Reprogramming

Question 1

What happens to axons when they reach intermediate targets?

Answer 1

They reprogramme

Question 2

What happens to the neurons in the hindbrain when they cross the floor plate?

How is this different to in the spinal cord?

Answer 2

In the hindbrain: neurons continue straight on

In the spinal cord: neurons turn anteriorly

Question 3

What happens to pre-crossing neurons if they are exposed to an ectopic floor plate?

Answer 3

They are attracted to the ectopic floor plate

Question 4

What happens to post-crossing neurons if they are exposed to an ectopic floor plate?

Answer 4

They are not attracted to the ectopic floor plate

Question 5

What happens to neuron sensitivity when they cross the floor plate?

Answer 5

Sensitivity changes:

• No longer attracted to netrins in the floor plate
• Now sensitive to repellants in the floor plate

Question 6

How are semaphorins and slits expressed in the floor plate?

Answer 6

In 3 bands

Question 7

Why do spinal cord axons turn after crossing the floor plate?

Answer 7

Repelled by slits and semaphorins in the floor plate

Question 8

Why don’t the axons in the spinal cord go straight on once crossing the floor plate in the spinal cord? (like in the hindbrain)

Answer 8

Slits and semaphorins (repelllants in the floor plate) create a channel at which the axons grow

Question 9

What is expressed in INSECT midline glial cells?

Answer 9

• Diffusible attractants (netrins)

- Cell surface repellants (slits)

Question 10

What occurs in the roundabout mutant? (NO ROBO)

Answer 10

Neurons lose sensitivity to repellants in the midline:

- Axons cross the midline many times

Question 11

What occurs in the commissurless mutant? (NO COMM)

Answer 11

Neurons are permanently sensitive to repellants in the midline:
- Axons don’t cross the midline

Question 12

What happens when FORCE expression of comm?

What does this show?

Answer 12

Looks like robo mutant (no robo) - no longer sensitive to midline repellants

Shows that comm controls robo

Question 13

Do all axons cross the midline?

Answer 13

NO some axons cross to form commissures that join with longitudinal pathways formed by axons that have not crossed the midline

Question 14

What determines whether or not axons can cross the midline?

Answer 14

Levels of SLIT receptors at the cell surface

Question 15

What type of molecule is comm?

Where is it found?

Answer 15

A membrane-associated protein

Found at the cell surface and on intracellular components

Question 16

How does comm control robo?

Answer 16

Controls the intracellular trafficking of robo to the cell surface

Question 17

What is Robo?

Answer 17

A receptor for the inhibitory protein SLIT

Question 18

Where is robo expression high/low?

Answer 18

High on neurons that DON’T cross (repelled by the midline)

High on C neurons AFTER they have crossed (prevent crossing again)

Low on C neurons BEFORE crossing (so they can be attracted to the midline)

Question 19

Why do the axons continuously cross the midline in robo mutants?

Answer 19

No robo, no slit detected, not repelled from the midline

Can constantly be attracted to the midline by netrins

Question 20

Which 2 places is comm expressed?

Answer 20

1) In the MIDLINE

2) In neurons that normally cross the midline

Question 21

Why do the axons not cross the midline in comm mutants?

Answer 21

Robo upregulated, higher sensitivity to slits, extend axons longitudinally

Question 22

What are the 2 possible models of how Comm controls Robo?

Answer 22

1) Sorting model

2) Clearance model

Question 23

Describe the sorting model of how comm controls robo

Answer 23

Presence of Comm forces the sorting of newly synthesised Robo into late endosomes:

Pre-crossing/during crossing - Robo recycled and degraded

Post-crossing - Robo upregulated

In neurons that DON’T cross - no Comm, no robo degredation

Question 24

Describe the clearance model of how comm controls robo

Answer 24

• Robo goes down the axon with comm
• Robo gets to the surface but is CLEARED from the surface (during crossing)
• Following crossing, Robo is UPREGULATED

Question 25

How is robo cleared from the cell surface during the crossing of a commisural axon?

Answer 25

Due to the HOMOPHILLIC interactions between comm in the axon and comm in the midline

Question 26

In the clearance model, how is robo upregulated in post-crossing axons?

Answer 26

No longer homophillic interactions between comm in the axon and comm in the midline

Question 27

What predictions distinguish between the clearance and the sorting model?

Answer 27

1) Only the clearance model requires comm expression in the midline
2) In the clearance model, robo is sent down the axon before the axon crosses, but in the sorting model, robo stays in the cell body before the axon crosses

Question 28

Why is the clearance model an attractive model for how comm controls robo?

