Building Brains 6 - Vertebrates

Question 1

Name the zone of the neural tube in the vertebrate embryo which lies closest to the lumen, and contains the proliferating epithelium. (1)

Answer 1

Ventricular zone

Question 2

In the DV axis of the vertebrate embryo spinal cord, distinct cell types arise from corresponding domains of proliferating epithelium.

How are these domains distinguished from one another? (1)

Answer 2

Expression of different transcription factors

Question 3

Name all of the progenitor domains in the DV axis of the vertebrate embryo spinal cord which give rise to specific neurones. (lots of marks)

Answer 3

dl1
dl2
dl3
dl4
dl5
dl6
V0
V1
V2
MN
V3

Question 4

Name the structures which lie…

a) most dorsal in the neural tube
b) most ventral in the neural tube

(2)

Answer 4

a) roof plate
b) floor plate

Question 5

True or false? (1)

The floor plate is an epithelial structure in the dorsal neural tube.

Answer 5

False - the floor plate is an epithelial structure in the VENTRAL neural tube

Question 6

Name the structure in the vertebrate embryo which induces development of the floor plate of the neural tube. (1)

Answer 6

Notochord

Question 7

True or false? (1)

In the neural tube of the vertebrate embryo, the notochord and floor plate induce the formation of ventral structures, such as sensory neurones.

Answer 7

False - change sensory neurones to motor neurones

Question 8

Briefly describe an experiment where the sufficiency of the notochord to induce ventral fates in the vertebrate embryo neural tube could be tested.
Describe the expected results. (3)

Answer 8

• Transplant an extra notochord in different area
• Should see extra ventral structures

eg. floor plate and motor neurone pools

Question 9

Briefly describe an experiment where the necessity of the notochord to induce ventral fates in the vertebrate embryo neural tube could be tested.
Describe the expected results. (3)

Answer 9

• Ablation of notochord
• Would lead to loss of floor plate and motor neurones
• Also, dorsal markers would extend ventrally

Question 10

Name the molecule in the vertebrate embryo which patterns the ventral part of the neural tube. (1)

Answer 10

Sonic hedgehog

Question 11

True or false? (1)

In the vertebrate embryo, sonic hedgehog is a morphogen and a transcription factor.

Answer 11

False - it is a morphogen, but is a secreted peptide, not a transcription factor

Question 12

Describe the Shh signalling pathway. (3)

Answer 12

• Shh binds to patched
• Patched activated smoothened
• Smoothened allows GLI to acts as a transcriptional activator instead of a transcriptional repressor

Question 13

Which structure/s in the vertebrate embryo express/es Shh protein?

Answer 13

Notochord and floor plate

Question 14

Shh affects homeodomain proteins (TFs) in the vertebrate embryo neural tube, in order to create distinct domains.

There are two classes of homeodomain proteins which respond differently to Shh.

Name these two classes and state how they respond to Shh. (4)

Answer 14

Class I proteins repressed by Shh

Class II proteins activated by Shh

Question 15

True or false? (1)

All class I proteins in the vertebrate embryo neural tube are repressed equally by Shh, and all class II proteins are activated equally.

Answer 15

False - proteins show varying strengths of response to Shh to create variable expression in the DV axis

Question 16

True or false? (1)

In the DV axis of the vertebrate embryo neural tube, each ventral domain expresses a unique transcription factor (under the control of Shh) to distinguish it from other domains.

Answer 16

False - different combinations of transcription factors are expressed in each domain

Question 17

In the vertebrate embryo neural tube DV axis, class I transcription factors and class II transcription factors (controlled by Shh) sometimes share a boundary between different domains.

How do these TFs ensure that the boundary is sharp? (1)

Answer 17

Mutual inhibition

Question 18

Describe an experiment that could be carried out to test the mutual inhibition of class I and class II transcription factors in the vertebrate embryo ventral neural tube. (2)

Answer 18

• Overexpress one TF
• Use colocalisation to see if these TFs are able to be expressed together or if they are inhibited

Question 19

Describe how in ovo electroporation can be used to force a chick embryo to overexpress certain transcription factors. (4)

Answer 19

• Cells pulsed with electric current
• This forces them to take up molecules (eg. DNA/RNA) which have been injected into the organism
• Molecule will move to area of electric current to which they are attracted (eg. -ve charged molecule moves towards positive current)
• Can cause over/under/mis-expression of specific genes

Question 20

Describe what you would expect to happen if vertebrate embryo neural tube cells which are from the dorsal region are cultured which Shh? (1)

Answer 20

They will take on a ventral fate

Question 21

Name the class I transcription factors which are inhibited by Shh in the ventral part of the vertebrate embryo neural tube. (5)

Answer 21

Pax7

Pax6

Dbx1

Dbx2

Irx3

Question 22

Name the class II transcription factors which are activated by Shh in the ventral part of the vertebrate embryo neural tube. (2)

Answer 22

Nkx6.1

Nkx2.2

Question 23

Name the part of the vertebrate embryo which induces formation of the roof plate. (1)

Answer 23

Dorsal ectoderm which has healed over the neural tube.

