -55mV and then a positive mV

K+ channels open more slowly (K+ flows in) and Na+ channels close by inactivation causing repolarization of membrane potential

membrane potential is hyperpolarized as it reaches the equilibrium potential for K+

K+ channels slowly close and membrane potential reestablishes to resting

Answer 143

A

this occurs when the cell is incapable of initiating a new action potential (ex. during the depolarization phase)

Answer 144

A

the period that’s more difficult to initiate new action potential

usually during repolarization or hyperpolarization

Answer 145

A

Huxley and Hodgkin used the giant axon of a squid because it was easier to see

Answer 146

A

voltage clamp technique

inject a voltage and clamp it at that value to measure the induced AP

Answer 147

A

graded potentials vary in magnitude, whereas AP (in a particular cell) are always the same size and shape
GP vary in duration, whereas AP are always the same duration (in a given cell type)
GP degrade with distance, whereas AP do not
GP occur in dendrites and the cell body, whereas AP are in the axons of neurons (and muscle cells)
GP are caused by the opening and closing of different kinds of ion channels whereas AP are only caused by the opening and closing of voltage-gated ion channels

Answer 148

A

each area of an axon has an electrical circuit which contains:

3 resistors: extracellular, membrane, intracellular

a capacitor with 2 conducting materials (ICF and ECF)

Answer 149

A

they either occur or they don’t (threshold potential must be reached or there’s no AP)

there’s no variation in magnitude/amplitude like there is in GPs

Answer 150

A

One AP will trigger another AP in an adjacent area without degradation of the signal

Answer 151

A

the change to the membrane potential which causes the AP is spread along the membrane

Answer 152

A

entry of ions causes the electrotonic current spread which triggers an AP

Answer 153

A

ions move through the voltage-gated channels = current across the membrane

this current spreads electrotonically along the axon

some of the current leaves the axon and backwards along the external side of the axon (completing circuit)

Answer 154

A

myelination
larger diameter of axon

Answer 155

A

faster speed of conduction with more electrotonic flow

Answer 156

A

low membrane resistance = low length constant and decreased conductance speed

Answer 157

A

low ri = increased length constant, increased conduction speed

Answer 158

A

membrane resistance is inversely proportional to radius = larger diameter, lower membrane resistance = lower length constant and conduction speed

Answer 159

A

intracellular resistance is inversely proportional to radius^2 = larger diameter, higher length constant and conduction speed

Answer 160

A

they take up a lot of space = limits the number of neurons that can exist in the nervous system

they require a lot of cytoplasm which makes them energetically expensive to produce and maintain

Answer 161

A

myelination of axons

Answer 162

A

membrane resistance is increased = decreased current loss through leak channels and increased length constant (voltage is maintained for longer distances)

decreased membrane capacitance (insulating layer is thickened to reduce time constant)

overall: increased conduction speed because higher length constant and lower time constant

Answer 163

A

Nodes of Ranvier

Answer 164

A

the exposed axon bits between the myelin sheaths

where Na+ channels are concentrated

Answer 165

A

Na+ channels

Answer 166

A

the myelinated part of an axon

Answer 167

A

when APs jump from node to node (to areas of high Na+ ion channel concentration)

Answer 168

A

very rapid

Answer 169

A

at the nodes of Ranvier because these are areas with high concentrations of Na+ channels

Answer 170

A

through internodes

Answer 171

A

it is produced by

Schwann cells in the PNS and oligodendrocytes in CNS

Answer 172

A

they start at the axon initial segment and only move towards the axon terminal

APs cannot go backwards because the Na+ channels downstream are in the absolute refractory period (cannot be reactivated)

Answer 173

A

electrical and chemical

Answer 174

A

chemical synapses

Answer 175

A

electrical

Answer 176

A

connexins (specialized protein complexes) create aqueous pores between adjacent cells for ions to move (direct communication)

Answer 177

A

the electrical signal in the presynaptic cell is transferred to the postsynaptic cell via gap junctions

Answer 178

A

electrical:
- bidirectional (ions or currents can move from cell A to B or B to A)
- rapid transmission (electrotonic spread)
- signal received by the postsynaptic cell is always similar to the signal in the presynaptic cell

chemical:
- unidirectional
- slow transmission (docking/fusion of vesicles, diffusion across synapse, signal transduction)
- signal received by postsynaptic cell can be different from the signal in the presynaptic cell

