Neurons and Glia 1

Question 1

Give the ‘official’ definition of ‘reversal potential’. (1)

Answer 1

The potential difference across a membrane when there is no net movement of ions.

Question 2

Give another name for reversal potential. (1)

Answer 2

Equilibrium potential

Question 3

Which ions (out of K, Na, Cl, and Ca) are predominantly extracellular? (1)

Answer 3

Na

Cl

Ca

Question 4

Which ions (out of K, Na, Cl, and Ca) are predominantly intracellular? (1)

Answer 4

K

Question 5

Describe what is meant by the term ‘electrochemical gradient’. (1)

Answer 5

A combination of the concentration (diffusion) gradient of an ion and the electrical gradient acting across the membrane.

Question 6

What is the function of the Nernst equation (what does it calculate)? (1)

Answer 6

The reversal potential of an ion.

Question 7

Give the ‘pure’ form of the Nernst equation. (1)

Answer 7

Ex = RT/zF ln (xo)/(xi)

Question 8

Give the simplified form of the Nernst equation for a mammal at 37 degrees. (1)

Answer 8

Ex = 61.5 log (xo)/(xi)

Question 9

How do you convert from ln to log10? (1)

Answer 9

Multiply by 2.303

Question 10

What does R stand for in the Nernst equation? (1)

Answer 10

Gas constant

Question 11

What does z stand for in the Nernst equation? (1)

Answer 11

Ion valence

Question 12

What does F stand for in the Nernst equation? (1)

Answer 12

Faraday constant

Question 13

What does T stand for in the Nernst equation? (1)

Answer 13

Temperature (Kelvins)

Question 14

According to the Nernst equation, what would Ex of an ion be if the intracellular and extracellular concentrations were equal? (1)

Answer 14

0mV

Question 15

According to the Nernst equation (for a positively charged ion), if the extracellular concentration is higher than the intracellular concentration, will Ex be positive or negative? (1)

Answer 15

Positive

Question 16

According to the Nernst equation (for a positively charged ion), if the extracellular concentration is lower than the intracellular concentration, will Ex be positive or negative? (1)

Answer 16

Negative

Question 17

What is log10 (1)? (1)

Answer 17

0

Question 18

Why are astrocytes important when looking at the Nernst equation? (2)

Answer 18

Astrocytes are permeable to K only

so Em will be equal to Ek.

Question 19

When converting the Nernst equation for Ek to an equation for a straight line, we can disregard [K]i. Why? (2)

Answer 19

Because it takes very few ions to move to carry charge across the membrane.

Therefore, a change in voltage will only result in a negligible change in intracellular ion concentration.

Question 20

How does increasing the extracellular potassium concentration affect the value of Ek and why? (4)

Answer 20

As [K]o increases, Ek increases.

Because the concentration gradient across the membrane is decreased,

and a smaller electrical gradient is required to oppose the concentration gradient,

and stop the net movement of ions across the membrane.

Question 21

What would be the clinical consequence of a rise in extracellular potassium? (2)

Answer 21

Membrane becomes depolarised because Ek increases,

and the neurone then fires too easily.

Question 22

Describe how an astrocyte is able to detect neuronal activity away from the synapse. (3)

Answer 22

During the AP there is efflux of potassium into the extracellular space.

This affects Vm of the astrocyte (makes it less negative)

The astrocyte becomes depolarised.

Question 23

Give a brief description of how potassium activity in astrocytes can quantify neuronal activity. (3)

Answer 23

APs release potassium into extracellular space which changes Vm of astrocytes.

Using the change in Vm, we can use the Nernst equation

to work out the change in [K]o which occurs with an action potential.

Question 24

Describe a method to work out [K]i of astrocytes using electrodes. (4)

Answer 24

Vm of astrocyte is equal to Ek.

When [K]i = [K]o, Ek and Vm are zero.

Keep bathing astrocytes in known concentrations of [K]o until Vm=0.

When Vm=0, [K]i will be the same as [K]o.

Question 25

Why can’t the Nernst equation be used to calculate Em of neurones? (1)

Answer 25

Neurones are permeable to more than one ion.

Question 26

Describe how the Nernst equation predicts the direction and speed with which a particular ion will move across a membrane. (2)

Answer 26

Ion moves across the membrane in the direction that will cause Em to move towards Ex.