Question 24

Name the molecule/s which is/are produced by the dorsal ectoderm and roof plate in the vertebrate embryo to induce dorsal fates in the neural tube.

Answer 24

BMP

Along with other members of the TGF-b family

Question 25

Name the family of molecules which BMP belongs to. (1)

Answer 25

TGF-b superfamily

Question 26

True or false? (1)

BMPs released from the dorsal ectoderm and floor plate in the vertebrate embryo form a concentration gradient in order to induce different dorsal fates in the neural tube.

Answer 26

False - change floor plate to roof plate

Question 27

Name two structures in the vertebrate embryo which release BMPs, along with other members of the TGF-b family, to pattern the dorsal part of the neural tube. (2)

Answer 27

• Dorsal ectoderm
• Roof plate

Question 28

Apart from Shh, BMP, and members of the TGFb family, name another molecule which may be involved in patterning the vertebrate embryo neural tube in the DV axis. (1)

Answer 28

Wnt

Question 29

Describe ‘specification’, when referring to levels of cellular commitment. (2)

Answer 29

The cell is capable of differentiating autonomously in a neutral environment.

This stage can be reversed.

Question 30

Describe ‘determination’, when referring to levels of cellular commitment. (2)

Answer 30

The cell will retain its fate when place into a different environment of the embryo (which may promote other fates).

This stage is irreversible and the cell is now committed to a particular fate.

Question 31

Describe one difference in the lumen of the neural tube between the cranial and caudal ends of the vertebrate embryo. (2)

Answer 31

CRANIAL:
- Cells secrete fluid into lumen to create brain vesicles

CAUDAL:
- Lumen remains very narrow with no fluid secretion

Question 32

Describe the protein products which are produced due to the expression of Hox genes. (2)

Answer 32

Transcription factors

which contain a homeodomain that interacts with DNA.

Question 33

What is the role of Hox genes/transcription factors in the vertebrate embryo? (3)

Answer 33

Activate programs of gene expression

along AP axis

for all tissues in the embryo, not just neural tissues.

Question 34

Although Hox genes have been highly conserved between organisms (eg. flies and humans), the Hox genes expressed in higher organisms are different to those expressed in Drosophila.

Explain how and why the Hox code is different. (3)

Answer 34

As vertebrates have evolved the Hox genes have duplicated

so more Hox genes present in vertebrates

to produce a much more complex AP pattern.

Question 35

Describe the importance of the Hox genes being expressed in a specific order on the chromosome during embryonic development. (2)

Answer 35

• Hox genes expressed on chromosome in the order that they are expressed on AP axis
• This has been conserved between organisms so the same Hox gene which forms the head region in drosophila will also form the head region in vertebrates

Question 36

Describe the organisation of the embryonic rhombencephalon in the AP axis. (1)

Answer 36

Split into rhombomeres

Question 37

Describe what would happen in the vertebrate embryo if two rhombomeres expressed the same Hox genes. (1)

Answer 37

These rhombomeres would have the same structure and function

Question 38

Describe what is meant by the following sentence:

‘Hox genes exhibit nested domains of expression in the vertebrate embryo.’

(3)

Answer 38

Hox genes have overlapping domains of expression.

More Hox genes are turned on moving posteriorly in the embryo.

Moving posteriorly, the more anterior genes fade out and the ‘newly expressed’ genes become more dominant.

Question 39

Describe the synthesis and degradation of RA in the vertebrate embryo. (3)

Answer 39

RA synthesised from vitamin A.

By Raldh enzymes expressed by mesoderm.

Then degraded anteriorly by enzymes (eg. Cyp26a1).

Question 40

How is retinoic acid able to influence Hox gene expression in the vertebrate embryo? (1)

Answer 40

Hox gene promotors may express retinoic acid response elements (RARE).

Question 41

Complete the sentence. (1)

In the vertebrate embryo, the peripheral nervous system is derived from …………………………..

Answer 41

The neural crest / neural crest cells

Question 42

Which part of the early vertebrate embryo (after gastrulation but before neurulation has occurred) goes on to form the neural crest? (1)

Answer 42

Neural plate border

Question 43

In the early vertebrate embryo, is the neural crest located ventrally or dorsally in the neural tube? (1)

Answer 43

Dorsally

Question 44

True or false? (1)

As in the CNS, the PNS develops from anterior to posterior in the vertebrate embryo.

