The phototransduction pathway. Lecture 8

Question 1

What is phototransduction?

Answer 1

The process of a cell absorbing light and creating a response

Question 2

What is the response generated by phototransduction?

Answer 2

This response is a change in the amount of neurotransmitter released to its target neuron.

Question 3

What is the first step of the phototransduction pathway?

Answer 3

Light interacts with the visual pigment of the photoreceptor. Which is found in the outer segment of the photoreceptors.

Question 4

What does this lecture go over with regards to the phototransduction pathway?

Answer 4

1. How light is transduced and results in hyperpolarisation.
2. How this hyper polarisation event also results in low Ca that leads to deactivation of the cascade.
3. The various possible ways of deactivating the cascade.

Question 5

What sort of pathway is the phototransduction pathway?

Answer 5

A molecular transduction cascade

signalling cascades

Question 6

What does phototransduction result in?

light on photoreceptors

Answer 6

Closure of the Na/Ca channels in the membrane and hyperpolarisation of the membrane.

Question 7

Do phototransduction result in the generation of an action potential?

Answer 7

No action potential is generated by phototransduction regardless of light or dark conditions… however neurotransmitter release can be varied from basal level.

Question 8

What are the components of the phototransduction pathway in rods?

Answer 8

1. Visual pigment = Rhodopsin (transmembrane protein) CIS-retinal sits in a binding pocket of rhodopsin. (specific form of retinal)
2. Transducin (intracellular membrane bound protein)
3. Phosphodiesterase (PDE)

Question 9

What comprises the transducin protein?

Answer 9

alpha, beta and gamma subunits.

In the INACTIVE state G-alpha subunit has GDP bound in its binding site.

Transducin is a G-protein.

Question 10

What is the activity of the transducin protein?

Answer 10

It has GTPase activity.

Question 11

Whats the function of PDE?

Answer 11

Breaks down cGMP to GMP by the PDE enzyme.

Question 12

Whats the first reaction of the phototransudction pathway?

in light

Answer 12

In the presence of light:

1. Light exposure causes the isomerisation of the CIS-retinal into trans-retinal (causing it to leave the rhodopsin (opsin) protein binding pocket.
2. This causes a conformational change of rhodopsin into metarhodopsin2 or Rho* (activated form)
3. Rho* binds transducin
4. Transducin dissociates from its GDP and binds GTP

Question 13

Describe the second phototransduction reaction:

In light

Answer 13

1. GTP causes Gα transducin to dissociate from βγ subunit
2. Gα binds to PDE γ
3. 2 transducin molecules are required to release inhibitory constraint imposed by PDE γ (activating it)
4. PDE hydrolyses cGMP to GMP

Question 14

Whats the third (final) phototransduction step?

IN light

Answer 14

1. The level of cGMP has been reduced by PDE.
2. low cGMP means that there is insufficient to bind to cGMP gated Na channels therefore there is decreased Na/Ca influx

(lowered Ca levels, means less glutamate release as no Ca to bind to the vesicles and cause vesicle glutamate release.) i.e synaptic transmission.

Question 15

IN short what is the phototransduction mechanism of rods?

in light

Answer 15

1. LIGHT Activated opsin interacts with
   transducin.
2. (2) Transducin (Tα-GTP) interact with PDE.
3. Causes hydrolysis of cGMP.
4. Low levels of cGMP cause closure of Na+ and Ca2+ channels.

Question 16

What happens to photoreceptors in the dark at a chemical level that results in increased glutamate release?

Answer 16

In the dark:

1. Activation of guanylate cyclase (GC)
2. Catalyses the formation of GTP to cGMP 3. Increase in cGMP
3. Opening of Na+/Ca2+ cGMP gated channels

Question 17

Describe the location of steps in phototransduction:

Answer 17

Steps 1-2 occur in the outer segments optic discs, thus changing cGMP levels.

The step 3 i.e. effects of cGMP change in concentration occurs at the membrane.

Question 18

Describe signal amplification of photoreceptors.

Answer 18

One light activated rhodopsin protein can activate 800 transducin molecules. (RHODOPSIN IS VERY LIGHT SENSITIVE PIGMENT) i.e one photon activates it.

Two transducin molecules are required to activate one PDE

Each PDE can break down 6cGMP

A PDE molecule can break down 800cGMP per second.

Question 19

How important is the deactivation of the phototransduction cascade?

Answer 19

Equally important to activation of signaling is switching the signal off and limiting the duration of this amplifying cascade and restoring molecules to their inactivated state.

Question 20

What signals for the deactivation of the phototransduction cascade?

Answer 20

During the phototransduction cascade i.e light hitting the photoreceptor, Ca is extruded from the outer segment of a photoreceptor and sufficiently low Ca concentration acts as a signalling event partially responsible for the deactivation of the phototransduction cascade.

Question 21

What exchanger is primarily involved in Ca extrusion from the photoreceptor, during the phototransduction cascade.?

Answer 21

Na/ Ca+K exchanger

i.e 4 Na + in for One Ca and One K out.

Question 22

Why is Ca so important?

Answer 22

Ca2+ plays a key role in light induced modulation of photoreceptor sensitivity i.e it is partially responsible for phototransduction deactivation.

