M&R

Question 0

Where are alpha1 adrenoreceptors found and what is their function there?

Answer 0

Liver - glycogenolysis
Pupil - increase dilation
Bladder - increase sphincter contraction = bladder relaxes
Vascular smooth muscle - vasoconstriction
Skeletal muscle - glycogenolysis and arterial dilation

Question 1

Where are adrenoreceptors found?

Answer 1

On effectors stimulated by the sympathetic nervous system

Question 2

Where are alpha 2 adrenoreceptors found and what is their function there?

Answer 2

GIT - decrease peristalsis and gut secretion.

- constrict sphincters

Question 3

Where are beta 1 adrenoreceptors found and what is their function there?

Answer 3

SAN - increase HR
Ventricle - increase force of contraction
Adipose tissue - lipolysis (along with beta3)

Question 4

Where are beta 2 adrenoreceptors found and what is their function there?

Answer 4

Lungs bronchi - vasodilation
Vascular smooth muscle - vasoconstriction
Liver - glycogenolysis
Skeletal muscle - glycogenolysis
Bladder - relaxation
Ventricle - increase force of contraction
GIT - decrease peristalsis

Question 5

How does GalphaQ G protein work?

Answer 5

It activates phospholipase C.
This converts PIP2 —-> IP3 + DAG
IP3 acts upon IP3 receptors in the SR to open Ca2+ channels
= Ca2+ influx

Question 6

What is the action of GalphaS G protein?

Answer 6

Activates adenylate cyclase
Increases cAMP levels
This activates:
Protein kinase A = phosphorylations (beta1 and 2)
HCN channels (beta1)
Certain K+ channel for relaxation (beta2)

Question 7

How does GalphaI G protein usually work?

Answer 7

It acts to inhibit adenylate cyclase
Decreases cAMP levels
Less activation of protein kinase A
Less phosphorylation

Question 8

What adrenoreceptors does adrenaline have the highest affinity for?

Answer 8

Beta2
Then alpha 1
But still acts upon all

Question 9

What drug can be used as an alpha1 agonist?

Answer 9

Oxymetazoline (nasal decongestant)

- vasoconstriction of nasal vessels = less inflammation and mucus production

Question 10

What drug can be used as an alpha 2 agonist?

Answer 10

Adrenaline = prolongs action of local anaesthetic

- vasoconstriction limits its diffusion/absorption and bleeding in surgery

Question 11

What drug can be given as an alpha adrenoreceptor antagonist?

Answer 11

Terazosin

- decrease high BP by blocking vasoconstriction

Question 12

What drug can be given as a beta1 agonist?

Answer 12

Dobutamine - used in cardio genic shock to increase HR

Question 13

What drug can be given as a beta1 antagonist?

Answer 13

Atenolol - acts to slow heart rate, therefore reducing hearts need for O2 (angina) and decreasing BP

Question 14

What drug can be given as a beta2 agonist?

Answer 14

Salbutamol - decrease bronchoconstriction in asthmatics

Question 15

What can be given as a beta adrenoreceptor antagonist?

Answer 15

Propanolol

Acts the same as atenolol in slowing HR, but is less selective, so a danger to asthmatics

Question 16

Where are muscarinic1 receptors found and what is their function?

Answer 16

Bladder - increase contraction

Exocrine glands - increase secretion

Question 17

Where are muscarinic 2 receptors found and what is their function?

Answer 17

SAN - decrease HR
Presynaptic neurone of post synaptic ganglion at neuromuscular junction - autoregulation
Bronchi - constriction

Question 18

What is auto regulation at muscarinic 2 receptors?

Answer 18

Where if he amount of ACh builds up, it will act upon M2 and M4 receptors on the presynapse membrane and inhibit ACh release. This prevents desensitisation.

Question 19

Where are muscarinic 3 receptors found and what is their function?

Answer 19

Bronchi - constriction
Bladder - constriction
Pupils - dilation
GIT - increase peristalsis and gut secretions
       - relax sphincters 
Liver - increase glycogenesis
Glands in general - increase secretion

Question 20

What are the muscarinic and adrenoreceptors which seem to have the greatest effect?

Answer 20

Alpha 1
Beta 2
Muscarinic 3

Question 21

What receptors are present and most active on the heart?

Answer 21

Beta 1

Muscarinic 2

Question 22

Name a drug specific to action on an M3 receptor and its action.

Answer 22

Carbachol/pilocarpine - acts to dilate the pupil which increases the angle of the eye via contraction of the sphincter pupillae = decrease in intraocular pressure to help glaucoma etc.

Question 23

What is atropine?