Answer 44

True

Question 45

Give five cell types in the vertebrate embryo/adult that are derived from the neural crest. (5)

Answer 45

• Neurones
• Glial cells
• Pigment cells (melanocytes)
• Endocrine cells (chromaffin cells)
• Mesenchymal cells (osteocytes)

Question 46

What do studies show happens if the dorsal neural tube (ie. the neural crest) is ablated in the vertebrate embryo? (1)

Answer 46

The neural crest regenerates

Question 47

Give three molecules which may be early markers of the neural crest cells in the vertebrate embryo.

Where are these molecules expressed? (4)

Answer 47

• Pax7
• Sox10
• HNK1

Expressed at the neural plate border.

Question 48

What type of molecule is Pax7? (1)

Answer 48

Transcription factor

Question 49

Describe a difference in the expression of Pax7 and Sox10 in the neural crest / PNS of the vertebrate embryo. (2)

Answer 49

Pax7 expressed earlier and switched off as neural crest cells migrate away from neural tube.

Sox10 expressed later and doesn’t switch off as cells migrate.

Question 50

Name two signalling molecules that can induce neural crest, depending on their timing and exposure in the vertebrate embryo. (2)

Answer 50

• Wnt
• BMP

Question 51

Describe the temporal relationship between wnt and BMP which is required to induce neural crest in the vertebrate embryo. (2)

Answer 51

Wnt induces BMP

and then remains switched on.

Question 52

True or false? (1)

Later in vertebrate embryonic development, BMPs alone can induce neural crest, without involvement from Wnt.

Answer 52

True

Question 53

Describe what you would expect to happen if you cultured ventral neural tube cells from the vertebrate embryo with a sample of ectoderm.
Why would this happen? (2)

Answer 53

Cells would become neural crest

because ectoderm produces BMPs.

Question 54

Describe what you would expect to happen if you cultured ventral neural tube cells from the vertebrate embryo with added BMP4 and BMP7. (1)

Answer 54

Neural crest would be produced.

Question 55

How might studying neural crest cell migration be relevant in clinical situations? (1)

Answer 55

Neural crest cell migration may also be applicable to cancer metastasis.

Question 56

Name a gene in the vertebrate embryo which is essential to allow neural crest cells to migrate.
What family is this gene a member of? (1)

Answer 56

Slug (snail in mice)

Member of snail family

Question 57

What type of protein does the slug gene encode in the vertebrate embryo? (1)

Answer 57

Zinc-finger transcription factor

Question 58

Describe how expression of the slug gene in the vertebrate embryo allows neural crest cells to migrate. (1)

Answer 58

Inhibits N-cadherin

Question 59

Name a cadherin in the vertebrate embryo which has to be active to allow neural crest cell migration. (1)

Answer 59

Cadherin-7

Question 60

Describe what you would expect to happen if antisense oligonucleotides against slug were injected into a vertebrate embryo. (1)

Answer 60

Neural crest cells would not be able to migrate.

Question 61

True or false? (1)

The mechanism of inhibiting cadherin-7 and activating N-cadherin to allow neural crest cell migration can be applied to all vertebrates.

Answer 61

False:

• It may not happen in mammals
• N-cadherin is inhibited and cadherin-7 is activated

Question 62

Briefly describe the two possible migratory routes that neural crest cells can take.
Give an example of the ‘types/fates’ of neural crest cells that take each route. (4)

Answer 62

• Through somites (eg. dorsal root ganglia)
• Just underneath ectoderm (eg. melanocytes)

Question 63

Describe the results of an experiment where:

a) the neural tube
b) the somites

in the vertebrate embryo are rotated to study the route that neural crest cells take during migration. (2)

Answer 63

Neural crest cells will ALWAYS migrate through the anterior section of somite (or the section that was originally anterior).

Question 64

What can be deduced from the finding that neural crest cells always migrate through the anterior portion of somites, even if the somites or neural crest are rotated? (2)

Answer 64

Somite tissue dictates neural crest migration,

posterior section produces a repulsive signal.

Question 65

In which embryonic animal model would experiments be best performed which involve rotating either the neural tube or the somites to study neural crest cell migration? (1)

Answer 65

Chick

Question 66

In which region of the vertebrate embryo may neural crest cells be able to make bone and muscle?
Name two transcription factors needed for this. (3)

Answer 66

Cranial region

Sox8
Sox9

Question 67

In what type of embryonic animal model are experiments typically performed regarding neural crest cell fate? (1)

Answer 67

Quail/chick chimeras

Question 68

In general, are neural crest cells specified before or after migration in the vertebrate embryo?

