Slow axoplasmic transport: a fiction?

Ribosomes have not been observed in axoplasm. This had led to the notions that the perikaryon is the only source of neuronal proteins and that the axoplasm is supplied by a (slow) transport mechanism. However, we question these two notions because they are unable to give an account of real neurones in accordance with the body of biological knowledge. We point out, for example, that the synthetic rate of perikarya or the life span of axoplasmic proteins should be beyond known ranges for animal cells and that a uniform axon is unlikely to result if it is fed from one end. We propose an alternative view for the maintenance of the axon which accepts the controversial idea of axoplasmic synthesis of proteins; as a result, the slow transport becomes unnecessary. Our view gives a qualitative account of the observations dealing with the maintenance of the axoplasm. To account for the phenomenology in a more quantitative fashion, a computer simulation was carried out where the equations of the program provided only for axoplasmic synthesis of proteins; the set of curves retrieved were in good agreement with experimental findings believed so far to support the notion of slow transport. In conclusion, we think that the notion of "slow axoplasmic transport" has been a misinterpretation of good observations because the frame of reference was incomplete in not providing for axoplasmic synthesis of proteins.     

Axonal and presynaptic RNAs are locally transcribed in glial cells.

In the last few years, the long-standing opinion that axonal and presynaptic proteins are exclusively derived from the neuron cell body has been substantially modified by the demonstration that active systems of protein synthesis are present in axons and nerve terminals. These observations have raised the issue of the cellular origin of the involved RNAs, which has been generally attributed to the neuron soma. However, data gathered in a number of model systems indicated that axonal RNAs are synthesized in the surrounding glial cells. More recent experiments on the perfused squid giant axon have definitively proved that axoplasmic RNAs are transcribed in periaxonal glia. Their delivery to the axon occurs by a modulatory mechanism based on the release of neurotransmitters from the stimulated axon and on their binding to glial receptors. In additional experiments on squid optic lobe synaptosomes, presynaptic RNA has been also shown to be synthesized locally, presumably in nearby glia. Together with a wealth of literature data, these observations indicate that axons and nerve terminals are endowed with a local system of gene expression that supports the maintenance and plasticity of these neuronal domains.     

Slow axoplasmic transport under scrutiny

The origin of axoplasmic proteins is central for the biology of axons. For over fifty years axons have been considered unable to synthesize proteins and that cell bodies supply them with proteins by a slow transport mechanism. To allow for prolonged transport times, proteins were assumed to be stable, i.e., not degraded in axons. These are now textbook notions that configure the slow transport model (STM). The aim of this article is to cast doubts on the validity of STM, as a step toward gaining more understanding about the supply of axoplasmic proteins. First, the stability of axonal proteins claimed by STM has been disproved by experimental evidence. Moreover, the evidence for protein synthesis in axons indicates that the repertoire is extensive and the amount sizeable, which disproves the notion that axons are unable to synthesize proteins and that cell bodies supply most axonal proteins. In turn, axoplasmic protein synthesis gives rise to the metabolic model (MM). We point out a few inconsistencies in STM that MM redresses. Although both models address the supply of proteins to axons, so far they have had no crosstalk. Since proteins underlie every conceivable cellular function, it is necessary to re-evaluate in-depth the origin of axonal proteins. We hope this will shape a novel understanding of the biology of axons, with impact on development and maintenance of axons, nerve repair, axonopathies and plasticity, to mention a few fields.     

Axonal protein synthesis and transport

Recent evidence has challenged our ideas about the nature of axonal protein synthesis and transport. Previous metabolic labeling evidence supported the idea that all axonal proteins were synthesized in the cell body and then transported as formed cytoplasmic structures into the axon. Recent evidence suggests that neither the synthesis nor the transport of axonal proteins is that simple. Though most axonal proteins do appear to be synthesized in the neuronal cell body, a small amount of protein appears to be synthesized intra-axonally in some axons. Though small in amount, intra-axonal protein synthesis may be important functionally in some axons. Recent experiments have also begun to identify the presence of a rich array of transport motors in axons, including many members of the kinesin, dynein and myosin families. Progress is being made in identifying which cargoes are being transported by which of these motors. Finally, recent experiments have addressed an old question about whether axoplasmic proteins are transported as filamentous polymers or as soluble components in axons. The answer is that both mechanism can be used in axons. For example, neurofilament protein can move in its particulate or polymeric state, while tubulin can move in its soluble or unpolymerized state.     

