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Nov 6, 2011

Growth cone and its role in axonal guidance


Growth cone are specialized and highly motile cellular compartment at the tips of the growing axon which supports the growth of the axon by sensing the extracellular cues and transducing it to the cytoskeletons.

The structure consists of a central region filled with organelles and microtubules; whereas at the peripheral region, it has highly dynamic, actin rich region such as Lamellipodia and Filopodia.

Lamellipodia are the broad veil like cellular protrusions that contain branched actin filaments. Filopodia are thin protrusions made out of unbranched and parallel F actin bundles. 

Fig 1: Shows that the central region of the structure is composed of densely concentrated organelles, whereas thin veil like Lamellipodia and spiky Filopodia is found at the peripheral region.  

This is large paused growth cone imaged through differential interference contrast microscope. 

A brief about growth cone and its structure is explained in the topic called Cytoskeleton Role in Neuronal polarity.

A growth cone helps the developing neuron to reach the particular target site or synaptic partner. Hence axonal growth cones used to navigate along the specific pathways in the response to the molecule guidance cues. In this article, it will be explained that how growth cone is influenced by extracellular cues inorder to select a particular pathway towards the target site.

The growth cone is highly concentrated with actin filaments rather than microtubule. Microtubules which are bundled together in the axon shaft will also extend into the central region of the growth cones, but the growth cone stalls it, thereby making it to form a prominent loop in the central region.

Fig 2: distribution of actin and microtubule in the growth cone. 

In the Filopodia region, the actin filaments will constantly undergo polymerization and depolymerization. At the barbed end there will be addition of G actin molecule, whereas the in the pointed end the G actin molecules are constantly removed, thereby leading to the movement and extension of Filopodia. The G-actin molecule is brought back from the peripheral region to the distal region by myosin (actin cargo carrying protein) and this process we term as retrograde movement. The tip of the Filopodia contains the receptors for the extracellular cues and in the Lamellipodia is concentrated with regulators of actin and microtubules which gets activated and deactivated based the signals obtained at the peripheral region of the growth cones. Combining these two properties, growth cone is said to be the compartment which has the ability to guide the neuron to reach its target site or synaptic partner. 

Fig 3: Pictorial representation of growth cone action towards the gradient. 

In the fig 3, it’s shown how the cytoskeletons modify which lead the growth cone to turn towards the highly concentrated gradient. The polymerization and depolymerization of the actin takes place simultaneously in different regions. For eg: In the stage 3, the filaments are stable and polymerize towards the attracting gradient region, whereas there happens to be depolymerization in the non gradient region of the Growth cone. 

Cytoskeletons
Stage 1
Stage 2
Stage 3
Stage 4
Actin
Balanced F actin dynamics across the GC
Increase in anticapping and severing, decrease in capping leading to polymerization
Cross linking of the filament leads to stable ribs.  
Capping of the F actin filament will not allow the polymerization and finalize to stabilization.
Microtubules
Random MT exploration of P region
Polymerization happens with less catastrophe
Acetylation and detyrosination leads to stabilization of microtubule.
Bundling

  Table 1: Action of cytoskeletons in the growth cone under two gradient regions. 


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