ICPP

Question 1

Name an amine hormone

Answer 1

NA, adrenaline, dopamine, 5-HT

Question 2

Out of amine, peptide and steroid hormones, order how long their half lives are

Answer 2

Amine seconds, peptide minutes, steroids hours

Question 3

Name an amino acid neuroT

Answer 3

Glutamate, glycine, GABA

Question 4

What are metabotropic receptors?

Answer 4

GPCRs

Question 5

How do ionotropic Rs carry out their effects?

Answer 5

Ca2+ coupled

Question 6

Name the alpha protein and effector molecules involved in GPCRs

Answer 6

a1 Gaq activ PLC --> IP3 and DAG
a2 Gai inhib AC --> cAMP --> PKA
B Gas activ AC --> cAMP --> PKA
M1/3 Gaq activ PLC --> IP3 and DAG
M2/4 Gai inhib AC --> cAMP --> PKA

Question 7

Describe the structure of a GPCR

Answer 7

7TM, single polypeptide, N terminus is extracellular and C terminus intracellular

Question 8

What happens following PLC activation

Answer 8

Has two effectors, IP3 and DAG. IP3 joins to IP3 receptor on SR/ER which causes calcium release. DAG activates PKC which phosphorylates proteins

Question 9

What happens following AC activation

Answer 9

AC hydrolyses ATP to create cyclic AMP which then activates PKA which phosphorylates proteins

Question 10

At what stage is there signal amplification in GPCR signalling

Answer 10

AC activates many molecules of cAMP
PKA phosphorylates many proteins
PLC activates two effectors (IP3 and DAG)
DAG phosphorylates many proteins

Question 11

Name all the calcium transporters/channels in a cell

Answer 11

Plasma membrane: NCX, PMCA Ca out, NOCC Ca in, LGIC Ca in

SR/ER: IP3 Ca out, SERCA Ca in, CICR (ryanodine Rs) Ca out

Question 12

Which molecules can pass through the lipid bilayer?

Answer 12

Small uncharged polar or any hydrophobic molecules

Question 13

What determines rate of passive transport?

Answer 13

Permeability coefficient and concentration gradients on each side J=P(C1-C2)

Question 14

If ∆G is positive, what does this mean about the transport process?

Answer 14

Its active transport! ∆G negative is passive transport

Question 15

What determines if it will be active or passive transport?

Answer 15

Dependent on concentration ratio and membrane potential

Question 16

What are the glucose and fructose transporters for both sides?

Answer 16

Glucose SGLT, fructose GLUT5 and then both GLUT2 on basolateral side

Question 17

Give an example of an ATPase Calcium transporter

Answer 17

PMCA (transports Ca out of cell)

Question 18

What type of transporter is SGLT?

Answer 18

Cotransporter/symtransporter. Transports Na and glucose into cell

Question 19

What is mainly responsible for RMP of -70mV?

Answer 19

Passive K+ diffusion out of cell through K+ channels

NOT Na/KATPase, this is only responsible for 5-10mV

Question 20

Name two antiports

Answer 20

NCX (NaCa), NHE (Na H)

Question 21

How does NaKATPase drive secondary active transport?

Answer 21

Drives Na out so provides energy for transporters that bring Na in e.g. Na/H or Na/Ca antiports or Na/glucose Na/aa symport

Question 22

Name primary active, secondary active and facilitated transporters in Calcium

Answer 22

Primary active: PMCA (Na/CaATPase), SERCA
Secondary active: NCX
Facilitated: mitochondrial Ca uniports at high Ca to buffer harmful effects

Question 23

What is NCX?

Answer 23

3 Na in, one Ca out (can reverse mode of operation if low Ca or high Na

Question 24

Why do you get reversal of NCX activity in ischemia?

Answer 24

So normally NCX moves 3Na in and 1Ca out, but if ischaemic then NaCaATPase (PMCA) doesn’t work so then Na accumulates in cell so NCX reverses direction

Question 25

What transporters control cell pH

Answer 25

NHE (Na in H out antiport), AE (HCO3- out, Cl- in)

Question 26

What do you need to have a membrane potential?

Answer 26

Ion gradients and selective ion channels

Question 27

What is the nernst equation?

Answer 27

Gives the equilibrium potential for an ion (=where chemical and electrical charges are balance) i.e. the membrane potential where the ion will be in equilibrium

Question 28

If you increase membrane permeability, you move it closer/further away from its equilibrium potential?

Answer 28

Closer to its equilibrium potential

Question 29

What is fast synaptic transmission?