IRES‐mediated translation of cofilin regulates axonal growth cone extension and turning

In neuronal development, dynamic rearrangement of actin promotes axonal growth cone extension, and spatiotemporal translation of local mRNAs in response to guidance cues directs axonal growth cone steering, where cofilin plays a critical role. While regulation of cofilin activity is well studied, regulatory mechanism for cofilin mRNA translation in neurons is unknown. In eukaryotic cells, proteins can be synthesized by cap‐dependent or cap‐independent mechanism via internal ribosome entry site (IRES)‐mediated translation. IRES‐mediated translation has been reported in various pathophysiological conditions, but its role in normal physiological environment is poorly understood. Here, we report that 5′UTR of cofilin mRNA contains an IRES element, and cofilin is predominantly translated by IRES‐mediated mechanism in neurons. Furthermore, we show that IRES‐mediated translation of cofilin is required for both axon extension and axonal growth cone steering. Our results provide new insights into the function of IRES‐mediated translation in neuronal development.     

Kinesin‐1/Hsc70‐dependent mechanism of slow axonal transport and its relation to fast axonal transport

Cytoplasmic protein transport in axons (‘slow axonal transport’) is essential for neuronal homeostasis, and involves Kinesin‐1, the same motor for membranous organelle transport (‘fast axonal transport’). However, both molecular mechanisms of slow axonal transport and difference in usage of Kinesin‐1 between slow and fast axonal transport have been elusive. Here, we show that slow axonal transport depends on the interaction between the DnaJ‐like domain of the kinesin light chain in the Kinesin‐1 motor complex and Hsc70, scaffolding between cytoplasmic proteins and Kinesin‐1. The domain is within the tetratricopeptide repeat, which can bind to membranous organelles, and competitive perturbation of the domain in squid giant axons disrupted cytoplasmic protein transport and reinforced membranous organelle transport, indicating that this domain might have a function as a switchover system between slow and fast transport by Hsc70. Transgenic mice overexpressing a dominant‐negative form of the domain showed delayed slow transport, accelerated fast transport and optic axonopathy. These findings provide a basis for the regulatory mechanism of intracellular transport and its intriguing implication in neuronal dysfunction.     

Identification of precursor microRNAs within distal axons of sensory neuron

A set of specific precursor microRNAs (pre‐miRNAs) are reported to localize into neuronal dendrites, where they could be processed locally to control synaptic protein synthesis and plasticity. However, it is not clear whether specific pre‐miRNAs are also transported into distal axons to autonomously regulate intra‐axonal protein synthesis. Here, we show that a subset of pre‐miRNAs, whose mature miRNAs are enriched in axonal compartment of sympathetic neurons, are present in axons of neurons both in vivo and in vitro by quantitative PCR and by in situ hybridization. Some pre‐miRNAs (let 7c‐a and pre‐miRs‐16, 23a, 25, 125b‐1, 433, and 541) showed elevated axonal levels, while others (pre‐miRs‐138‐2, 185, and 221) were decreased in axonal levels following injury. Dicer and KSRP proteins are also present in distal axons, but Drosha is found restricted to the cell body. These findings suggest that specific pre‐miRNAs are selected for localization into distal axons of sensory neurons and are presumably processed to mature miRNAs in response to extracellular stimuli. This study supports the notion that local miRNA biogenesis effectively provides another level of temporal control for local protein synthesis in axons.

