Neural Development - Extension of axons to targets, formation and modification of synaptic connection Flashcards
What is axon guidance?
After neuron has migrated to final position
= must create neurites (axons and dendrites)
= to connect it to other neurons
= neurites often travel long distances to reach final targets
Growth cone
= at leading edge of each growing neurite
= it extends amoeboid- like fingers = Filopodia
= Filopodia interact with immediate environment
What does Axonal Transport do?
= provides supplies to growth cone
Cell body
= only site of protein synthesis
Membrane components for growth cone extension
= made in cell body as vesicles
= transported along microtubules in the growing neurite
= proteins for neuronal extension transported inside these vesicles to growth cone
= by anterograde axonal transport
What is the role of Actin and Tubulin? What is growth influenced by?
Movement of filopodia
= driven by filaments of actin connected to plasma membrane
= in association with myosin (connected to cytoskeleton)
As growth cone moves forwards
= backbone is continually reinforced with microtubules (tubulin)
= if it keeps moving forwards it must adhere to adjacent cells and ECM
Growth is influenced by
= cell adhesion molecules (CAMs)
= substrate adhesion molecules (SAMs)
= diffusible guidance molecules
What is the structure of the growth cone?
Central Domain
= microtuvules, organneles, vesicles
Transitional Zone
Peripheral domain
= actin, lamellipodia, filopodia
= lamellipodia found in between the filopodia
(flat regions of dense actin meshwork instead of the bundled F-actin found in filopodia)
How does the Axon know where to go?
Highly motile growth cone
= very sensitive to attractive and repellent cues
= they act as molecular guideposts for the developing neuron
= combination of CAMs/SAMs and diffusible chemotropic molecules gives guidance
e.g. if Neuron A can only attach to SAM = X
neuron B to SAM = Y
(resulting in correct orientation to path A or B)
What is N-CAM (cell adhesion molecule)?
= found on surface of neurons and glial cells
= belongs to immunoglobulin superfamily
= shows homophilic adhesion via immunoglobulin domains
= >27 different isoforms
= N-CAM KO mice show axon migration defects
What is N-Cadherin (cell adhesion molecule)?
= contain 5 cadherin repeats
(each comprising of a sandwhich of β sheets)
= show homophilic Ca2+-dependent adhesion at each end
= functional unit is a dimer
= anti-N-cadherin antibodies prevent outgrowth of Xenopus retinal axons
What are SAMs (substrate adhesion molecule)?
= substrate adhesion molecules
= important ECM adhesion molecules: laminin, fibronectin, tenascin
= can inhibit or promote neurite attachment and growth
= laminin / fibronectin in ECM interact with integrin on cell surface
= integrin then interacts with actin to influence growth cone motility
= laminins = trimeric glycoproteins (alpha, beta and gamma chains) with many isoforms to give specificity
= have cross-like structure with multiple binding properties
What are diffusible Chemotropic Molecules?
= can act over longer distances
(substrate-associated cues only work over short distances)
= can act as chemoattractants or chemorepellents
e.g. Netrins - chemoattractant
What are Netrins?
= netrin 1 = made by floor plate of developing spinal cord
= guides development of commisural neurons in spinal cord
= has high homology to ECM molecules like laminin
= ventral floor plate produces netrin-1, netrin-2 and Shh (as chemoattractants)
AND
BMPs in dorsal spinal cord = repel commissural neurons
(drive connections to the ventral spinal cord)
What are Semaphorins?
= some secreted / some membrane-bound
= often guide growth cones by repulsion (short-range inhibitory signals)
= their receptors are neuropilins (for class 3) and plexins (class 1 and others)
Neuropilins
(NRP-1, NRP-2)
= single pass transmembrane receptors that work as dimers
= have no signal transduction system of their own
= so co-receptor: plexin is needed
Plexins
= receptors either alone or in combination with neuropilins
= trigger a novel signal trandsduction pathway controlling cell repulsion
= binding of semaphorin leads to microtubule dissassembly and actin depolymerisation
= leads to growth cone collapse
Semaphorin 3
= secreted by developing spinal cord cells in ventral part
= repels incoming thermoreceptor and pain receptor neurites
(role in axonal guidance)
= group 1a sensory neurons are not affected
(muscle proprioceptor input)
What are Ephrins and EPH?
Ephrins = ligand
EPH = receptor
Migrating axon is repelled away from site of Eph/Ephrin activation
= growth cone collapse
Ephrin A ligand
= GPI anchor to membrane
Ephrin B ligand
= transmembrane
Eph receptor
= tyrosine kinase receptor
= bi-directional signalling
How is Axonal Guidance affected by Ephrins/EPH signalling? What is an example?
Retinotopic map formation
= nerve cells in retina send out projections to the tectum
(superior colliculus in mammals that directs eye movements)
Temporal retinal neurons
= have high sensitivity to Ephrins (repelled)
= break down early on, don’t grow
Nasal retinal neurons
= have low sensitivity to Ephrins
= so extend to a higher concentration of Ephrins
(grow all the way to posterior)
What are Pioneer Axons?
Axons migrate to targets in bundles
= called fascicles
Pioneer axons sent first
= heavily dependent on guidance cues
Follower axons
= use existing axons as the pathway to follow
What are NGF / other Neurotropic Factors for?
NGF
= Initiate neurite outgrowth and needed for survival
Without NGF
= poor neurite outgrowth
= neurons die
With NGF
= prolific neurote outgrowth
= neurons survive
BDNF - Brain derived neurotrophic factor and neutrophins are others
Receptors = are tyrosine receptor kinases (trk)
