Axon guidance
Axon guidance is a critical process in the development of the nervous system that ensures the proper wiring of neurons. It involves the navigation of axons to their target destinations during neurogenesis. This complex process is mediated by a variety of molecular cues and their receptors, which guide axons through the developing brain and spinal cord to establish functional synaptic connections.
Mechanisms of Axon Guidance[edit | edit source]
Axon guidance is governed by four main mechanisms: attraction, repulsion, adhesion, and degradation. These mechanisms are influenced by various molecular cues, including growth factors, chemokines, and extracellular matrix proteins.
Attraction[edit | edit source]
Axons are attracted to their target areas by specific attractive cues. One well-known family of attractive cues is the netrins, which bind to DCC receptors on axons, guiding them towards sources of high netrin concentration.
Repulsion[edit | edit source]
Conversely, some cues repel axons, preventing them from growing into inappropriate areas. The Slit family of proteins and their Robo receptors are key players in repulsive guidance, ensuring axons do not cross the midline of the nervous system more than once.
Adhesion[edit | edit source]
Cell adhesion molecules (CAMs) facilitate axon guidance by promoting adhesion between the axon and its surrounding environment. This interaction can guide axons along specific pathways via a mechanism known as haptotaxis.
Degradation[edit | edit source]
Extracellular matrix degradation also plays a role in axon guidance, clearing paths for axons to reach their targets. Enzymes such as matrix metalloproteinases are involved in this process, breaking down extracellular matrix components to facilitate axon pathfinding.
Molecular Cues and Receptors[edit | edit source]
Several families of molecular cues and their corresponding receptors are involved in axon guidance, including:
- Ephrins and Eph receptors: Involved in both attractive and repulsive axon guidance.
- Semaphorins and plexin/neuropilin receptors: Primarily mediate repulsive guidance.
- Netrins and DCC/Unc5 receptors: Can mediate both attraction and repulsion.
- Slit proteins and Robo receptors: Mainly involved in repulsive guidance.
Clinical Significance[edit | edit source]
Aberrations in axon guidance processes can lead to a variety of neurological disorders, including congenital mirror movement disorder, horizontal gaze palsy with progressive scoliosis, and certain forms of intellectual disability. Understanding the molecular mechanisms of axon guidance has implications for developing therapeutic strategies for these conditions.
Research and Future Directions[edit | edit source]
Research in axon guidance continues to uncover the complex interplay of molecular cues and their receptors. Advances in genetic engineering, live imaging, and computational biology are providing new insights into how axons navigate in the developing nervous system. Future research aims to further elucidate the molecular mechanisms of axon guidance and their implications for neurodevelopmental and neurodegenerative diseases.
Search WikiMD
Ad.Tired of being Overweight? Try W8MD's physician weight loss program.
Semaglutide (Ozempic / Wegovy and Tirzepatide (Mounjaro / Zepbound) available.
Advertise on WikiMD
WikiMD's Wellness Encyclopedia |
Let Food Be Thy Medicine Medicine Thy Food - Hippocrates |
Translate this page: - East Asian
中文,
日本,
한국어,
South Asian
हिन्दी,
தமிழ்,
తెలుగు,
Urdu,
ಕನ್ನಡ,
Southeast Asian
Indonesian,
Vietnamese,
Thai,
မြန်မာဘာသာ,
বাংলা
European
español,
Deutsch,
français,
Greek,
português do Brasil,
polski,
română,
русский,
Nederlands,
norsk,
svenska,
suomi,
Italian
Middle Eastern & African
عربى,
Turkish,
Persian,
Hebrew,
Afrikaans,
isiZulu,
Kiswahili,
Other
Bulgarian,
Hungarian,
Czech,
Swedish,
മലയാളം,
मराठी,
ਪੰਜਾਬੀ,
ગુજરાતી,
Portuguese,
Ukrainian
WikiMD is not a substitute for professional medical advice. See full disclaimer.
Credits:Most images are courtesy of Wikimedia commons, and templates Wikipedia, licensed under CC BY SA or similar.
Contributors: Prab R. Tumpati, MD