     

Growth cone neuropilin‐1 mediates collapsin‐1/sema III facilitation of antero‐ and retrograde axoplasmic transport

Collapsin‐1/SemaIII, a member of the semaphorin family, has been implicated in axonal pathfinding as a repulsive guidance cue. Cellular and molecular mechanisms by which collapsin‐1 exerts its action are not fully understood. Collapsin‐1 induces growth cone collapse via a pathway which may include neuropilin‐1, a cell‐surface collapsin‐1 binding protein, as well as intracellular CRMP‐62 and heterotrimeric G proteins. We previously identified a second action of collapsin‐1, the facilitation of antero‐ and retrograde axoplasmic transport. This response occurs via a mechanism distinct from that causing growth cone collapse. To investigate the possible involvement of neuropilin‐1 in the action of collapsin‐1 on axoplasmic transport, we produced a soluble neuropilin‐1 (sNP‐1) lacking the transmembrane and intracellular region. sNP‐1 progressively displaced the dose–response curve for collapsin‐1 to induce growth cone collapse to higher concentrations. sNP‐1 also inhibited collapsin‐1‐induced augmentation of both antero‐ and retrograde axoplasmic transport. Furthermore, an anti‐neuropilin‐1 antibody blocked the collapsin‐induced axoplasmic transport. These results together indicate that neuropilin‐1 mediates collapsin‐1 action on axoplasmic transport. To visualize collapsin‐1 binding to endogenous neuropilin‐1, we used a truncated collapsin‐1–alkaline phosphatase fusion protein (CAP‐4). CAP‐4 stains the growth cone, neurite, and cell body. However, local application of collapsin‐1 to growth cone but to neither neurite nor cell body promotes axoplasmic transport. Thus, growth cone NP‐1 mediates the facilitatory action of collapsin‐1 on antero‐ and retrograde axoplasmic transport. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 579–589, 1999     

AMP‐activated protein kinase mediates activity‐dependent axon branching by recruiting mitochondria to axon

During development, axons are guided to their target areas and provide local branching. Spatiotemporal regulation of axon branching is crucial for the establishment of functional connections between appropriate pre‐ and postsynaptic neurons. Common understanding has been that neuronal activity contributes to the proper axon branching; however, intracellular mechanisms that underlie activity‐dependent axon branching remain elusive. Here, we show, using primary cultures of the dentate granule cells, that neuronal depolarization‐induced rebalance of mitochondrial motility between anterograde versus retrograde transport underlies the proper formation of axonal branches. We found that the depolarization‐induced branch formation was blocked by the uncoupler p‐trifluoromethoxyphenylhydrazone, which suggests that mitochondria‐derived ATP mediates the observed phenomena. Real‐time analysis of mitochondrial movement defined the molecular mechanisms by showing that the pharmacological activation of AMP‐activated protein kinase (AMPK) after depolarization increased anterograde transport of mitochondria into axons. Simultaneous imaging of axonal morphology and mitochondrial distribution revealed that mitochondrial localization preceded the emergence of axonal branches. Moreover, the higher probability of mitochondrial localization was correlated with the longer lifetime of axon branches. We qualitatively confirmed that neuronal ATP levels decreased immediately after depolarization and found that the phosphorylated form of AMPK was increased. Thus, this study identifies a novel role for AMPK in the transport of axonal mitochondria that underlie the neuronal activity‐dependent formation of axon branches. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 74: 557–573, 2014     

A novel action of collapsin: Collapsin-1 increases antero- and retrograde axoplasmic transport independently of growth cone collapse

Chick collapsin-1, a member of the semaphorin family, has been implicated in axonal pathfinding as a repulsive guidance cue. Collapsin-1 induces growth cone collapse via a pathway which may include CRMP-62 and heterotrimeric G proteins. CRMP-62 protein is related to UNC-33, a nematode neuronal protein required for appropriately directed axonal extension. Mutations in unc-33 affect neural microtubules, the basic cytoskeletal elements for axoplasmic transport. Using computer-assisted video-enhanced differential interference contrast microscopy, we now demonstrate that collapsin-1 potently promotes axoplasmic transport. Collapsin-1 doubles the number of antero- and retrograde-transported organelles but not their velocity. Collapsin-1 decreases the number of stationary organelles, suggesting that the fraction of time during which a particle is moving is increased. Collapsin-1-stimulated transport occurs by a mechanism distinct from that causing growth cone collapse. Pertussis toxin (PTX) but not its B oligomer blocks collapsin-induced growth cone collapse. The holotoxin does not affect collapsin-stimulated axoplasmic transport. Mastoparan and a myelin protein NI-35 induce PTX-sensitive growth cone collapse but do not stimulate axoplasmic transport. These results provide evidence that collapsin has a unique property to activate axonal vesicular transport systems. There are at least two distinct pathways through which collapsin exerts its actions in developing neurons. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 316–328, 1997     