Answer 23

An antagonist of muscarinic ACh receptors that is often used to prevent spasms in the gut.

Question 24

What is bethanechol?

Answer 24

An agonist of muscarinic receptors, which can be used to treat urinary retention, often due to previous surgery.

Question 25

What role does NCX have in cell injury due to ischaemia?

Answer 25

Ischaemia = no ATP = no Na+/K+ ATPase
This means Na+ builds up intracellularly.
This causes greater Na+ gradient in the cell so NCX reverses as it is electrogenic (dependant on Na+ gradient)
Brings calcium into the cell which is toxic.

Question 26

What pumps are used to control cellular pH?

Answer 26

Acid extruders

• NHE (Na+ in, H+ out)
• Na+ dependent HCO3-/Cl- exchanger (Na+ and HCO3- in, H+ and Cl- out)

Base extruders
- AE (HCO3- out, Cl- in)

Question 27

How is the action of NHE stimulated or inhibited?

Answer 27

Inhibited by the drug amiloride

Activated by growth factors as growth factors mean more metab is occurring and therefore more H+ is being produced.

Question 28

What are the methods of controlling cell volume via pumps and channels?

Answer 28

1). Conductive systems
- allow K+ down its conc gradient
= shrink
- allow Na+ or Ca2+ in
= swell

(Cl- will follow to maintain electroneutrality)

2). pH related
- AE = HCO3- in, and K+/H+ exchanger brings H+ in = H2CO3 which can then form H2O and CO2 and leave
= shrink
- this reverses
= swell

3). Cotransport systems
- efflux of free amino acids or K+/Cl- symporter out
= shrink
- Na+/K+/2Cl- symport in, Na+/Cl- symport in
= swell

Question 29

What are the ion conc’s in and outside the cell?

Answer 29

Na+ 145 out, 10 in
Cl- 122 out, 4 in
K+ 155 in, 4 out
Ca2+ 10-7 in, 1.5mM out

Question 30

What are the 3 ways of raising Ca2+ levels?

Answer 30

1) . Across the plasma membrane
2) . Rapidly releasable stores
3) . Non rapidly releasable stores

Question 31

How can Ca2+ levels be raised across the plasma membrane?

Answer 31

V-gated Ca2+ channels

Ligand gated Ca2+ channels

Question 32

How do rapidly releasable stores increase Ca2+ levels?

Answer 32

1). Ligand binds to GPCR
= GalphaQ acts on phospholipase C = IP3 reacts on IP3 receptors to open SR

2). Calcium induced calcium release
= Ca2+ acts on ryanodine receptors or in skeletal muscle, Ca2+ channels shape change is transduced onto ryanodine receptors = Ca2+ influx

Question 33

How do non rapidly releasable Ca2+ stores work?

Answer 33

The mitochondria take up Ca2+ when it is very high in microdomains close by via Ca2+ ATPase.

Can release into these microdomains by store operated Ca2+ channels opening.

Question 34

What is the evidence for involvement of mitochondria in non rapidly releasable stores?

Answer 34

1) . They buffer Ca2+ which allows mitochondria to regulate the pattern and extent of signalling.
2) . Role in apoptosis which is reliant on Ca2+
3) . Mitochondrial metabolism is activated by Ca2+, as high Ca2+ means more ATP is required for its removal, meaning more metabolism occurs.

Question 35

Name 2 Ca2+ buffers and their function.

Answer 35

Calsequestrin
Calbindin

Bind to Ca2+ and prevent its diffusion

Question 36

What are the 3 steps to restoring regular Ca2+ levels?

Answer 36

1) . Stop Ca2+ influx signals
2) . Remove Ca2+
3) . Refill Ca2+ stores

Question 37

How are Ca2+ stores refilled?

Answer 37

SERCA - pump Ca2+ into SR using ATP

This is stimulated via depleted store signals which open STIM (and ER membrane protein with a Ca2+ sensor that changes shape in low Ca2+)

This then interacts with ORAI, a plasma membrane Ca2+ channel, activating it to allow Ca2+ influx into the cell.

Question 38

How do drugs exert their effect?

Answer 38

By binding to a target e.g.
DNA
Enzymes
Ion channels
Transporters
GPCRs

Question 39

What is the action of drug determined by?

Answer 39

The conc of drug molecules surrounding the receptor

Question 40

Why do we use molarity to calculate drug concentrations rather than simply mg/L?

Answer 40

mg/L is simply the conc of the weight of drug added to the volume.

By working out conc in molarity (dividing above by molecular weight) we can then multiply this by Avogadro’s number to obtain the number of drug molecules in the solution.

= weight conc of drugs may be same but molecules differ.