Describe how/when the neural crest cells acquire their fate. (4)

Answer 68

Cells acquire fate at various times.

Neural crest cells appear to be a mixture of cells at various stages of commitment to different fates.

Some cells are still able to acquire all fates and some are more restricted.

As cells migrate, if they arrive in an appropriate environment to develop one of their specified fates, they do so, and if not, they die.

Question 69

What is a placode, and what do placodes turn into in the vertebrate embryo/adult? (3)

Answer 69

Specialised regions of the cranial neuroectoderm

which form special sense organs and some sensory neurones in the head.

But some placodes from non-neural ectoderm can form hair follicles, feathers, and teeth.

Question 70

Give four genes/molecules that establish neural competence to neural crest cells. (4)

Answer 70

• BMP
• FGF
• Wnt
• Pax7

Question 71

Give three genes/molecules which play a role in delamination and migration of neural crest cells. (3)

Answer 71

• Snail/slug
• FoxD3
• Sox10

Question 72

Give a potential role of Sox10 in the delamination and migration of neural crest cells in the vertebrate embryo. (1)

Answer 72

Activates cadherin-7

Question 73

Describe what is meant by the following sentence. (3)

To initiate neural crest cell delamination and migration in the vertebrate embryo, there must be a switch from type I to type II cadherins.

Answer 73

N-cadherin is type I

Cadherin-7 is type II

Switch from N-cadherin to cadherin-7 essential for migration.

Question 74

True or false? (1)

The methods that axons use to navigate to their target in the vertebrate embryo are thought to be the same as glia, dendrite, and neural crest path finding.

Answer 74

True

Question 75

Complete the sentence regarding vertebrate embryos. (1)

The …………………. is the part at the end of the neurite which facilitates extension of the neurite.

Answer 75

growth cone

Question 76

What are microspikes, in relation to growth cones? (1)

Answer 76

Tiny projections which come off the filopodia.

Question 77

Describe the cytoskeleton of the embryonic axon and growth cone. (3)

Answer 77

Axon formed of microtubules

Growth cone contains actin network

Actin bundles and a few microtubules extend into filopodia

Question 78

What is the name given to microtubules which extend into the filopodia of the growth cone? (1)

Answer 78

Pioneer microtubules

Question 79

How are pioneer microtubules able to drive axon growth at the tip of the growth cone? (1)

Answer 79

Contain kinesin on their tips

Question 80

True or false? (1)

The growth cone is a highly-active structure, meaning that some essential molecules such as DNA and proteins (tubulin) are constantly being transported to the growth cone.

Answer 80

False - molecules are STORED in the growth cone, and it is RNA (DNA stays in nucleus)

Question 81

Name the small protein molecules which make microtubules. (1)

Answer 81

Tubulin

Question 82

Describe the arrangement of microtubules within the vertebrate embryonic axon. (2)

Answer 82

• Microtubules laid down with plus ends (rapidly growing ends) pointed towards tip
• Microtubules cross-linked by microtubule-associated proteins (MAPs)

Question 83

Give two examples of microtubule-associated proteins found in the embryonic axon, and describe their function. (2)

Answer 83

• Examples include Tau and MAP1/MAP2 families
• MAPs help transport molecules to the growth cone from the cell body

Question 84

Describe the location and function of the actin meshwork in an embryonic axon. (2)

Answer 84

• Located just underneath plasma membrane
• Provides shape and stability

Question 85

Name the proposed mechanism by which a growth cone can extend and elongate the axon in the vertebrate embryo. (1)

Answer 85

Molecular clutch

Question 86

Briefly describe the molecular clutch hypothesis of axon/growth cone growth in the vertebrate embryo. (4)

Answer 86

Clutch not engaged = membrane anchored to ECM but actin cytoskeleton is not

When new actin molecules added, retrograde flow occurs as new actin cannot protrude

Clutch engaged = both membrane and cytoskeleton anchored to ECM

Addition of new actin cannot cause retrograde flow so new actin protrudes and causes growth

Question 87

Describe why a balance must be established between a growth cone making and breaking connections with the ECM in order for the growth cone to cause axon elongation. (2)

Answer 87

• As leading edge advances forwards (makes connections),
• following edge must unstick to allow whole structure to move.

(As front sticks, back has to unstick)

Question 88

Name the individual molecules which stick together to form an actin filament. (1)

Answer 88

Microfilament

Question 89

Describe the response of a growth cone in the vertebrate embryo when it meets a repulsive guidance cue. (2)

Answer 89

• Growth cone collapses
• Then the growth cone puts out new processes to attempt to grow again

Question 90

Describe the response of a growth cone in the vertebrate embryo when it meets an attractive guidance cue. (1)

Answer 90

Activation of actin and tubulin outgrowth mechanisms.