Axon Viability and Mitochondrial Function are Dependent on Local Protein Synthesis in Sympathetic Neurons

(1) Axons contain numerous mRNAs and a local protein synthetic system that can be regulated independently of the cell body. (2) In this study, cultured primary sympathetic neurons were employed, to assess the effect of local protein synthesis blockade on axon viability and mitochondrial function. (3) Inhibition of local protein synthesis reduced newly synthesized axonal proteins by 65% and resulted in axon retraction after 6 h. Acute inhibition of local protein synthesis also resulted in a significant decrease in the membrane potential of axonal mitochondria. Likewise, blockade of local protein transport into the mitochondria by transfection of the axons with Hsp90 C-terminal domain decreased the mitochondrial membrane potential by 65%. Moreover, inhibition of the local protein synthetic system also reduced the ability of mitochondria to restore axonal levels of ATP after KCl-induced depolarization. (4) Taken together, these results indicate that the local protein synthetic system plays an important role in mitochondrial function and the maintenance of the axon.     

Origin of axoplasmic RNA in the squid giant fiber

The origin of axoplasmic RNA in the squid giant fiber was investigated after exposure of the giant axon or of the giant fiber lobe to [3H]uridine. The occurrence of a local process of synthesis was indicated by the accumulation of labeled axoplasmic RNA in isolated axons incubated with the radioactive precursor. Similar results were obtained in vivo after injection of [3H]uridine near the stellate nerve at a sizable distance from the ganglion. Exposure of the giant fiber lobe to [3H]uridine under in vivo and in vitro conditions was followed by the appearance of labeled RNA in the axoplasm and in the axonal sheath. While the latter process is attributed to incorporation of precursor by sheath cells, a sizable fraction of the radioactive RNA accumulating in the axoplasmic is likely to originate from neuronal perikarya by a process of axonal transport.     

Aβ1–42 triggers the generation of a retrograde signaling complex from sentinel mRNAs in axons

Neurons frequently encounter neurodegenerative signals first in their periphery. For example, exposure of axons to oligomeric Aβ_1‐42 is sufficient to induce changes in the neuronal cell body that ultimately lead to degeneration. Currently, it is unclear how the information about the neurodegenerative insult is transmitted to the soma. Here, we find that the translation of pre‐localized but normally silenced sentinel mRNAs in axons is induced within minutes of Aβ_1–42 addition in a Ca²⁺‐dependent manner. This immediate protein synthesis following Aβ_1–42 exposure generates a retrograde signaling complex including vimentin. Inhibition of the immediate protein synthesis, knock‐down of axonal vimentin synthesis, or inhibition of dynein‐dependent transport to the soma prevented the normal cell body response to Aβ_1–42. These results establish that CNS axons react to neurodegenerative insults via the local translation of sentinel mRNAs encoding components of a retrograde signaling complex that transmit the information about the event to the neuronal soma.     

Function and translational regulation of mRNA in developing axons

The capacity to synthesize proteins in axons is limited to early stages of neuronal development, while axons are undergoing elongation and pathfinding. Although the roles of local protein synthesis are not fully understood, it has been implicated in regulating the morphological plasticity of growth cones. Recent studies have identified specific mRNAs that are translated in growth cones in response to specific extracellular signals. In this review, we discuss the functional relevance of axonal protein translation for developing axons, the differences in translational capacity between developing and mature vertebrate axons, and possible pathways governing the specific translational activation of axonal mRNAs.     