Answer 179

A

the signal from the presynaptic cell is the same as the signal received in the postsynaptic cell

Answer 180

A

true

ex. cAMP, ATP, GTP

Answer 181

A

true, they don’t always have to be open

Answer 182

A

unidirectional, only from presynaptic cell to postsynaptic cell

Answer 183

A

calcium

when the presynaptic axon terminal is depolarized, Ca2+ voltage-gated channels open and Ca2+ flows in

influx of Ca2+ causes vesicles to fuse to presynaptic membrane which releases a neurotransmitter

Answer 184

A

action potential reaches presynaptic axon terminal

presynaptic axon terminal is depolarized, Ca2+ voltage-gated channels open and Ca2+ flows in

influx of Ca2+ causes vesicles to fuse to presynaptic membrane which releases a neurotransmitter

neurotransmitter diffuses across synapse and binds to receptor on the postsynaptic membrane

postsynaptic channels open/close

postsynaptic current causes excitatory or inhibitory potential of the cell

neurotransmitter is removed by enzymatic degradation or glial uptake

Answer 185

A

In a study on squid giant synapses:

control: voltage clamp at depolarization of -25mV (from -70mV)

result:
- presynaptic Ca2+ current shows rapid spike then rapid and significant decline before stabilizing
- postsynaptic membrane potential shows slight delay in excitation of membrane potential to approach 0mV

experimental: CdCl Ca2+ channel blocker with voltage clamp at same voltage

result:
- presynaptic Ca2+ current shows no real influx of Ca2+, not much change to current
- no effect on postsynaptic membrane potential

overall: Ca2+ influx is required for release of neurotransmitter which will cause the excitatory response in the postsynaptic membrane potential

Answer 186

A

placed one heart with vagus nerve intact in a chamber of fluid and recorded rhythmic beating until vagus nerve was stimulated
stimulation of vagus nerve slowed heart beat

placed a second heart without direct vagus nerve connection in a second chamber and connected the solution to the first chamber
when the first heart’s vagus nerve was stimulated, the second heart experienced similar effects but at a time delay = there’s an inhibitory effect of the vagus nerve

Answer 187

A

the vagus nerve must be releasing some neurotransmitter (now known to be acetylcholine) that alters heart contractility

Answer 188

A

when the presynaptic axon terminal is depolarized, voltage-gated Ca2+ channels are opened, and because [Ca2+] is low inside the cell and and the equilibrium potential of Ca2+ is +130mV, the electrochemical gradients favour the influx of Ca2+ into the cell

increased Ca2+ inside the axon terminal signal to synaptic vesicles containing neurotransmitters

Answer 189

A

AP reaches presynaptic axon terminal

voltage-gated Ca2+ channels open and Ca2+ flows into cell

Ca2+ binds to synaptotagmin of vesicles containing neurotransmitters

vesicles translocate to membrane and their synaptotagmins bind to SNAREs

vesicles fuse with membrane to release neurotransmitter (exocytosis)

neurotransmitter diffuses across synapse to bind to receptors on postsynaptic cell membrane

binding triggers signal transdusction pathways in postsynaptic cell

Answer 190

A

vesicles contain many molecules of neurotransmitters (all vesicles within the same neuron contain a similar number of molecules of neurotransmitter)

neurotransmitter molecules are packaged into vesicles which then fuse to the membrane surface and are released by exocytosis

every time a vesicle fuses, the same amount of neurotransmitter molecules are released

if an AP frequency increases, the amount of neurotransmitter released will be step-like because each vesicle is packaged with the same amount of neurotransmitter molecules

neurotransmitters are released into the synapse via exocytosis of the vesicle in the same quantities every time a vesicle fuses to the membrane

Answer 191

A

the responses will be of discrete sizes because the neurotransmitters are released in discrete packaged amounts

Answer 192

A

I = npq
where
I = current
n = # of release sites
p = probability of release
q = quantal response size

q = I/np

Answer 193

A

the size of the AP

Answer 194

A

synaptotagmin
SNAREs (syntaxin SNAP-25 and synaptobrevin)