The greater the difference between Em and Ex, the quicker/more ions will move.

Question 27

True or false? (1)

An ion will always move down its concentration gradient, even if it means Em will move away from Ex.

Answer 27

False - an ion will always move so that Vm moves towards Ex, even if that means moving against its concentration gradient.

Question 28

Calculate log10 (0.01). (1)

Answer 28

-2

Question 29

Calculate log10 (0.1). (1)

Answer 29

-1

Question 30

Calculate log10 (10). (1)

Answer 30

1

Question 31

Calculate log10 (100). (1)

Answer 31

2

Question 32

How does increasing [K]o affect the peak of the action potential? (1)

Answer 32

It doesn’t - the peak is due to sodium only

Question 33

Why does the afterhyperpolarisation get smaller as [k]o increases? (2)

Answer 33

As [k]o increases there is less of a concentration gradient so Ek gets closer to zero.

Because Vm will approach Ek during repolarisation, it will not go as negative if Ek is not as negative.

Question 34

Describe what is meant by local currents, in relation to the axon. (1)

Answer 34

Excitation in a region of axon will send small currents down the axon and out through the membrane.

Question 35

Give three effects on the action potential of decreasing [Na]o. (3)

Answer 35

• The conduction velocity decreases
• Rate of upstroke decreases
• Action potential amplitude decreases

Question 36

Describe the passive phase of the action potential rise. (3)

Answer 36

• Local currents depolarise small sections of membrane
• Up to the threshold value only
• Vm rises slowly

Question 37

Describe the active phase of the action potential rise. (3)

Answer 37

• Threshold is reached and Na channels open
• The membrane has a rapid-onset, transient, increased conductance to Na
• Vm rises rapidly

Question 38

How does a membrane’s permeability to different ions affect its Vm? (1)

Answer 38

At any instant, the membrane potential will approach the equilibrium potential of the ion to which it is most permeable at that instant.

Question 39

Describe the magnitude and direction of the electrochemical gradient acting on Na at rest. (2)

Answer 39

Large gradient

driving Na into cell.

Question 40

Describe the magnitude and direction of the electrochemical gradient acting on K at rest. (2)

Answer 40

Small gradient

driving K out of cell.

Question 41

At rest, why isn’t Em halfway between ENa and Ek?
Where does it rest? (2)

Answer 41

Because the membrane is much more permeable to K than Na.

Em lies closer to Ek.

Question 42

If the electrochemical gradient acting on Na is larger than the one acting on K at rest, why doesn’t more Na move into the cell? (1)

Answer 42

Na channels are not open

Question 43

True or false? (1)

The voltage-gated opening of sodium channels during the rising phase of the action potential is an example of negative feedback.

Answer 43

False - it is an example of positive feedback

Question 44

What accounts for the increased conductance to K during the repolarisation phase of the action potential? (1)

Answer 44

Delayed opening of voltage-gated K channels

Question 45

True or false? (1)

When depolarisation occurs, sodium channel inactivation gates are triggered to close.

Answer 45

True - however activation gates open more rapidly to allow transient Na influx, and inactivation gate closing is delayed.

Question 46

Describe the role of the Na channel inactivation gate in the neuronal refractory period. (3)

Answer 46

After depolarisation there is delayed closing of the inactivation gate.

The inactivation gate remains closed until the cell becomes repolarised.

Only then can another AP be stimulated to occur.

Question 47

Describe the states of the activation and inactivation gates of the sodium channel during the rising phase of the action potential. (2)

Answer 47

Activation gates open

Inactivation gates open

Question 48

Describe the states of the activation and inactivation gates of the sodium channel during the resting phase of the action potential. (2)

Answer 48

Activation gate closed

Inactivation gate open

Question 49

Which equation would be used to work out Em of a cell which is permeable to more than one ion? (1)

Answer 49

Goldman Hodgkin Katz

Question 50

What is the Goldman Hodgkin Katz equation? (1)

Answer 50

Em = RT/zF ln (PNa[Na]o + Pk[k]o)/(PNa[Na]i + Pk[k]i

Question 51

What is the effect of increasing PNa on Vm?
Consider how this changes if [k]o were to be increased. (2)

Answer 51

Increasing PNa increases Vm.

As [K]o increases, this effect diminishes

because as [k]o increases it begins to dominate the GHK equation.