Local regulation of the axonal phenotype, a case of merotrophism

In this essay, we show that several anatomical features of the axon, namely, microtubular content, caliber and extension of sprouts, correlate on a local basis with the particular condition of the glial cell, i.e., the anatomy of axons is dynamic, although it is seen usually in its 'normal' state. The occurrence of ribosomes and messenger RNAs in the axon suggests that axoplasmic proteins are most likely synthesized locally, at variance with the accepted notion that they are supplied by the cell body. We propose that the supporting cell (oligodendrocyte or Schwann cell) regulates the axonal phenotype by fine-tuning the ongoing axonal protein synthesis.     

The evolution of the axonal transport toolkit

Neurons are highly polarized cells that critically depend on long‐range, bidirectional transport between the cell body and synapse for their function. This continual and highly coordinated trafficking process, which takes place via the axon, has fascinated researchers since the early 20th century. Ramon y Cajal first proposed the existence of axonal trafficking of biological material after observing that dissociation of the axon from the cell body led to neuronal degeneration. Since these first indirect observations, the field has come a long way in its understanding of this fundamental process. However, these advances in our knowledge have been aided by breakthroughs in other scientific disciplines, as well as the parallel development of novel tools, techniques and model systems. In this review, we summarize the evolution of tools used to study axonal transport and discuss how their deployment has refined our understanding of this process. We also highlight innovative tools currently being developed and how their addition to the available axonal transport toolkit might help to address key outstanding questions.     

Growth cone neuropilin-1 mediates collapsin-1/Sema III facilitation of antero- and retrograde axoplasmic transport.

Collapsin-1/Sema III, a member of the semaphorin family, has been implicated in axonal pathfinding as a repulsive guidance cue. Cellular and molecular mechanisms by which collapsin-1 exerts its action are not fully understood. Collapsin-1 induces growth cone collapse via a pathway which may include neuropilin-1, a cellsurface collapsin-1 binding protein, as well as intracellular CRMP-62 and heterotrimeric G proteins. We previously identified a second action of collapsin-1, the facilitation of antero- and retrograde axoplasmic transport. This response occurs via a mechanism distinct from that causing growth cone collapse. To investigate the possible involvement of neuropilin-1 in the action of collapsin-1 on axoplasmic transport, we produced a soluble neuropilin-1 (sNP-1) lacking the transmembrane and intracellular region. sNP-1 progressively displaced the dose-response curve for collapsin-1 to induce growth cone collapse to higher concentrations. sNP-1 also inhibited collapsin-1-induced augmentation of both antero- and retrograde axoplasmic transport. Furthermore, an anti-neuropilin-1 antibody blocked the collapsin-induced axoplasmic transport. These results together indicate that neuropilin-1 mediates collapsin-1 action on axoplasmic transport. To visualize collapsin-1 binding to endogenous neuropilin-1, we used a truncated collapsin-1-alkaline phosphatase fusion protein (CAP-4). CAP-4 stains the growth cone, neurite, and cell body. However, local application of collapsin-1 to growth cone but to neither neurite nor cell body promotes axoplasmic transport. Thus, growth cone NP-1 mediates the facilitatory action of collapsin-1 on antero- and retrograde axoplasmic transport.     

Tubulin cofactor B plays a role in the neuronal growth cone

Tubulin cofactors, initially identified as alpha-, beta-tubulin folding proteins, are now believed to participate in the complex tubulin biogenesis and degradation routes, and thus to contribute to microtubule functional diversity and dynamics. However, a concrete role of tubulin cofactor B (TBCB) remains to be elucidated because this protein is not required for tubulin biogenesis, and it is apparently not essential for life in any of the organisms studied. In agreement with these data, here we show that TBCB localizes at the transition zone of the growth cones of growing neurites during neurogenesis where it plays a role in microtubule dynamics and plasticity. Gene silencing by means of small interfering RNA segments revealed that TBCB knockdown enhances axonal growth. In contrast, excess TBCB, a feature of giant axonal neuropathy, leads to microtubule depolymerization, growth cone retraction, and axonal damage followed by neuronal degeneration. These results provide an important insight into the understanding of the controlling mechanisms of growth cone microtubule dynamics.