Question 91

True or false? (1)

As an axon begins to extend towards its target, it mainly responds to diffusible cues, and contact cues become more relevant as the axon gets closer to its target.

Answer 91

False - first responds to contact cues, then diffusible cues close to target

Question 92

Name the main signalling pathway within the axonal growth cone which leads to either collapse or extension after a guidance cue has been detected. (1)

Answer 92

Rac-Rho System

Question 93

Describe how the Rac-Rho system responds when an attractive guidance cue binds to the axonal growth cone. (2)

Answer 93

Rac activated.

Rac inhibits Rho and stimulates growth via the actin cytoskeleton.

Question 94

Describe how the Rac-Rho system responds when a repulsive guidance cue binds to the axonal growth cone. (2)

Answer 94

Rho activated

Rho inhibits Rac and inhibits growth of actin cytoskeleton.

Question 95

What types of molecules are Rac and Rho? (1)

Answer 95

G-proteins

Question 96

How are Rac and Rho activated/inactivated in the axonal growth cone? (1)

Answer 96

Via interaction with GDP/GTP

Question 97

Describe how different neurites are able to respond differently to the same external guidance cues. (1)

Answer 97

Different intra- and extra-cellular machinery

(eg. receptors and signalling pathways)

Question 98

True or false? Give an explanation. (1)

Some aspects of neurite outgrowth can be cell autonomous and do not rely on external cues.

Answer 98

True - given types of neurones can produce specific general morphologies (eg. motor neurone with one axon or purkinje cell with many dendrites)

Question 99

Are axons organised before outgrowth, or do they become organised once they have found a target? (1)

Answer 99

Tend to be organised before outgrowth (have specific targets which they will grow towards)

Question 100

Give three general pathways that axons might follow as they first migrate (pretty non-specifically) to their target. (3)

Answer 100

• Along blood vessels
• glial tracts
• Tissue borders

Question 101

True or false? (1)

Studies show that axons will always grow towards their specific intended target, but if this target is out of range the axon will die.

Answer 101

False - Axons will grow towards their specific target, but if that target is not in range they have the ability to find a similar type of target to innervate

Question 102

True or false? (1)

Vertebrate embryos tend to use the same axon guidance molecules found in invertebrate embryos.

Answer 102

True

Question 103

Name two types of molecules involved in cell-cell adhesion during axon pathfinding in the vertebrate embryo. (2)

Answer 103

Cadherins

Cell adhesion molecules (CAMs)

Question 104

Name three types of molecules involved in cell-ECM adhesion during axon pathfinding in the vertebrate embryo. (3)

Answer 104

• Integrins
• Laminin
• Fibronectin

Question 105

Give three examples of cell-attached, positive axon guidance cues in the vertebrate embryo. (3)

Answer 105

• CAMs
• Cadherins
• Integrins

Question 106

Give an example of a secreted, positive axon guidance cue in the vertebrate embryo. (1)

Answer 106

Netrin I

Question 107

Give two examples of secreted, negative axon guidance cues in the vertebrate embryo. (2)

Answer 107

• Netrins
• Semaphorins

Question 108

Give one example of a cell-attached, negative axon guidance cue in the vertebrate embryo. (1)

Answer 108

Semaphorin I

Question 109

Describe whether cadherins and CAMs are homophilic or heterophilic. (2)

Answer 109

Cadherins are homophilic

CAMs can be homophilic or heterophilic

Question 110

Describe whether cadherins and CAMs are calcium-dependent or calcium-independent. (2)

Answer 110

Cadherins are calcium-dependent

CAMs are calcium-independent

Question 111

Give an example of a cadherin involved in axon guidance. (1)

Answer 111

N-Cadherin

Question 112

Give an example of a CAM involved in axon guidance. (1)

Answer 112

N-CAM

Question 113

Describe how integrins and laminins/fibronectins interact to form cell-ECM connections during axon guidance. (2)

Answer 113

Integrins attached to cells and extend into ECM

Integrins on cells bind to laminin/fibronectin in ECM

Question 114

In the vertebrate embryo, the floor plate expresses netrin-1.

Describe the response of:

a) commissural/sensory neurones
b) motor neurones

to the floor plate. (1)

Answer 114

Sensory neurones attracted to floor plate.

Motor neurones repelled from floor plate.