Question 52

At low [k]o, which ion dominates the GHK equation? (1)

Answer 52

Sodium

Question 53

How are PNa and Pk expressed in the GHK equation? (2)

Answer 53

Pk = 1

PNa expressed relative to Pk.

Question 54

True or false? (1)

The numerator of the GHK equation can be treated as a constant.

Answer 54

False - the denominator (PNa[Na]i + Pk[k]i) can be treated as a constant.

Question 55

Describe the effect (and the magnitude of the effect) of [k]o on the resting phase of the action potential. (2)

Answer 55

Low [k]o makes Vm slightly more negative.

Small effect because membrane is also slightly permeable to Na.

Question 56

Describe the effect (and the magnitude of the effect) of [k]o on the peak of the action potential. (2)

Answer 56

No effect

The membrane is almost exclusively permeable to Na.

Question 57

Describe the effect (and the magnitude of the effect) of [k]o on the afterhyperpolarisation phase of the action potential. (2)

Answer 57

Lower [k]o produces larger (more negative) hyperpolarisation.

Large effect because membrane is almost exclusively permeable to K.

Question 58

At high concentrations of Na, what effect size will decreasing [Na]o have on ENa? (1)

Answer 58

Very little decrease

Question 59

At low concentrations of Na, what effect size will decreasing [Na]o have on ENa? (1)

Answer 59

Large decrease

Question 60

According to the GHK equation, why does changing [Na]o at resting membrane potential have very little overall effect on Em? (1)

Answer 60

PNa is very small

Question 61

Complete the sentence. (1)

At low [K]o, the ………………… ion contributes more to the position of Vm.

Answer 61

Sodium

Question 62

Complete the sentence. (1)

At high [K]o, the ………………… ion contributes more to the position of Vm.

Answer 62

Potassium

Question 63

How does the neuronal Vm compare to the astrocyte Vm at the same [k]o? (1)

Answer 63

Less negative

Question 64

If 10mM K was added to the extracellular fluid in the brain, would Vm of the neurone or the astrocyte increase more? (1)

Answer 64

Astrocyte

Question 65

In an experiment where [k]o is gradually increased and change in neurone and astrocyte Vm is compared, would a bigger difference be seen at low [k]o or high [k]o? (1)

Answer 65

Low

Question 66

Give two differences between myelin in the CNS and myelin in the PNS. (2)

Answer 66

• CNS provided by oligodendrocytes and PNS provided by Schwann cells
• In CNS one oligodendrocyte myelinates many axons, in PNS one Schwann cell myelinates only one axon

Question 67

For each axon in the CNS and PNS, is myelin contributed to by just one cell or from many cells? (1)

Answer 67

Many

Question 68

Describe the structure of a single sheet of myelin (including how many layers there are and how these layers sit in relation to each other). (3)

Answer 68

2 layers of myelin

Layers sit close together in middle

Around the edges, the layers are separated by cytoplasm

Question 69

True or false? (1)

A single sheet of myelin is a little like ravioli - the layers are ‘stuck together’ at the edges and separated by substance towards the middle.

Answer 69

False - it is the opposite way round.

Question 70

True or false? (1)

As the myelin wraps around an axon, the leading edge (which is the edge closest to the oligodendrocyte cell body) tucks underneath the existing layers of myelin.

Answer 70

False - The leading edge (which is the edge FURTHEST from the cell body), pushes under the rest of the myelin layers.

Question 71

Which edge of the myelin sheet grows and forms new layers? (1)

a) the edge closest to the cell body
b) the edge furthest from the cell body

Answer 71

b) the edge furthest from the cell body

Question 72

True or false? (1)

Looking at a transverse section of a myelinated axon right next to the node of Ranvier will show less layers of myelin than looking at a section of axon in the internodal region.

Answer 72

True - the inner tongue has a shorter width than the outer tongue because the sheet of myelin is not a perfect rectangle.

