MSc III Sem PPT: Axonal Guidance and Neurotropic Factors

Summary

This presentation covers the intricate process of axonal guidance, focusing on the role of neurotropic factors in guiding growing axons to their target cells. It details the molecular mechanisms, including signal reception, transduction, and growth cone responses, driven by guidance cues like chemoattractants and chemorepellents. The presentation also explores the role of the cytoskeleton in growth cone dynamics and the importance of different guidance cues, and their receptors in axonal pathfinding and target selection.

Full Transcript

SGT UNIVERSITY
Gurugram

Subject – Advanced Neurobiochemistry
And
Immunology

Topic – Axonal Guidance and
Neurotropic Factors

Submitted to Presented by
Dr.Shweta Tripathi Ritu and Reetika
Assistant Professor MNNT III Sem
FAHS, FAHS,
SGT University SGT University
Axonal Guidance
and Neurotropic
Factors
Axonal guidance is the intricate process by which growing
axons navigate the developing nervous system to reach their
correct target cells. This journey is guided by a complex
interplay of molecular cues and cellular interactions. Neuronal
growth factors play a crucial role in supporting axon growth
and survival during this journey.
Role of Neuronal Growth
Factors
Neuronal growth factors are proteins that promote the survival,
growth, and differentiation of neurons. These essential molecules act
as guiding signals, influencing axon elongation, branching, and target
selection.

1 Promoting Survival 2 Stimulating Growth
Growth factors act as life- They trigger the
sustaining signals, production of proteins and
preventing neurons from other molecules necessary
undergoing apoptosis for axon elongation and
(programmed cell death). branching.

3 Guiding Pathfinding
Growth factors influence the direction of axon growth, ensuring
they reach their appropriate targets.
Molecular Mechanisms of Axon
Guidance
Axon guidance is a complex process involving intricate molecular interactions.
Guidance cues, such as chemoattractants and chemorepellents, bind to specific
receptors on the axonal surface, triggering intracellular signaling cascades that
influence axon behavior.

1 Signal Reception
Guidance cues bind to receptors on the axonal surface, initiating a
signaling cascade.

2 Signal Transduction
The signal is relayed through a series of intracellular molecules,
activating downstream effector proteins.

3 Growth Cone Response
The signal alters the cytoskeleton and growth cone dynamics,
directing axon growth towards or away from the cue.
Axon Development and
Growth Cone Formation
1 Axon Initiation
Axon development begins with the formation of a growth cone,
a specialized structure at the tip of the axon.

2 Growth Cone Morphology
The growth cone is characterized by filopodia and lamellipodia,
which serve as exploratory structures that sense the
environment.

3 Axon Extension
The growth cone is highly dynamic and constantly extends,
retracts, and turns as it navigates the environment towards its
target.
 Growth Cone Structure and Function
Growth cones, the dynamic tips of axons, are responsible for sensing and responding to guidance cues.
They have a complex structure, consisting of filopodia and lamellipodia, which explore the environment
and direct axon growth.
Filopodia Lamellipodia Cytoskeleton

Slender, finger-like projections A flattened, sheet-like structure A network of microtubules and
that extend from the growth that forms a wider area of actin filaments that provides
cone, probing the environment contact with the extracellular structural support and
for guidance cues. matrix. facilitates growth cone
movement.
The Role of the Cytoskeleton in Growth Cone Dynamics
The cytoskeleton of the growth cone, composed of microtubules and actin filaments, plays a crucial role in shaping the growth cone, driving its motility, and mediating its
responses to guidance cues.

Microtubules
Growth Cone Extension
Microtubules extend from the axon shaft into the central region,
providing structural support and serving as tracks for Microtubule polymerization and actin filament assembly drive
intracellular transport. the extension of the growth cone, propelling it forward.

1 2 3 4

Actin Filaments Growth Cone Retraction
Actin filaments are highly dynamic and form a network in the Microtubule depolymerization and actin filament disassembly
lamellipodia and filopodia, driving their extension and retraction. contribute to the retraction of the growth cone, allowing it to
change direction.
Molecular Signals in
Axonal Guidance
Attractive Signals Repulsive Signals
These signals draw the growth These signals push the growth
cone towards its target, often cone away from specific areas,
guiding it along specific preventing it from straying into
pathways. They act as 'pulling inappropriate regions. They act
forces' that guide the axon in as 'pushing forces' to steer the
the right direction. axon away from undesirable
areas.

Netrin
A protein family that acts as both attractive and repulsive signals. It
guides axons in the developing nervous system towards specific target
cells, influencing their final destination.
Flowchart of Axonal Guidance

1 Growth Cone Formation
The axon develops a growth cone at its tip, which is a dynamic structure responsible for sensing and responding to guidance cues.