Question 115

Describe the response of commissural axons which are grown in culture with:

a) floor plate
b) roof plate
c) fibroblasts expressing Netrin-1

(3)

Answer 115

a) axons attracted to floor plate

b) axons not attracted to roof plate

c) axons attracted to fibroblasts

Question 116

Give an example of how 2 different types of neurone can respond differently to a group of semaphorin-3 secreting cells. (2)

Answer 116

• Mechanoreceptor neurones will be repelled
• NT-3 responsive neurones will be attracted

Question 117

True or false? (1)

Different regions of a cell (eg. dendrites and neurones) can have different responses to the same guidance cue.

Answer 117

True

Question 118

Describe and explain the results of an experiment which tested the effect of semaphorin 3a on the dendrites/axon of the same cell.
How is this affected by cGMP? (5)

Answer 118

Dendrites grow towards SEMA-3A

because they express cGMP.

Axons grow away from SEMA-3A

because they do not express cGMP.

Guanylyl cyclase ‘cap’ seen where dendrite forms and throughout dendrite.

Question 119

Describe how commissural axons in the vertebrate embryo spinal cord have to change their response to guidance cues as they cross the midline. (3)

Answer 119

• Initial attraction to floor plate
• Then repulsion from floor plate
• Then direction change to travel up spinal cord

Question 120

An ‘open book’ explant was performed, where the neural tube from a vertebrate embryo was unrolled (so floor plate was located in the middle of the tissue strip), and commissural axon growth was observed.

What would happen if:

a) nothing was changed
b) ectopic floor plate was added before normal floor plate
c) ectopic floor plate was added after normal floor plate
d) normal floor plate moved to a point further along the tissue strip

What does this tell us about the changing response of commissural fibres to axon guidance cues? (5)

Answer 120

a) axons travel through floor plate then carry on away from it like usual

b) axons travel to ectopic floor plate and do not continue growth towards the normal floor plate

c) axons travel through normal floor plate and ignore ectopic floor plate

d) axons travel to floor plate despite its change of location

This tells us that axons are attracted to the floor plate, but once they have crossed, they are repelled by floor plate.

Question 121

Describe how vertebrate embryo commissural axons are attracted to the midline floor plate. (2)

Answer 121

Netrin secreted by midline.

Axons express DCC receptor.

Question 122

Name the ligand and receptor which mediate the repulsive properties of the midline floor plate to commissural axons in the vertebrate embryo. (2)

Answer 122

Slit and robo

Question 123

If netrin is not expressed by the midline floor plate in the vertebrate embryo, some commissural axons will still grow towards the floor plate.
How is this possible? (2)

Answer 123

• Shh attraction
• BMP repulsion

Question 124

Name the molecule (in drosophila, but which may also apply to vertebrates) which alters expression of robo in commissural axons as they cross the midline floor plate. (1)

Answer 124

Comm

Question 125

Name the cell adhesion molecule which is expressed by longitudinal fascicles travelling in the vertebrate embryo spinal cord, which allows commissural axons to join once they have crossed the midline. (1)

Answer 125

Fasciclin II

Question 126

There are three main fascicles travelling longitudinally in the vertebrate embryo spinal cord to the brain (medial, intermediate, and lateral).

Commissural axons expressing only robo1 will join which fascicle after they have crossed the midline floor plate? (1)

Answer 126

Medial

Question 127

There are three main fascicles travelling longitudinally in the vertebrate embryo spinal cord to the brain (medial, intermediate, and lateral).

Commissural axons expressing robo1 and robo3 will join which fascicle after they have crossed the midline floor plate? (1)

Answer 127

Intermediate

Question 128

There are three main fascicles travelling longitudinally in the vertebrate embryo spinal cord to the brain (medial, intermediate, and lateral).

Commissural axons expressing robo1, robo2, and robo3 will join which fascicle after they have crossed the midline floor plate? (1)

Answer 128

Lateral

Question 129

Describe how the robo receptors that a commissural axon expresses helps determine which fascicle (medial, intermediate, lateral) the axon will join once it has crossed the midline of the vertebrate embryo. (3)

Answer 129

The more robo receptors (ie, robo1/robo2/robo3 or a mixture) a neurone expresses

the more sensitive it will be to midline slit repulsion

and the further it will grow away from the midline.

ie. more robo = lateral fascicle

Question 130

Describe what is meant by the ‘retinotectal map’. (2)

Answer 130

The process by which information from the retina is mapped onto the visual cortex

in a spatially-organised fashion.

Question 131

Complete the sentence regarding the formation of the vertebrate retinotectal map. (2)

Neurones grow along the surface of the retina to the exit point, where ………………. promotes migration and fasciculation to form the …………………..

Answer 131

N-CAM

Optic Nerve

Question 132

Complete the sentence regarding the formation of the vertebrate retinotectal map. (2)

Where the optic nerve exits the retina, the combination of ……………….. and extracellular ………………. repels axons and stimulates them to grow into the brain.