Question 73

When looking at transverse sections of myelinated axons, what is happening at the intraperiod lines? (1)

Answer 73

The 2 outer faces of subsequent myelin wraps meet (one myelin sheet is stuck to a separate myelin sheet)

Question 74

When looking at transverse sections of myelinated axons, what is happening at the major dense lines? (1)

Answer 74

The two inner faces of the same myelin sheet meet (where the two layers of one sheet are stuck together)

Question 75

How does myelinating an axon affect capacitance? (1)

Answer 75

It reduces it

Question 76

Is the relationship between membrane capacitance and number of myelin wraps linear? (1)

Answer 76

No - it is exponential

Question 77

Does increasing the number of myelin wraps have more effect on membrane capacitance when there are more or less existing myelin wraps? (1)

Answer 77

Less

Question 78

What is the meaning of the ‘g ratio’, in relation to myelin? (1)

Answer 78

The g ratio determines the optimal number of wraps of myelin.

Question 79

Give the equation for the g ratio, and describe it in words. (2)

Answer 79

g ratio = di/do

Ratio of the axon diameter divided by the combined diameter of axon and myelin.

Question 80

What does the value of the g ratio tend to be for central axons? (1)

Answer 80

0.75

Question 81

True or false? (1)

Myelinating very small axons would actually slow down their conduction velocity.

Answer 81

True - however only very small axons

Question 82

True or false? (1)

Increasing the diameter of unmyelinated axons is an efficient way to increase conduction velocity.

Answer 82

False - Increasing axon diameter in unmyelinated axons does not increase conduction velocity that much

Question 83

Mammalian nervous systems would have much higher conduction velocities if all axons had large diameters and as many layers of myelin as possible.

Why doesn’t this happen? (2)

Answer 83

To keep the system compact.

And so that the brain doesn’t take up too much energy.

Question 84

Give the two main components of myelin and their relative contributions. (2)

Answer 84

Predominantly fat

Some protein

Question 85

Name the two main proteins found in CNS myelin. (2)

Answer 85

• MBP (myelin basic protein)
• PLP (myelin proteolipid protein)

Question 86

Name the main protein found in PNS myelin. (1)

Answer 86

P0 (myelin protein zero)

Question 87

You get given a sample of myelin to test in the lab without the originating glial cell. How do you tell if the myelin is from the CNS or the PNS? (1)

Answer 87

CNS myelin and PNS myelin differ in their protein composition.

Question 88

What is the role of tight junctions in myelin? (1)

Answer 88

To stop current from leaking out of the axon between myelin layers.

Question 89

In the axon-myelin partnership, give two places where tight junctions may form. (2)

Answer 89

• Between axon and myelin
• Between layers of myelin

Question 90

Describe the distribution of voltage gated Na channels at the nodes of Ranvier. (1)

Answer 90

Concentrated at the nodes

Question 91

Describe the distribution of voltage gated K channels at the nodes of Ranvier. (1)

Answer 91

Located at the juxtaparanodal and internodal regions.

Question 92

Give two proposed roles of voltage gated K channels at the internodal regions. (2)

Answer 92

• Maintaining Vm at internodal region
• Preventing aberrant firing of the axon

Question 93

If there are no voltage gated K channels at the nodes of Ranvier, how does repolarisation occur, and what differences are seen compared to areas which do have VGK channels? (2)

Answer 93

Repolarisation happens due to leak K channels.

The hyperpolarisation will be smaller.

Question 94

Give three factors which affect the axonal conduction velocity. (3)

Answer 94

• Longitudinal resistance of axoplasm
• Capacitance of axon membrane
• Membrane resistance

Question 95

Name a muscarinic antagonist. (1)

Answer 95

Atropine

Question 96

Name a nicotinic antagonist. (1)

Answer 96

Curare

Question 97

Which types of ACh receptors are present at the neuromuscular junction? (1)

a) nicotinic
b) muscarinic

Answer 97

Nicotinic

Question 98

Name two AChE inhibitors. (2)

Answer 98

Eserine
Prostigmine

Question 99

Give two effects of prostigmine on the action potential profile. (2)

Answer 99

• Larger response
• Longer-lasting

Question 100

What is the difference between ‘current’ and ‘voltage’? (2)

Answer 100

Voltage is the difference in charge across the membrane.

Current is the movement of charge across the membrane.

Question 101

Which occurs more rapidly at the neuromuscular junction after ACh release - current or voltage change? (1)

Answer 101

Current occurs quicker

Question 102

Which of these statements is correct? (1)

a) the voltage across the membrane causes a change in current

b) the current across the membrane causes a change in voltage

Answer 102

b - the current across the membrane causes a change in voltage

Question 103

Describe the difference between the end plate potential and the action potential at the neuromuscular junction. Describe how they are related? (4)

Answer 103

End plate potential is a depolarisation of the membrane

caused by ACh binding to receptors.