Answer 29

Where the R is also an ion channel e.g. Nictonic ACh R that lets sodium in

Question 30

What are excitatory and inhibitory synapses?

Answer 30

Ligand-gated ion channels

Excitatory causes EPSP (ACh, glutamate, dopamine) and inhibitory cause IPSP (glycine, GABA)

Question 31

Give examples of slow synaptic transmission

Answer 31

GPCRs, use of intracellular messengers

Question 32

How can you measure the RMP of a cell?

Answer 32

With a microelectrode

Question 33

Where does depolarisation initiate an ap?

Answer 33

The axon hillock

Question 34

What are the ARP and RRP?

Answer 34

Absolute refractory period- another AP cannot be generated as nearly all Na channels are in the inactivated state (they have already let Na in and now are tired)
Relative refractory period- a strong stimulus may generate an AP, Na channels recover from inactivation and less are inactivated

Question 35

What is the structure of voltage gated Na channel?

Answer 35

Channel is made of one alpha subunit. Has four domains (I,II,III,IV) each with 6 transmembrane alpha helices. The S4 segments in each domain act as a voltage sensory- they are positively charged and following depolarisation initiate a conformational change in the channel and cause the pore to open. The pore is between S5 and S6.

Question 36

What is the structure of voltage gated K channels?

Answer 36

Similar to voltage gated Na channels except the K channel has 4 alpha subunits. Same as Na channel with S4 voltage sensor and pore between S5 and S6.

Question 37

How do local anaesthetics such as procaine work?

Answer 37

Block Na channels

Question 38

In terms of axons, what order do local anaesthetics block them?

Answer 38

1st small myelinated
2nd unmyelinated
3rd large myelinated

Question 39

What fibres conduct sharp localised pain?

Answer 39

Ad

Question 40

What fibres conduct diffuse pain? (as well as itch)

Answer 40

C fibres

Question 41

What theory describes the spread of charge along the axon and causes propagation of the action potential?

Answer 41

Local currents

Question 42

What is capacitance and what is it a property of?

Answer 42

Ability to store charge, a property of the lipid bilayer

Question 43

What is membrane resistance?

Answer 43

Relates to the number of open ion channels (high resistance = lots of ion channels closed)

Question 44

Would would a high capacitance membrane mean for conduction?

Answer 44

Stores lots of charge so membrane charge changes more slowly

Question 45

What would a high resistance membrane mean for conduction?

Answer 45

Lots of ion channels closed so change in voltage will spread further along the axon

Question 46

Describe the structure of the myelin sheath

Answer 46

Schwann cell rotates around the axon to make a spiral. It is high resistance so allows current to spread further. Decreases membrane capacitance

Question 47

What do nodes of ranvier have high concentrations of?

Answer 47

Na channels

Question 48

What is saltatory conduction?

Answer 48

Conduction of an action potential via action potentials only occuring at nodes of ranvier then “jumping” to the next node due to the myelin sheath (which is high resistance so ap can spread)

Question 49

Name a demyelinating disease

Answer 49

Multiple sclerosis (stops saltatory conduction)

Question 50

Myelinated axons have a low/high resistance and a low/high capacitance?

Answer 50

High resistance, low capacitance

Question 51

What channels are involved in the NMJ

Answer 51

depolarisation triggers opening of Ca channels which trigger neuroT release, ACh binds to nAChR on end plate and causes voltage gated Na influx, this depolarises muscle fibre which then contracts

Question 52

Does the frequency of APs change amount of Ca entry and neuroT release?

Answer 52

Yes, higher frequency APs = more Ca entry = more neuroT release

Question 53

Describe the structure of voltage gated Ca channels?

Answer 53

Very similar to Na with 4 domains in a subunit (I,II,III,IV)

Question 54

Which subunit of Na and Ca voltage gated channels forms the pore?

Answer 54

Alpha subunit

Question 55

Which activates faster: Na or Ca voltage-gated channels?

Answer 55

Na much faster, Ca are slow

Question 56

What breaks down ACh?

Answer 56

Acetycholine esterase

Question 57

How does Ca entry lead to neuroT release?

Answer 57

Enters, binds to vesicle via synaptotagmin, vesicle moves close to membrane, Snare complex makes a fusion pore, neuroT released through pore

Question 58

What ions does nAChR let through?

Answer 58

Cations, N+ and K+

Question 59

What is an end plate potential?

Answer 59

Axon action potential –> neuroT release –> depolarisation of motor end plate occurs. This is the end plate potential –> generates action potential in the muscle

Question 60

Name a disease involving the NMJ

Answer 60

Myasthenia gravis- autoimmune against nAChRs causing profound weakness because end plate potentials are reduced

Question 61

Why are nAChRs fast acting?