Answer 28

Suggests a mechanism for up regulation of robo in crossed axon segments

Question 29

What 2 things are used to test if the clearance model or the sorting model is correct?

Answer 29

1) Is comm required in the MIDLINE CELLS for correct crossing? (clearance models says should be)
2) Is robo PREVENTED from going to axons in the presence of comm? (sorting model says it should be)

Question 30

How to test if comm required in the MIDLINE CELLS for correct crossing?

Answer 30

Use neuron-specific promoter to drive axon marker in a subset of cells:

• Use promoter to drive comm expression IN THE NEURONS in a comm mutant background
• Comm is in the neurons but NOT the midline

–> rescues the phenotype, in favour of the SORTING model

Question 31

How to test if robo PREVENTED from going to axons in the presence of comm?

Answer 31

Use robo-GFP fusion protein in the fly:

Axon NOT expressing comm - robo moves down the axon

Axon expressing comm - robo remains in the CELL BODY

–> shows comm doesn’t ship robo down the axon, in favour of the SORTING model

Question 32

What model explains how comm controls robo?

What are the problems with this model?

Answer 32

Sorting model

Problems, don’t understand why:

1) Comm is expressed in the midline
2) What controls upregulation of robo on the contalateral side (after crossing the midline)

Question 33

What is the likely explanation of upregulation of robo after the midline?

Answer 33

Due to contact with the midline

Question 34

When is robo made in the axon?

What does this allow?

Answer 34

BEFORE axons cross

Allows robo to rapidly appear on the cell surface once the midline is crossed

Question 35

What type of molecules are TAG-1 and L1?

How are they expressed in commisural axons?

Answer 35

Cell adhesion molecules (on the cell surface) in MAMMALS

TAG-1:
High in axons pre-crossing, switched off post crossing

L1:
Up regulated in post-crossing axons

Question 36

What is the comm homologue in vertebrates?

Answer 36

There isn’t one, instead:

- Another Robo-like receptor is expressed in pre-crossing axons

Question 37

In vertebrates, what is the robo-like receptor expressed in pre-crossing axons?

Answer 37

Robo3/Rig1

- Also a receptor for slit

Question 38

What happens in mice if KO robo3?

Why is this surprising?

Answer 38

PREVENTS floorplate crossing (axons aren’t attracted to the FP)

Surprising because robo is a receptor slit, if KO - assume will cross the floor plate (less sensitive to slits)

Question 39

What are the 2 models of how Robo3 works?

Answer 39

1) Robo3 is a receptor for an ATTRACTANT not a repellant

2) Robo3 is an INHIBITOR of Robo

Question 40

What does model 1 of how Robo3 works suggest when KO robo3?

Answer 40

Neurons are prematurely sensitive to slit and are not attracted to the floorplate

Question 41

What happens in a mouse with Robo3KO AND blocked slit function?

What model is this consistent with?

Answer 41

Attraction to the floor plate is RESTORED

Consistent with model 2 (Robo3 is inhibitor of robo):
- NO inhibitor of Robo, robo can function and sense slits (doesn’t cross)

• BUT, no slits, robo cannot sense slits (axons cross)

Question 42

How is slit function blocked?

Answer 42

Adding Robo1 ectodomain (part of receptor outside of the cell that usually binds to slit):

• Binds to slits and stops slits binding to Robo in the neurons

Question 43

What experiments show that Robo3 function is to prevent premature slit sensitivity?

What does this show?

What is the control?

Answer 43

Take cells expressing slit in a bath with netrin:

• WT pre-crossing C axons IGNORE slits in presence of netrin (axons grow into netrin)
• Pre-crossing C axons LACKING Robo3 are REPELLED away from slit source (still grow into netrin, but away from slit)

Control: Not true for other inhibitory factors, only slit

Question 44

When can netrin override effect of slit?

Answer 44

In WT neurons

But ONLY when ROBO3 is present

Question 45

What prevents robo from functioning in the wrong part of the pathway?

Answer 45

Crosstalk between receptors

Question 46

What is the role of Robo3 and Comm?

Answer 46

Robo3 (in vertebrates) is ANALOGOUS to comm (in flies) (similar function, different protein):

• Prevents Robo from signalling BEFORE the midline…
• Allowing netrin to signal through its receptor

Question 47

What is the receptor of netrin?

Answer 47

Dcc

Question 48

How does Robo3 and Comm prevent robo signalling?