Question 41

What is a ligand?

Answer 41

A molecule that binds specifically to a receptor.

Question 42

What is drug action based on?

Answer 42

1) . Affinity - the degree to which the ligand binds to the receptor
2) . Intrinsic efficacy - the ability of the ligand to activate the receptor
3) . Efficacy - the ability of the activated receptor to form a response

Question 43

What is an agonist?

Answer 43

A ligand which binds to cause a response. Has both affinity and intrinsic efficacy.

Question 44

What is an antagonist?

Answer 44

A ligand which binds to a receptor without causing a response, therefore blocking the action of agonists. Has affinity but no intrinsic efficacy.

Question 45

What is Kd and what does it give us?

Answer 45

The dissociation constant (a measure of affinity)

The conc of ligand required to occupy 50% of receptors.

Question 46

How is Kd calculated?

Answer 46

Addition of an increasing amount of radioactive ligand to the cell, and then calculating the proportion of receptors bound.
This is then plotted.

Question 47

What is EC50?

Answer 47

The conc of ligand required to gain a 50% of max response

Therefore is a measure of potency.

Question 48

What is potency?

Answer 48

A measure of how well a drug works.

Question 49

What is potency dependant on?

Answer 49

Affinity - how well it binds
Intrinsic efficacy - how well it activates the target receptor
No. of receptors - how many need to be occupied to formulate a response

Question 50

Why may a cell have “spare receptors” and what is the effect this has?

Answer 50

In some cells, less than 100% of receptors are needed for a response because of amplification reactions, or a post receptor event which limits the response.

More spare receptors = increased sensitivity

Question 51

What type of cells tend to have spare receptors?

Answer 51

Those with catalytic ally active receptors (GPCRs, enzyme linked etc)

Question 52

How can receptor number change and what may this cause?

Answer 52

Up or down regulation

Tolerance
Tachyphalaxis (decreased reaction to a drug)

Question 53

What is the difference between concentration and doseage?

Answer 53

Conc - drug conc at site of action is known (cell/tissue)

Doseage - drug conc at site of action is unknown (body system)

Question 54

What is a partial agonist and what is this due to?

Answer 54

One where a full response is not stimulated, despite 100% of receptors being full.

Poor efficacy (good affinity, so the ability of the receptor to cause a response or of the ligand to activate the receptor is poor)

Question 55

What are the EC50 and Kd values in a partial agonist like?

Answer 55

They are equal

Question 56

How may a partial agonist become a full agonist?

Answer 56

Via upregulation of receptors -
intrinsic efficacy is still the same there are now a greater number of receptors to allow us to stimulate a full response.

Question 57

What occurs if a partial agonist has a greater affinity for a receptor than a full agonist?

Answer 57

It will antagonise the full agonist.

Question 58

What are the EC50 and Kd values of a full agonist like?

Answer 58

Kd is greater than EC50

Question 59

What is IC50?

Answer 59

The inhibitor concentration (antagonist) at 50% response

Question 60

What is Kd and Kb in terms of antagonists?

Answer 60

Kd is still the conc of radio labelled drug to take up 50% receptors.

Kb is the same but pharmacologically - the conc of antagonist

Question 61

What are the 3 types of antagonism and what occurs in each?

Answer 61

1) . Reversible competitive
- antagonist binds at same site as agonist and therefore blocks it.

2) . Irreversible competitive
- antagonist binds at same site but dissociates very slowly or not at all

3) . Non competitive inhibition
- antagonist binds at allosteric site, affecting the orthosteric site of the ligand, or efficacy of this site (primary binding site of ligand) = agonist has no/reduced effect

Question 62

Where may reversible competitive antagonism be used clinically?

Answer 62

Drugs such as naloxolene have a higher affinity at u-opioid receptors than other opioids = bind and prevent opioids stimulating = less resp depression in OD

Question 63

How may irreversible competitive antagonism be useful clinically?

Answer 63

To block alpha1 receptors in disorders which secrete adrenaline = less highBP

Question 64

How may non competitive antagonism be useful clinically?

Answer 64

Ketamine can be used for analgesia as it binds to allosteric site of an ion channel, blocking glutamate = no excitation

Question 65

How may a high affinity partial agonist be used clinically?

Answer 65

Can be given to wean from drugs such as heroin
- binds to receptors as affinity is higher but has less efficacy, so still gives partial response, but lessens risk of respiratory depression etc.

Question 66

Why does salbutamol have little effect on HR?

Answer 66

It has a higher Kd for beta2 receptors than beta1.

Given IV as salmeterol (has higher affinity for beta2 so is better) isn’t always used as it is insoluble = can’t be given IV