Axonal Protein Synthesis and Degradation Are Necessary for Efficient Growth Cone Regeneration

Verma, Poonam; Chierzi, Sabrina; Codd, A. Mortime; Campbell, Douglas S.; Meyer, Ronald L.; Holt, Christine E.; Fawcett, James W.

doi:10.1523/jneurosci.3073-04.2005

Cited by 363 publications

(353 citation statements)

References 56 publications

(84 reference statements)

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“…An increasing body of evidence indicates that DRG axons contain mRNA and that these axons are translationally competent (Zheng et al, 2001;Verma et al, 2005;Willis et al, 2005). In this study, we have shown that DRG and TG neurons express the RNA binding and transport proteins stau and FMRP and that these proteins localize to DRG axons.…”

Section: Discussionmentioning

confidence: 52%

“…There is now compelling evidence that translation occurs in axons (Koenig, 1967;Nixon, 1980;Koenig, 1991;Eng et al, 1999;Brittis et al, 2002;Piper and Holt, 2004), as mRNA and translational machinery have been localized to CNS (Tiedge et al, 1993;Aronov et al, 2001;Brittis et al, 2002), sympathetic (Olink-Coux andHollenbeck, 1996;Eng et al, 1999) and sensory (Zheng et al, 2001;Li et al, 2004a;Verma et al, 2005;Willis et al, 2005) axons. Moreover, an emerging physiological role for local translation in axons has been described for growth cone guidance and collapse (Zheng et al, 2001;Li et al, 2004a;Verma et al, 2005;Wu et al, 2005).Primary sensory neurons of the dorsal root ganglion (DRG) and trigeminal ganglion (TG) have among the longest axons of the entire neuraxis (greater than one meter for some human DRG neurons). Given the relatively long time interval required for axonal transport of proteins to occur in these neurons following somal synthesis, it would be advantageous if regulable, ondemand protein synthesis would occur at distal sites (for review see: Alvarez et al, 2000;Alvarez, 2001).…”

mentioning

confidence: 99%

“…Extra-somal translation in neurons requires the presence of specific substrates, including mRNA and translational machinery, as well as mechanisms for their transport to these distal sites of protein synthesis. To this end, various components of the translational machinery have been identified in the axons of DRG neurons (Koenig, 1991;Pannese and Ledda, 1991;Verma et al, 2005), and translation itself has been shown to occur in these axons (Koenig, 1991;Zheng et al, 2001;Verma et al, 2005;Willis et al, 2005). However, with the exception of zipcode binding protein 1 (ZBP1), which transports β-actin mRNA to growth cones (Zhang et al, 2001), RNA binding and transport molecules have not been shown to be present in axons, and none, to our knowledge, have been localized to the axons of DRG afferents.…”

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confidence: 99%

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The RNA binding and transport proteins staufen and fragile X mental retardation protein are expressed by rat primary afferent neurons and localize to peripheral and central axons