Answer 132

Netrin-1

Laminin

Question 133

Complete the sentence regarding the formation of the vertebrate retinotectal map. (2)

At the optic chiasm, ………………… on brain cells and ……………… receptors on axons allow some axons to cross and some to remain ipsilateral.

Answer 133

Ephrins

Eph

Question 134

Complete the sentence regarding the formation of the vertebrate retinotectal map. (2)

When the optic nerves have crossed at the chiasm, ………………… and …………………. then promote growth along the optic tracts.

Answer 134

• L1CAM
• Laminin

Question 135

Axons from the dorsal region of the retina must project to which region of the tectum? (1)

Answer 135

Ventral

Question 136

Axons from the ventral region of the retina must project to which region of the tectum? (1)

Answer 136

Dorsal

Question 137

Axons from the nasal region of the retina must project to which region of the tectum? (1)

Answer 137

posterior

Question 138

Axons from the temporal region of the retina must project to which region of the tectum? (1)

Answer 138

Anterior

Question 139

Name the ligand/receptor which facilitate pattern-matching of the retinotectal map. (1)

Answer 139

Ephrins/Ephs

Question 140

Describe how Ephrins/Ephs are able to match axons from specific regions of the retina to their correct region in the tectum. (5)

*Nasal axons go to posterior tectum
*Temporal axons go to anterior tectum

Answer 140

Ephrins act as inhibitory signals.

Gradient of Ephrins in tectum - lowest anterior and highest posterior.

Nasal axons must express low levels of Eph receptor so can travel into the regions of high Ephrin concentrations.

Temporal axons must express high levels of Eph receptor so cannot travel through higher levels of Ephrins in tectum, and stop in anterior region.

Dorsal and ventral axons must express intermediate levels of Eph receptor.

Question 141

This question refers to the development of the retinotectal map.

Temporal and nasal retinal axons were grown using a stripe assay.
A slide contained areas of anterior tectum and separate areas of posterior tectum.

Which areas would you expect the temporal fibres to grow on and which areas would you expect the nasal fibres to grow on? (2)

Answer 141

Temporal fibres would grow on anterior portions only

Nasal fibres would grown on both anterior and posterior portions

Question 142

True or false? (1)

The Ephrin/Eph method of matching retinal ganglion axons to their optic tectum target may also be used to match motor neurones to their target muscles.

Answer 142

True

Question 143

Briefly describe the steps required for NMJ synaptogenesis in the vertebrate embryo. (5)

Answer 143

• Axonal growth cone makes contact with target muscle (via ligands/receptors/guidance molecules)
• Postsynaptic receptors cluster at contact site
• Growth cone differentiates into presynaptic terminal (bouton)
• Each presynaptic terminal contains active zone which lies opposite a cluster of AChRs on postsynapse
• Basal lamina forms in synaptic cleft

Question 144

Describe the structure of the NMJ at the end of embryogenesis.

How does this change during later stages of development? (2)

Answer 144

• Functional NMJs with multiple synaptic contacts
• During later stages there is synaptic refinement so that only one synapse remains

Question 145

Briefly describe the 2 different mechanisms of postsynaptic receptor clustering during embryonic synaptogenesis. (2)

Answer 145

• Initial redistribution of existing AChRs
• Altered expression of genes encoding AChR subunits

Question 146

Describe how the expression of genes encoding AChR subunits are altered during synaptogenesis. (2)

Answer 146

• Upregulated near synapse
• Downregulated away from synapses

Question 147

Describe the molecular mechanisms allowing postsynaptic receptor clustering at the NMJ. (4)

Answer 147

• Agrin protein synthesised and transported down motor axons
• Agrin incorporated into basal lamina between pre and post synapse
• Agrin acts on muscle-specific tyrosine kinase called MuSK
• MuSK affects Rapsyn protein which anchors AChR to the cytoskeleton

Question 148

Name the three main molecules involved in postsynaptic AChR clustering at the NMJ. (3)

Answer 148

• Agrin
• MuSK
• Rapsyn

Question 149

What would you expect to see regarding AChR clustering at the NMJ in the presence of the following molecules? (3)

a) Agrin mutant
b) MuSk mutant
c) Rapsyn mutant

Answer 149

All would result in no/reduced receptor clustering

Question 150

Give two roles of the basal lamina in synaptogenesis. (2)

Answer 150

• Marks site of synapse formation
• Receptor clustering

Question 151

What would happen if you destroyed a muscle fibre and its connecting synapse, but left the basal lamina intact and added a new migrating axon? (1)

Answer 151

New axon would form a synapse at the site on the basal lamina which had previously been occupied by a synapse.