Answer 61

Ligand gated ion channel (unlike GPCRs which have to trigger events)

Question 62

What are Bmax and Kd?

Answer 62

Bmax is maximum binding capacity and Kd is the drug concentration at 50% of Bmax

Question 63

Low Kd = ___ affinity

Answer 63

High affinity

Question 64

What are Emax and EC50?

Answer 64

Emax is maximal response and EC50 is concentration at 50% response i.e. EC50 is potency

Question 65

What is potency?

Answer 65

Measured by EC50, amount of response generated and depends on affinity and intrinsic efficacy (ability to activate receptor). Receptor number can change potency

Question 66

If Kd for salbutamol is 20uM for B1 and 1uM for B2, what does this mean?

Answer 66

A bit more selective for B2 than B1 (because B2 Kd is lower = higher affinity)

Question 67

Potency = ___ + ____

Answer 67

affinity + efficacy

Question 68

Why do we have spare Rs?

Answer 68

Amplify signal transduction 
Increase sensitivity (allow responses at low concs of agonist)

Question 69

What’s the point in partial agonists?

Answer 69

Can function as antagonists in presence of full agonist, can allow a more controlled response, can work in the absence/low presence of ligand

Question 70

What is IC50?

Answer 70

Concentration of antagonist giving 50% inhibition

Question 71

Define pharmacodynamics and kinetics

Answer 71

PD- what the drug does to the body

PK- what the body does to drug

Question 72

What are enteral and parenteral drug routes?

Answer 72

Enteral is via GI (sublingual, rectal, oral)

Parenteral is via anything else (SC,IM,IT,IV)

Question 73

What are SLCs and what types are there?

Answer 73

SoLute Carriers for charged molecules across GI epithelium for drug absorption. Types are OATs or OCTs. Transport either by facilitated diffusion or secondary active transport

Question 74

Give factors affecting each of ADME

Answer 74

Absorption: drug lipophilicity, pKa, density of SLC expression, blood flow, GI motility,
Distribution: if lipophilic will cross barriers, albumin binding
Metabolism: in Liver Phase I by CYP450 and Phase II by hepatic enzymes, induction or inhibition of CYP450 by other drugs and genetic variation
Elimination: renal function

Question 75

Which drugs can passively diffuse across GI?

Answer 75

Lipophilic, weak acids and bases

Question 76

Describe the route drugs are absorbed through once in gut

Answer 76

Gut –> hepatic portal vein –> liver –> body (or enterohepatic circulation meaning back to gut via bile duct)

Question 77

Bioavailability =

Answer 77

fraction of a defined dose that reaches a specific body compartment

Question 78

What is Vd?

Answer 78

Fluid volume needed to contain drug at the same concentration as in the plasma
Bigger d gives more penetration of the V

Question 79

Higher Vd=

Answer 79

More penetration of interstitial/intracellular fluid compartment
Bigger d = more penetration of V

Question 80

What is first pass metabolism?

Answer 80

Metabolism occuring before the drug reaches the systemic circulation i.e. first pass metabolism by GI/liver

Question 81

Phase I and II liver enzymes increase/decrease ionic charge or drugs and why?

Answer 81

Increase ionic charge to enhance renal elimination

Question 82

Give an example of a CYP genetic polymorphism?

Answer 82

CYP2DR for codeine

Question 83

What routes of elimination are there?

Answer 83

Renal is main, also lung, bile, breast milk, sweat, tears, saliva, genital secretions

Question 84

What will carry charged molecules across the PCT for renal excretion?

Answer 84

OATs and OCTs (helped by previous phase I and II metabolism that increased charge)

Question 85

What is clearance?

Answer 85

Rate of elimination of a drug from the body, made up of hepatic clearance (i.e. metabolism) and renal clearance (excretion)

Question 86

What are linear kinetics?

Answer 86

Rate of clearance is proportional to drug concentration (i.e. plenty of transporters etc). Will be linear on a log scale but curvy on a concentration scale

Question 87

What are zero order kinetics?

Answer 87

Rate of clearance reaches a limit of capacity- I have zero tolerance for this! Hyperbolic on a log scale but linear on a concentration scale

Question 88

Which type of kinetics is more likely to result in toxicity?

Answer 88

Zero order

Question 89

Most sympathetic post-ganglionic neurones are…

Answer 89

noradrenergic

Question 90

Muscarinic ACh Rs and all adrenoceptors are what type of R…?

Answer 90

GPCR

Question 91

What cells in the adrenal medulla innervated by the SNS secrete adrenaline?