Low Ca = deactivation!

Ca is a primary deactivation switch

Question 23

What happens to Ca concentrations when light is hitting the photoreceptor and their is phototransduction?

Answer 23

Decrease in intracellular Ca2+ due to closing of Ca2+ channels (no cGMP) and extrusion of Ca2+ by the Na+/Ca2+-K+exchanger.

Question 24

What are the three mechanisms that are activated by low Ca?

Answer 24

Three

1. increases the activity of guanylate cyclase
2. increases the activity of rhodopsin kinase
3. increases the affinity of cGMP gated channels for cGMP

Question 25

What is the effect of increasing guanylate cyclase activity?

Answer 25

1. increases the activity of guanylate cyclase (i.e. increase in cGMP)
   I. stimulates guanylate cyclase activating proteins (GCAPs).
   II. leads to activation of guanylate cyclase and synthesis of cGMP from GTP, leading to a recovery of the cGMP concentration.

cGMP activates cGMP gated cation channel i.e. Ca influxes.

Question 26

What are the effects of increasing rhodopsin kinase activity?

Answer 26

2. increases the activity of rhodopsin kinase
   i. causes phosphorylation of Rho*
   ii. decreases affinity for binding to transducin

Question 27

How is an increase of cGMP gated ion channels for cGMP achieved?

Answer 27

3. increases the affinity of cGMP gated channels for cGMP
   i. a decrease in intracellular Ca2+ concentration leads to the dissociation of Ca2+ from calmodulin (which binds to closed cGMP channels)
   ii. this in turn results in dissociation of calmodulin from the cGMP-gated channel, which results in an increase in affinity of the cGMP-gated channel for cGMP

Question 28

What is the first pathway that is deactivated?

Answer 28

Inactivation of rhodopsin and transducin

Question 29

How are rhodopsin and transducin deactivated and what are the effects of this?

Answer 29

• Activated rhopdopsin is phosphorylated by rhodopsin kinase
• Arrestin binds to (phosphrylated) rhodopsin
• Decreases affinity for binding to transducin
• Transducin is no longer activated

Question 30

What is the second pathway that could deactivate it?

Answer 30

Dissociation of all trans retinal from rhodopsin

Question 31

How is trans-retinal dissociated from rhodopsin and what are the effects of this?

Answer 31

• All-trans retinal is reduced to all trans retinol in the photoreceptor cells
• All-trans retinol is transported to the pigment epithelial cells (RPE)
• 11 cis retinal is regenerated in three enzymatic steps
• 11-cis retinal is then transported back to the rods.

This is the visual cycle.

Question 32

What is the visual cycle?

Answer 32

The regeneration of CIS retinal.

Question 33

Why is rhodopsin kinase normally not in function?

Answer 33

Normally rhodopsin kinase is bound to recoverin and during low Ca levels recoverin dissociates and rhodopsin is activated.

Question 34

What is retinal derrived from?

Answer 34

Vitamin A in the diet.

Question 35

Describe visual pigment composition:

Answer 35

1. Found in optic discs of outer segment.
2. Opsins are g-protein coupled receptors.
3. 7 transmembrane domains
4. retinal binding pocket.

Question 36

How does the opsin create the binding pocket?

Answer 36

By a lysine residue that is a retinal binding site in the seventh helix.

Question 37

How many opsin are there?

Answer 37

Rods = rhodopsin
Cones = Red, Green, blue photo opsin

Question 38

What is the AA difference between green and red opsin?

Answer 38

15 AA difference which changes the sensitivity of photopigment to light.

Question 39

Describe human vision:

Answer 39

Trichromatic

Question 40

Whats it called when someone only has two cone receptors are working?

Answer 40

Dichromatic.

Sex linked, mainly males.

Question 41

What does a lack of vitamin A lead to?

Answer 41

Complete lack of vision due to lack of retinal.

Question 42

What does an opsin mutation lead to?

Answer 42

Colour blindness

Question 43

What are the types of colour blindness?

Answer 43

Dichromacy (2 colours)
Monochromacy
Anomalous trichromacy

Question 44

What is anomalous trichomromacy?

Answer 44

Normal colour vision with slight out of alignment perception of colour

Question 45

What are the types of dichromacy?

Answer 45

Protanopia
Deuteranopia
Tritanopia

Question 46

What is propantopia?

Answer 46

1. patients do not have the red cone cells in the retina
2. most common type of dichromacy
3. red-green color blindness
4. impairment in perception of very long wavelengths, such as reds.

Question 47

What is Deuteranopia?

Answer 47

1. patients do not have green cone cells in the retina

2. is an impairment in perceiving medium wavelengths, such as greens.

Question 48

What is tritanopia?

Answer 48

1. Patients do not have the blue cone cells in the retina
2. A rarer form of colour blindness
3. An inability to perceive short wavelengths, such as blues.
4. They tend to confuse greens and blues, and yellow can appear pink.

Question 49

What causes vision difficienies?

Answer 49

Normally a change in an AA in the opsin protein leads to deficiencies

Question 50

What is retinitis pigmentosa?

Answer 50

A change in an amino acid that causes failure of rhodopsin leading to tunnel vision as peripheral rods are lost.