If EPP meets threshold, action potential is produced,

due to opening of voltage-gated Na channels.

Question 104

Roughly what percentage of NMJ end plate potentials DO NOT result in an action potential? (1)

Answer 104

0% - the NMJ is a very reliable synapse

Question 105

Complete the passage relating to MEPPs. (3)

‘MEPP’ stands for ……………………………

They occur due to ………………………………… at the NMJ.

MEPPs do not result in action potentials because ………………………………..

Answer 105

miniature end plate potential

spontaneous activity

they do not meet the threshold

Question 106

What effect would curare have on the frequency and magnitude of NMJ MEPPs? (2)

Answer 106

Decreased frequency

Decreased magnitude

Question 107

What effect would prostigmine have on the frequency and magnitude of NMJ MEPPs? (2)

Answer 107

Increased frequency

Increased magnitude

Question 108

What effect would decreasing Ca have on the frequency and magnitude of NMJ MEPPs? (2)

Answer 108

Decreased frequency

No effect of magnitude

Question 109

What effect would decreased Na have on the frequency and magnitude of NMJ MEPPs? (2)

Answer 109

No effect on frequency

Decreased magnitude

Question 110

What is a quantum in general terms? (1)

Answer 110

A discrete, individual amount of a substance.

Question 111

Describe the term ‘quantal release’ as it relates to neurotransmitters and MEPPs. (3)

Answer 111

A quantum can be referred to as the amount of NT in a single vesicle.

Each MEPP is due to release of a multiple of one quantum, ie. a certain number of vesicles being released.

Most MEPPs correspond to one unit of quantal release, ie. one vesicle being released.

Question 112

In an MEPP, if one unit of quantal release causes a change in voltage of 0.4mV, what change would a triple quantal release cause? (1)

Answer 112

1.2mV

Question 113

Describe how calcium causes presynaptic vesicles to release neurotransmitter.
What is this process called? (3)

Answer 113

Calcium causes proteins on the vesicles and membrane to interact.

This releases neurotransmitter

and is called synaptic docking.

Question 114

Name four proteins which are required for synaptic docking. (4)

Answer 114

v-SNARE
t-SNARE
SNAP
NSF

Question 115

ACh receptors are neurotransmitter-gated ion channels. Which ion/ions are ACh channels permeable to at the NMJ?

Answer 115

Na
K

Question 116

If Vm of the membrane at the NMJ is negative, what will happen in terms of ion movement and currents when ACh channels open? (1)

Answer 116

Na moves in

Question 117

If Vm of the membrane at the NMJ is positive, what will happen in terms of ion movement and currents when ACh channels open? (1)

Answer 117

K moves out

Question 118

Describe what is meant by ‘habituation’. (1)

Answer 118

A reduction in response after experiencing repeated unimportant stimuli.

Question 119

Describe the molecular process of habituation in a monosynaptic reflex. (2)

Answer 119

Decreased synaptic effectiveness between sensory and motor neurone,

due to decreased NT release from both sensory and motor neurones.

Question 120

Describe the action potentials seen in sensory and motor neurones in the process of habituation in a monosynaptic reflex. (2)

Answer 120

Normal AP in sensory neurone.

Diminished AP in motor neurone.

Question 121

Describe how the sensitivity of postsynaptic receptors is altered during habituation of a monosynaptic reflex. (1)

Answer 121

It is unaltered

Question 122

What is meant by sensitisation? (1)

Answer 122

Repeatedly experiencing harmful stimuli leads to increased synaptic efficacy.

Question 123

Give two examples of when sensitisation may occur. (2)

Answer 123

If a dangerous event has just happened, defence responses are enhanced.

If an injury has just occurred, responses to stimulation of adjacent skin are enhanced.

Question 124

Which neurotransmitter is involved in short term sensitisation? (1)

Answer 124

Serotonin

Question 125

Describe the molecular mechanism of short term sensitisation. (8)

Answer 125

Facilitating interneurone releases serotonin.

Serotonin binds to metabotropic 5HT GPCR on sensory neurone.

Binding of 5HT activates cAMP-dependent protein kinase A (via second messenger).

cAMP-dependent PKA phosphorylates certain K channels and closes them.

Reduced outward K current.