Answer 91

Chromaffin cells

Question 92

Describe effects of parasympathetic ACh and the receptors involved

Answer 92

Bradycardia via M2 at SAN and AVN
Bronchoconstriction via M3 at lungs
Increased GI motility via M3
Increased sweat/saliva/lacrimal M1/M3

Question 93

Describe effects of sympathetic NA and receptors involved

Answer 93

Tachycardia via B1
Bronchodilation via B2
Vasoconstriction via a1
Pupillary dilation via a1

Question 94

What are catecholamines?

Answer 94

Adrenaline and NA

Question 95

Side effects of cholinergics i.e. increased parasympathetic activity?

Answer 95

Bradycardia, bronchoconstriction

SLUDGE: salivation, lacrimation, urination. defecation, GI upset, emesis

Question 96

Which enzymes within the presynaptic terminal metabolise NA?

Answer 96

MAO and COMT

Question 97

How many people in each stage of drug development?

Answer 97

Phase 1- 50 healthy volunteers for pharmacokinetics and safety
Phase 2- 200-400 people with target disease for pharmacology
IIa is pilot study for dose finding
IIb measures therapeutic action
Phase 3- 1000-3000 target population longer term safety data, efficacy compared with current treatment, large scale RCT

Question 98

What might happen after lead identification?

Answer 98

Lead optimisation e.g. increase potency, optimise selectivity, optimise PKs,

Question 99

When are proof of concept and proof of principle established?

Answer 99

Proof of concept is Phase I/IIa

Proof of principle is Phase IIb/III

Question 100

Four ethical principles

Answer 100

Justice, autonomy, beneficience, non-maleficience

Question 101

Describe what happens in CICR

Answer 101

Ca enters myocyte via L-type Ca channels, VOCC and/or LGIC then this Ca influx stimulates ryanodine Rs on the SR so that Ca is then released from the SR

Question 102

What is a Store Operated Channel? (SOC)

Answer 102

Pumps Ca directly into SER when low

Question 103

How does a GPCR relate to calcium release from SER/SR?

Answer 103

Gq so activates PLC which activates IP3 and DAG, IP3 binds to IP3R on SR/SER to release Ca

Question 104

What is different about calcium channels in skeletal muscle?

Answer 104

T tubule VOCCs are physically coupled to ryanodine Rs

Question 105

After muscle contraction how is resting Ca regained?

Answer 105

SERCA moves Ca back into stores

Question 106

What buffers excessive Ca in a cell?

Answer 106

Mitochondria

Question 107

Name the 3 calcium buffers in the cytosol, SR, and SER

Answer 107

Cytosol- calbindin
SR- calreticulin
SER- calsequestrin

Question 108

What does calmodulin do?

Answer 108

Acts a calcium sensor protein. Binds 4 Ca, changes conformation, binds PMCA and increases PMCA sensitivity to Ca x10

Question 109

Describe normal compartment fluid volumes

Answer 109

70kg human is 60% water so 42kg. 2/3 intracellular (28k) and 1/3 extracellular (14). Of the 14L, 9L is interstitial and 5L is circulating blood volume, 3L of which is plasma and 2L is RBCs.

Question 110

How does fibre diameter affect conduction velocity?

Answer 110

Bigger diameter = faster conduction
(A fibres fastest and biggest, B fibres middle, C fibres slowest and smallest). Note A and B are myelinated, C unmyelinated

Question 111

Roughly what value is the internodal distance (between nodes of ranvier)

Answer 111

100 x external diameter of fibre

Question 112

What cells form the myelin sheath in the CNS and PNS?

Answer 112

CNS: oligodendrocytes
PNS: Schwann cells

Question 113

When does myelination occur in development?

Answer 113

Third trimester and first two ish years of life

Question 114

How does adrenaline increase inotropy?

Answer 114

Binds to Gas, cAMP and then PKA activated, PKA activates VOCC channels to increase intracellular calcium

Question 115

Equation for oral bioavailability?

Answer 115

F = AUCoral / AUCiV

Question 116

Bioavailability =

Answer 116

amount reaching systemic circulation / amount administered

Question 117

Anticholinergic side effects

Answer 117

Constipation, dry mouth, urinary retention

Question 118

What’s thyrotoxicosis? + signs/symptoms

Answer 118

Excess thyroid hormones

Tachycardia, diarrhoea, weight loss, heat intolerance, sweating, amennorhea, palmar erythema

Question 119

Name a treatment for hyperthyroidism

Answer 119

Carbimazole- inhibits thyroid peroxidase from iodinating tyrosine residues on thyroglobulin so prevents production of T3 and T4