Answer 48

Robo3:
Robo GETS TO the surface but Robo3 prevents its signalling

Comm:
PREVENTS robo from getting to the surface

Question 49

How is the mechanism of how Robo3 works differnetly to comm?

Answer 49

• Doesn’t affect the trafficking, it blocks the receptor at the CELL SURFACE
• Loss of Robo3 doesn’t lead to the upregulation of robo on pre-crossing axons, instead, allows robo to signal

Question 50

What happens to the level of slits as the FP is encountered?

Answer 50

Levels of slit increase

Question 51

How is robo stabilised in the membrane?

What does this cause?

Answer 51

When slit binds to robo as slit concentration increases

Causes:
- Amplification of the robo expression

• When above certain threshold this slit-induced robo signalling OVERWHELMS robo3 inhibition
• Through feedback, this TURNS OFF robo3 expression
• -> Fully stabilising Robo and slit repulsion

Question 52

How do post-crossing axons respond to netrin in the presence of slit?

What does this show?

Answer 52

No longer respond to netrin (even though they do when slit is not present)

Shows that slits INHIBIT netrin

Question 53

What are the 2 proposed models that suggest how slit inhibits netrin?

Answer 53

1) Model 1: Ligand-ligand interaction
(Slit and netrin physically interact)

2) Model 2: receptor-mediated silencing
(Ligands BIND to the receptor but the EFFECT of SLIT binding to ROBO silences signalling from the netrin receptor DCC

Question 54

How can you test if it is ligand-ligand interaction or receptor-mediated silencing that blocks netrin signalling?

What were the results?

Answer 54

Create hybrid version of robo (intracellular domain - robo, extracellular domain Met) - test which part of the recpetor is important:

• If ligand-ligand interaction: extracellular should be important
• If receptor-mediated silencing: intracellular part should be important

Results:

• HGF ligand binds to HGF receptor extracellularly
• Turning response occurs
• Since HGF doesn’t do this normally, shows it is the intracellular domain of robo that is important (silencing is due to receptor interactions)

Question 55

What causes the silencing of netrin once the floor plate is crossed?

Answer 55

Interactions between the cytoplasmic domains of DCC and Robo

Question 56

As well as loss of sensitivity of the commisural axons for netrin when the floor plate is crossed, what else occurs?

Answer 56

Sensitivity to repellants (slits) increase

Question 57

What are the 2 possibilites of the ‘switch’ in sensitivities as cross the floor plate?

Which model does the evidence suggest?

Answer 57

1) Contact with the floor plate as the trigger
2) Changes over TIME

Evidence for BOTH possibilities

Question 58

What are the 2 contact/proximity with the floor plate triggering the switch idea?

Answer 58

1) As get CLOSER to the floor plate - increase in concentration of SLIT that binds to ROBO on the cell surface:
- Concentration too high for robo3 to inhibit
- Feedback (shutdown of robo3 when there is slit signalling through its receptor)

2) Something on the surface of the FP - when come into contact with it it flips the switch
- NrCAM

Question 59

What is NrCAM and where is it present?

What does it interact with? What does this acheive?

Answer 59

Cell adhesion molecule ONLY expressed in the FP

Interacts with TAG1 on commisural axons to STABILISE robo on the commisural axons –> leads to increased sensitivity to sema –> repulsion

Question 60

What does shh do in the floor plate?

Answer 60

Attracts neurons to the floor plate by binding to receptor and then SWITCHES to repulsion as C axons cross the floor plate, due to a cell INTRINSIC change in the C axons

Changes how axons respond to repellants, switches response to netrin

Repulsion of axons by shh makes the neurons turn LEFT to travel anteriorly

Question 61

What happens if KO shh in the floor plate?

Answer 61

Confused neurons crossing of the floor plate and turning defects

Question 62

What is 14-3-3?

What is it involved in?

Answer 62

Par-5 homolog which INHIBITS PKA and stops it from responding to [cAMP] which controls the polarity of response

Mediating the sensitivity switch

Question 63

What revereses the response of C axons to shh?

Answer 63

Cell intrinsic levels of 14-3-3:
- Increases as C neurons get close to the floor plate

• Change in expression causes C axons to be repelled by the floor plate (initially attracted)

(PKA is normally activated by smo, which is activated when shh binds)

(Inhibit PKA - stop responding to cAMP, which controls the attractant response to a cue)

Question 64

What makes post-crossing axons turn left and travel anteriorly

Answer 64

Repulsion by shh posteriorly

Attraction by wnt anteriorly (wnt4)