2 Signal Reception
The growth cone receives signals from its environment, including attractants and repellents, through receptors on its surface.

3 Cytoskeletal Rearrangement
The signals trigger a cascade of events leading to the rearrangement of the cytoskeleton within the growth cone, directing its movement.

4 Axon Extension
The growth cone extends the axon in the direction of attractive signals, guided by the dynamic cytoskeletal changes.

5 Target Recognition
When the axon reaches its target cell, the growth cone recognizes specific signals indicating its final destination.
Axon Pathfinding and Target Selection
Axon pathfinding involves a series of decisions as axons navigate the intricate
pathways of the nervous system. This journey is guided by a combination of
guidance cues, growth factors, and interactions with other cells.

Initial Growth
Axons extend from the cell body, exploring the surrounding environment.

Guidance Cue Interactions
Axons respond to guidance cues, directing their growth towards or
away from specific targets.

Target Recognition
Axons recognize their specific targets and establish connections,
forming synapses.
Attractive and Repulsive
Guidance Cues

Attractive cues attract axons towards their target cells, while repulsive
cues guide axons away from inappropriate pathways. These cues act in
a coordinated manner to ensure precise axonal navigation.

Attractive Cues
These cues act like magnets, drawing axons towards their
targets, promoting proper connections.

Repulsive Cues
These cues act like barriers, pushing axons away from
inappropriate pathways, preventing misconnections.
Chemoattractant and Chemorepellent
Signals
Chemoattractants Chemorepellents Gradient Formation

These molecules attract axons, These molecules repel axons, Chemoattractants and
promoting their growth towards preventing them from growing in chemorepellents are often
specific target cells. Examples incorrect directions. Examples expressed in gradients, allowing
include netrins, Slit2, and BDNF. include semaphorins, ephrins, and axons to sense direction and
Slit1. navigate towards or away from
specific targets.
Guidance Cue Gradients

Concentration Gradients Directional Growth
Axon growth cones respond to differences in Guidance cue gradients establish a directional signal that
concentration of guidance cues, moving towards higher guides the growth cone, ensuring that axons grow in the
concentrations of attractants and away from higher correct direction towards their targets.
concentrations of repellents.
Guidance Cues and their
Receptors in Axonal
Pathfinding
Axonal guidance is achieved through a complex interplay between guidance
cues, secreted or membrane-bound molecules that influence growth cone
behavior, and their receptors, which detect and transduce signals.

Guidance Cue Receptor Function

Netrin-1 DCC (Deleted in Attracts axons
Colorectal Cancer) towards target cells

Slit Robo (Roundabout) Repels axons from
inappropriate
pathways
Semaphorin 3A Plexin-A1 Repels axons from
inappropriate
pathways
Ephrins and Eph Receptors in
Axon Guidance
Eph Receptors
These are transmembrane receptor tyrosine kinases found on the surface of neurons.

Ephrins
These are membrane-bound ligands that bind to Eph receptors, triggering
signaling pathways.

Repulsive Guidance
Ephrin-Eph receptor interactions typically lead to repulsive guidance of axons,
preventing them from crossing certain boundaries.

Fine-Tuning
Ephrin-Eph interactions can also contribute to the fine-tuning of axonal projections
within specific target areas.
Semaphorins and
Neuropilins in Axon
Guidance
Semaphorins Neuropilins Function

A family of Transmembrane Mediate repulsive
secreted and receptors that guidance of
membrane-bound bind to axons, ensuring
proteins. semaphorins. correct
pathfinding.
Netrins and Deleted in Colorectal Cancer
(DCC) Receptors

Netrins DCC Receptors Axonal Growth Synapse Formation
A family of secreted proteins Transmembrane receptors that Netrin-DCC interactions
that act as chemoattractants bind to netrins, triggering promote axonal growth and Netrins also play a role in
for axons. signaling pathways that guidance towards specific synapse formation,
promote axonal growth. targets. contributing to the
establishment of functional
neural circuits.
Slits and Robo
Receptors in Axon
Guidance
Slits Robo Receptors
A family of secreted proteins Transmembrane receptors
that act as chemorepellents that bind to Slits, triggering
for axons. signaling pathways that lead
to axonal repulsion.

Boundary Formation
Slit-Robo interactions help to establish boundaries in the
nervous system, guiding axons along specific pathways and
preventing them from crossing into inappropriate areas.
Neurotropic Factors
Definition and
Importance
1 What Are They? 2 Why Are They
Important?
Neurotrophic factors
are a group of proteins They play a critical role
that promote the in the development,
survival, growth, and maintenance, and
differentiation of repair of the nervous
neurons. system.

