Axoplasm

Axoplasm is the cytoplasm within the axon of a neuron (nerve cell). For some neuronal types this can be more than 99% of the total cytoplasm.^[1]

Axoplasm
Details
Part of	Axon of a nerve
System	Nervous system
Identifiers
Latin	axoplasma
TH	H2.00.06.1.00019
Anatomical terminology [edit on Wikidata]

Axoplasm has a different composition of organelles and other materials than that found in the neuron's cell body (soma) or dendrites. In axonal transport (also known as axoplasmic transport) materials are carried through the axoplasm to or from the soma.

Structure

Axoplasm is composed of various organelles and cytoskeletal elements. The axoplasm contains a high concentration of elongated mitochondria, microfilaments, and microtubules.^[2] Axoplasm lacks much of the cellular machinery (ribosomes and nucleus) required to transcribe and translate complex proteins. As a result, most enzymes and large proteins are transported from the soma through the axoplasm. Axonal transport occurs either by fast or slow transport. Fast transport involves vesicular contents (like organelles) being moved along microtubules by motor proteins at a rate of 50–400mm per day.^[3] Slow axoplasmic transport involves the movement of cytosolic soluble proteins and cytoskeletal elements at a much slower rate of 0.02-0.1mm/d. The precise mechanism of slow axonal transport remains unknown but recent studies have proposed that it may function by means of transient association with the fast axonal transport vesicles.^[4] Though axonal transport is responsible for most organelles and complex proteins present in the axoplasm, recent studies have shown that some translation does occur in axoplasm. This axoplasmic translation is possible due to the presence of localized translationally silent mRNA and ribonuclear protein complexes.^[5]

Function

Damage detection and regeneration

Axoplasm contains both the mRNA and ribonuclearprotein required for axonal protein synthesis. Axonal protein synthesis has been shown to be integral in both neural regeneration and in localized responses to axon damage.^[5] When an axon is damaged, both axonal translation and retrograde axonal transport are required to propagate a signal to the soma that the cell is damaged.^[5]

History

Axoplasm was not a main focus for neurological research until after many years of learning of the functions and properties of squid giant axons. Axons in general were very difficult to study due to their narrow structure and in close proximity to glial cells.^[6] To solve this problem squid axons were used as an animal model due to the relatively vast sized axons compared to humans or other mammals.^[7] These axons were mainly studied to understand action potential, and axoplasm was soon understood to be important in membrane potential.^[8] The axoplasm was at first just thought to be very similar to cytoplasm, but axoplasm plays an important role in transference of nutrients and electrical potential that is generated by neurons.^[9]

It actually proves quite difficult to isolate axons from the myelin that surrounds it,^[10] so the squid giant axon is the focus for many studies that touch on axoplasm. As more knowledge formed from studying the signalling that occurs in neurons, transfer of nutrients and materials became an important topic to research. The mechanisms for the proliferation and sustained electrical potentials were affected by the fast axonal transport system. The fast axonal transport system uses the axoplasm for movement, and contains many non-conductive molecules that change the rate of these electrical potentials across the axon,^[11] but the opposite influence does not occur. The fast axonal transport system is able to function without an axolemma, implying that the electrical potential does not influence the transport of materials through the axon.^[12] This understanding of the relationship of axoplasm regarding transport and electrical potential is critical in the understanding of the overall brain functions.

With this knowledge, axoplasm has become a model for studying varying cell signaling and functions for the research of neurological diseases like Alzheimer's,^[13] and Huntington's.^[14] Fast axonal transport is a crucial mechanism when examining these diseases and determining how a lack of materials and nutrients can influence the progression of neurological disorders.