Question 152

Name an essential basal lamina molecule which may aid in marking the site of synapse formation during synaptogenesis. (1)

Answer 152

Laminin

Question 153

Describe how neural electrical activity is able to regulate postsynaptic AChR expression in the newly-functional NMJ. (2)

Answer 153

Neural activity represses gene expression in non-synaptic areas.

Following denervation gene expression in non-synaptic sites is upregulated.

Question 154

Describe the role of the postsynaptic dendrite in CNS synaptogenesis. (2)

Answer 154

Extends a filopodium to axonal growth cone,

then axon guidance molecules may prime the axon and dendrite for synapse formation.

Question 155

Out of neuroligins and neurexins, which is the ligand and which is the receptor? (2)

Answer 155

Neuroligins are ligands

Neurexins are receptors

Question 156

True or false? (1)

Neuroligins are expressed on the postsynaptic membrane and neurexins are expressed on the axonal growth cone.

Answer 156

True

Question 157

Describe the role of the neurexin/neuroligin connections in CNS synaptogenesis.

How does their function relate to their structures? (2)

Answer 157

Bind to form a bridge between pre- and post-synaptic neurones.

They are then able to organise the active zone and post-synaptic density.

• Able to arrange intracellular structures because they are transmembrane proteins

Question 158

Complete the sentence regarding CNS synaptogenesis. (2)

Neuoligins and neurexins are able to organise axons and dendrites for synaptogenesis, however this seems to be dependent on an influx of …………………… into the ……………………….

Answer 158

Calcium ions

Presynaptic terminal

Question 159

Briefly describe the roles of cadherins and synCAM in CNS synaptogenesis. (3)

Answer 159

Once the synapse has been formed they stabilize it

by recruiting scaffolding proteins

and further developing the active zone and post-synaptic density.

Question 160

Give two general reasons why neurones need to modify the connections formed in the embryo. (2)

Answer 160

• Too many synapses
• Inaccurate wiring

Question 161

Describe in general terms, how the number of innervating neurones is matched to the size of the target tissue during development of the vertebrate nervous system. (2)

Answer 161

• Neurones must be sustained by their target
• However target is only able to sustain a minimal number of neurones

Question 162

Name the type of molecules produced by target tissues which enables a synapse to maintain its connection with the target. (1)

Answer 162

Neurotrophic factors

Question 163

Give two examples of neurotrophic factors, and state what type of neurones they act on. (4)

Answer 163

Nerve growth factor (NGF; for sensory and sympathetic neurones)

BDNF (for sensory neurones)

Question 164

What effect do neurotrophic factors released from target tissues have on the innervating neurone? (1)

Answer 164

Promotes survival

Question 165

True or false? (1)

Target tissues in the embryo require a functional synapse (electrical stimulation) in order to start producing neurotrophic factors.

Answer 165

True

Question 166

What effect would be seen if NGF was injected into a tissue containing dying cells? (1)

Answer 166

Dying cells would be rescued

Question 167

What effect would be seen if antibodies against NGF were injected into a tissue? (1)

Answer 167

Cell death would be triggered

Question 168

What effect would be seen in vitro if NGF was removed from a tissue sample? (1)

Answer 168

Cells would die

Question 169

True or false? (1)

It is thought that all cells throughout the body are programmed to survive, unless they get a signal to die.

Answer 169

False - all are programmed to die, unless they get a signal to survive

Question 170

True or false? (1)

During the modification of synaptic connections, the larger the target tissue, the more neurotrophins it can produce, so the more neurones survive and innervate it.

Answer 170

True

Question 171

True or false? (1)

Some neurotrophins can cause both cell survival and apoptosis, depending on which co-factor binds to the same receptor.

Answer 171

False - Some neurotrophins can cause both cell survival and apoptosis, depending on which receptor they bind to

Question 172

What is the main type of receptor which binds neurotrophins?

Name one other receptor which binds neurotrophins with lower affinity. (2)

Answer 172

Mainly tyrosine-kinase receptors

p75 binds with low affinity

Question 173

Name the receptor for NGF. (1)

Answer 173

TrkA

Question 174

Name the receptor for NT-3 (a neurotrophin). (1)

Answer 174

TrkC

But can also bind to TrkA and TrkB

Question 175

Name the receptor for both BDNF and NT4/5. (1)

Answer 175

TrkB

Question 176

Describe simply the potential pathway by which neurotrophic factors promote neuronal survival. (2)

Answer 176

• Activate signalling pathway to decrease cytochrome C release from mitochondria
• Cytochrome C usually activates caspases to trigger apoptosis