3 Their Impact
Neurotrophic factors influence neuronal function,
plasticity, and response to injury.
Neurotrophic Factors and
their Receptors
1 Brain-Derived 2 Nerve Growth Factor
Neurotrophic Factor (NGF)
(BDNF)
A key neurotrophic factor for
A powerful neurotrophic factor sensory and sympathetic
that supports the survival and neurons, promoting their
growth of neurons, particularly survival, growth, and
in the hippocampus and cortex. differentiation.

3 Neurotrophin-3 (NT-3) 4 Neurotrophin-4/5 (NT-
4/5)
A neurotrophic factor that A neurotrophic factor that is
promotes the survival and structurally similar to BDNF and
differentiation of motor neurons plays a role in the development
and other neuronal populations. and function of various neuronal
populations.
Role of Neurotrophic Factors in
Axon Guidance
1 Survival
Neurotrophic factors promote the survival of neurons, ensuring that only
those with successful axonal connections are maintained.

2 Growth and Differentiation
Neurotrophic factors stimulate the growth and differentiation of axons,
enabling them to reach their correct targets.

3 Synapse Formation
Neurotrophic factors contribute to the formation of synapses, strengthening
the connections between neurons and establishing functional neural circuits.

4 Plasticity
Neurotrophic factors play a role in neural plasticity, allowing for the
adaptation and refinement of neuronal connections throughout life.
Mechanism of
Neurotrophic Factor
Signaling
Receptor Binding
Neurotrophic factors bind to specific receptors on the surface
of target neurons.

Signal Transduction
This binding activates a signaling cascade within the neuron,
leading to changes in gene expression.

Transcriptional Activation
These changes in gene expression promote the production of
proteins that support survival, growth, and guidance of axons.
Nerve Growth Factor (NGF)
Discovery Function Clinical Significance

NGF was the first neurotrophic NGF plays a crucial role in the NGF has shown promise in
factor to be discovered. development and maintenance treating various neurological
of sensory and sympathetic disorders, including Alzheimer's
It was isolated in the 1950s by
neurons. disease and Parkinson's disease.
Rita Levi-Montalcini and Stanley It promotes the survival, growth,
Cohen. and differentiation of these
neurons.
Brain-Derived Neurotrophic
Factor (BDNF)

Synaptic Plasticity
BDNF enhances synaptic plasticity, the ability of synapses to
strengthen or weaken over time.

Learning and Memory
BDNF plays a critical role in learning and memory formation.

Neuroprotection
BDNF protects neurons from damage and promotes their survival.
Ciliary Neurotrophic Factor
(CNTF)
Function Promotes survival and
differentiation of motor
neurons, retinal ganglion
cells, and other neuronal
populations.
Clinical Applications Being explored for
treatment of amyotrophic
lateral sclerosis (ALS),
retinal degeneration, and
other neurological disorders.
Potential Benefits Could improve motor
function, protect neurons
from degeneration, and
promote nerve
regeneration.
Glial Cell Line-Derived
Neurotrophic Factor (GDNF)

1 Discovery
GDNF was first discovered in 1993.

2 Function
GDNF plays a critical role in the survival and
differentiation of dopaminergic neurons, which are
essential for movement control.

3 Clinical Applications
GDNF is being investigated for the treatment of
Parkinson's disease and other neurodegenerative
disorders.
Implications in Nervous System
Development
Axonal guidance and neuronal growth factors are crucial for proper nervous system
development. Disruptions in these processes can lead to neurological disorders, including
autism, epilepsy, and Alzheimer's disease.

Cognitive Development
Proper axonal connections are essential for cognitive functions, such as learning and memory.

Motor Control
Accurate axonal guidance is crucial for coordinating muscle movement and maintaining balance.

Sensory Perception
Axon pathways convey sensory information from the body to the brain, enabling our senses to
perceive the world.
Clinical Relevance and Future Directions
Understanding axonal guidance and neuronal growth factors has important clinical implications. Research is ongoing to
develop therapies for neurological disorders by promoting axonal regeneration and neuronal survival.

Neurodegenerative Diseases Spinal Cord Injuries Stroke
Targeting growth factors could Enhancing growth factor activity Growth factors could aid in
help slow or reverse neuronal loss might promote axonal neuronal survival and recovery
in diseases like Alzheimer's and regeneration and functional after stroke, promoting brain
Parkinson's. recovery after spinal cord injury. function recovery.
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