Answer 195

A

Loose SNAREs on vesicles and plasma membrane

SNARE complexes form to dock vesicle

Synaptotagmin on vesicle binds to SNARE complex

Ca2+ enters and binds to synaptotagmin to initiate membrane-vesicle fusion / curvature

membranes fuse and exocytosis releases neurotransmitters into the synapse

Answer 196

A

synaptotagmin and synaptobrevin are on the vesicle

Syntaxin and SNAP-25 are on the presynaptic cell membrane

Answer 197

A

ionotropic or metabotropic

Answer 198

A

they are ligand-gated ion channels

when a neurotransmitter binds to these receptors, the receptor undergoes a conformational change to open the pore and allow ions to move across the membrane

cause rapid changes to membrane potential

Answer 199

A

depolarizing:
glutamate receptor
nicotinic acetylcholine receptors
5-HT3, P2X

hyperpolarizing:
GABAa receptors, glycine receptors

Answer 200

A

depolarize:
- glutamate
- nicotinic acetylcholine
- 5-HT3, P2X

hyperpolarize:
- glycine, GABAa

Answer 201

A

a neurotransmitter receptor that undergoes a conformational change with the binding of a neurotransmitter and initiates a signal transduction pathway via a second messenger

causes a signal cascade in the postsynaptic cell

Answer 202

A

ionotropic receptors cause an immediate change to the membrane potential whereas metabotropic receptors initiate a signal transduction pathway

a signaling cascade will eventually send a message to an ion channel to open and that will alter the mmebrane potential

Answer 203

A

metabotropic because they affect the transcription and translation of receptors and ion channels

Answer 204

A

G-protein coupled receptors

ex. metabotropic glutamate receptors (mGluRs)
muscarinic acetylcholine receptors
serotinergic (5-HT1, 5-HT2, etc)
P2Y
GABAb receptors
norepinephrine
dopamine receptors

Answer 205

A

spatial summation
temporal summation

Answer 206

A

postsynpatic potentials originating from different sites change membrane potential

Answer 207

A

postsynaptic potentials occurring at different times change membrane potential

Answer 208

A

no, they work in combination to change the postsynaptic membrane potential

Answer 209

A

the amount of neurotransmitters released in the synapse and the number of receptors on the postsynaptic membrane

Answer 210

A

the frequency of AP
the probability of release
the number of release sites

Answer 211

A

passive diffusion out of synapse
synaptic enzymes degrade them
surrounding cells uptake them

Answer 212

A

rate of release - rate of removal

Answer 213

A

acetyl CoA is produced in the mitochondria
choline acetyl transferase converts choline + acetyl CoA = Acetylcholine (ACh)
ACh is packaged into vesicles by VAChT
vesicle fuses to presynaptic membrane surface
ACh is released by exocytosis into the synapse
ACh binds to receptor on post-synaptic membrane triggering a signal in the postsynaptic cell
Acetylcholinesterase (AChE) degrades ACh into choline and acetate, terminating signal

Answer 214

A

ionotropic

Answer 215

A

2 ligands

Answer 216

A

Na+, Ca2+, K+

Answer 217

A

close to 0mV

Answer 218

A

excitatory, it depolarizes the membrane

Answer 219

A

2 ligands have to bind for:

closed/resting
activated/open
closed/desensitized

Answer 220

A

acetylcholinesterase hydrolyzes ACh to shorten response

Answer 221

A

ionotropic

Answer 222

A

AMPA and kainate

NMDA receptors

Answer 223

A

glutamate as a ligand

Answer 224

A

Na+ and K+

Answer 225

A

membrane depolarization needs to occur to remove Mg2+ block

require glutamate and either glycine or D-serine to open channel

Answer 226

A

Na+, K+, and Ca2+

Answer 227

A

close to 0mV

Answer 228

A

excitatory, they depolarize the membrane potential

Answer 229

A

glutamate transporters

Answer 230

A

GABAa are ionotropic, GABAb are metabotropic

Answer 231

A

they’re similar, both pentameric

Answer 232

A

depends on Cl- which varies from -80- - 60mV

Answer 233

A

hyperpolarizes or shunts current = inhibitory

Answer 234

A

by GABA transporters

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Neuronal Function Flashcards

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