Prolonged AP, allowing more Ca to enter cell.

More NT release.

PKA also acts directly on vesicles.

Question 126

What is classical conditioning? (1)

Answer 126

An animal learns to associate one type of stimulus with another.

Question 127

Describe what is meant by the ‘unconditional stimulus’ in classical conditioning.
Give an example in Pavlov’s dogs. (2)

Answer 127

Stimulus will usually always evoke a response without requiring training.

Eg - food causes salivation

Question 128

Describe what is meant by the ‘conditional stimulus’ in classical conditioning.
Give an example in Pavlov’s dogs. (2)

Answer 128

Will not usually cause the response unless training has occurred.

Eg - bell does not usually cause salivation

Question 129

Briefly describe the process of classical conditioning. (3)

Answer 129

Conditional stimulus and unconditional stimulus are repeatedly paired.

Animal learns to associate them.

Conditional stimulus will then produce a response similar to that seen with the unconditional stimulus.

Question 130

Describe the ideal timing of the pairing of the stimuli in classical conditioning. (2)

Answer 130

Conditional stimulus should precede the unconditional stimulus

by about 0.5 seconds.

Question 131

Describe the molecular mechanism of classical conditioning. (5)

Answer 131

Conditional stimulus produces an action potential in the sensory neurone.

Calcium influx into presynaptic terminal.

5HT released by facilitating interneurone due to unconditional stimulus.

Because Ca is already in presynaptic neurone, the 5HT response is enhanced.

Presynaptic neurotransmitter release is enhanced.

Question 132

In classical conditioning, how does calcium enhance the effect of 5HT on the presynaptic neurone? (3)

Answer 132

Calcium binds to calmodulin.

Calcium and calmodulin activates adenylyl cyclase.

More cAMP is produced.

Question 133

Complete the sentence. (3)

Long term sensitisation and classical conditioning results from the production of new ……………… and ………………….., which is initiated and carried out by the action of repeated ………………………………

Answer 133

Proteins

Synapses

Short term sensitisation

Question 134

In which part of the brain does long term potentiation occur? (1)

Answer 134

CA1 of the hippocampus

Question 135

What is the function of long term potentiation? (1)

Answer 135

Memory formation

Question 136

How is the fEPSP slope affected in CA1 neurones after LTP has occurred? (1)

Answer 136

It increases (gets steeper)

Question 137

Which cells have to be stimulated to produce LTP in CA1 neurones? (1)

Answer 137

Schaffer collaterals

Question 138

Give 3 requirements needed in CA1 for LTP to occur. (3)

Answer 138

CA1 neurone must have a large enough depolarisation.

Temporal summation.

Spatial summation.

Question 139

Describe the molecular mechanism of LTP. (9)

Answer 139

Glutamate binds to AMPA receptors.

Na influx into cell.

Cell is depolarised.

Mg displaced and NMDA channel is opened.

Na and Ca enter through NMDA channel.

Ca activates protein kinase C and calcium calmodulin dependent protein kinase II (CaMKII).

Phosphorylation of AMPA receptors and increased number of AMPA receptors expressed on membrane.

Increased post-synaptic current.

Also retrograde signalling enhances presynaptic NT release.

Question 140

Describe why a small presynaptic action potential will not cause a current to flow through postsynaptic NMDA receptors, and how a current CAN be produced. (3)

Answer 140

Mg blocks up NMDA receptors.

Mg is not displaced until the membrane is depolarised.

This is achieved through AMPA receptors.

Question 141

AMPA channels are permeable to what ion/ions?

Answer 141

Na
K

Question 142

NMDA channels are permeable to what ion/ions?

Answer 142

Na
K
Ca

Question 143

NMDA channels are activated by glutamate, but they also have to be coactivated by which other molecule? (1)

Answer 143

Glycine

Question 144

It is hypothesised that glutamate may also promote LTP by binding to metabotropic GPCRs. How do GPCRs help to promote LTP? (1)

Answer 144

Calcium release from endoplasmic reticulum.

Question 145

Which one of these experiments has NOT been shown to produce deficits in LTP and memory in animals? (1)

• Knock out CaMKII gene
• Knock out NMDA receptors
• Knock out NMDA gene
• Knock out CaMKII gene
• Knock out calcium gene

Answer 145

Knock out calcium gene - there is no calcium gene you idiot.