et al. 2006

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Neuronal proteins have been traditionally viewed as being derived solely from the soma; however, accumulating evidence indicates that dendritic and axonal sites are capable of a more autonomous role in terms of new protein synthesis. Such extra-somal translation allows for more rapid, on-demand regulation of neuronal structure and function than would otherwise be possible. While mechanisms of dendritic RNA transport have been elucidated, it remains unclear how RNA is trafficked into the axon for this purpose. Primary afferent neurons of the dorsal root (DRG) and trigeminal (TG) ganglia have among the longest axons in the neuraxis and such axonal protein synthesis would be advantageous, given the greater time involved for protein trafficking to occur via axonal transport. Therefore, we hypothesized that these primary sensory neurons might express proteins involved in RNA transport. Rat DRG and TG neurons expressed staufen (stau) 1 and 2 (detected at the mRNA level) and stau2 and fragile × mental retardation protein (FMRP; detected at the protein level). Stau2 mRNA was also detected in human TG neurons. Stau2 and FMRP protein were localized to the sciatic nerve and dorsal roots by immunohistochemistry and to dorsal roots by Western blot. Stau2 and FMRP immunoreactivities colocalized with transient receptor potential channel type 1 immunoreactivity in sensory axons of the sciatic nerve and dorsal root, suggesting that these proteins are being transported into the peripheral and central terminals of nociceptive sensory axons. Based on these findings, we propose that stau2 and FMRP proteins are attractive candidates to subserve RNA transport in sensory neurons, linking somal transcriptional events to axonal translation. Keywordsprimary afferent neuron; fragile X mental retardation protein; staufen; RNA binding protein; axonal translation; RNA cargoThe discovery that RNA is transported to synaptic sites by RNA transport proteins, where it can be translated on demand, has provided insight into how neurons handle the rapid synaptic architectural and signaling changes that are known to occur in brain areas associated with learning and memory (Job and Eberwine, 2001;Steward and Worley, 2002;Steward and Schuman, 2003;Martin, 2004;Tiedge, 2005). There is now compelling evidence that translation occurs in axons (Koenig, 1967;Nixon, 1980;Koenig, 1991;Eng et al., 1999;Brittis et al., 2002;Piper and Holt, 2004), as mRNA and translational machinery have been localized to CNS (Tiedge et al., 1993;Aronov et al., 2001;Brittis et al., 2002), sympathetic (Olink-Coux andHollenbeck, 1996;Eng et al., 1999) and sensory (Zheng et al., 2001;Li et al., 2004a;Verma et al., 2005;Willis et al., 2005) axons. Moreover, an emerging physiological role for local translation in axons has been described for growth cone guidance and collapse (Zheng et al., 2001;Li et al., 2004a;Verma et al., 2005;Wu et al., 2005).Primary sensory neurons of the dorsal root ganglion (DRG) and trigeminal ganglion (TG) have among the longest axons of the entire ne...

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Section: Discussionmentioning

confidence: 52%

mentioning

confidence: 99%

mentioning

confidence: 99%

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The RNA binding and transport proteins staufen and fragile X mental retardation protein are expressed by rat primary afferent neurons and localize to peripheral and central axons

et al. 2006

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“…During the development of the nervous system, guided axon growth requires intra-axonal mRNA translation, and it is thus not surprising that local protein synthesis is also crucial for axon regeneration. The formation of a new growth cone after axotomy of developing axons in vitro requires both local protein synthesis and degradation [30], and upon injury of mature axons, mRNAs and protein synthesis machinery are rapidly recruited into axons and intraaxonal translation is upregulated or re-activated within these mature axons [31][32][33][34]. Locally synthesized proteins are required for communication from the injured axons to their soma and likely participate in the formation of the growth bulb at the site of injury [35,36].…”

Section: Regeneration After Nerve Injurymentioning

confidence: 99%

Targeting Axonal Protein Synthesis in Neuroregeneration and Degeneration

Baleriola

Hengst

2015

Neurotherapeutics

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Localized protein synthesis is a mechanism by which morphologically polarized cells react in a spatially confined and temporally acute manner to changes in their environment. During the development of the nervous system intra-axonal protein synthesis is crucial for the establishment of neuronal connections. In contrast, mature axons have long been considered as translationally inactive but upon nerve injury or under neurodegenerative conditions specific subsets of mRNAs are recruited into axons and locally translated. Intra-axonally synthesized proteins can have pathogenic or restorative and regenerative functions, and thus targeting the axonal translatome might have therapeutic value, for example in the treatment of spinal cord injury or Alzheimer's disease. In the case of Alzheimer's disease the local synthesis of the stress response transcription factor activating transcription factor 4 mediates the long-range retrograde spread of pathology across the brain, and inhibition of local Atf4 translation downstream of the integrated stress response might interfere with this spread. Several molecular tools and approaches have been developed to target specifically the axonal translatome by either overexposing proteins locally in axons or, conversely, knocking down selectively axonally localized mRNAs. Many questions about axonal translation remain to be answered, especially with regard to the mechanisms establishing specificity but, nevertheless, targeting the axonal translatome is a promising novel avenue to pursue in the development for future therapies for various neurological conditions.

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“…54,55 The application of the p38 inhibitor significantly eliminated the growth cone formation and axon regeneration in the cultured DRG neurons. 56 These observations indicate an evolutionarily conserved role of the MAP synaptic branch somehow controls the intrinsic growth state of injured neurons and has an inhibitory effect on distal axon regeneration.…”

Section: Model In the Study Of Axon Regenerationmentioning

confidence: 94%

C. elegansas a genetic model to identify novel cellular and molecular mechanisms underlying nervous system regeneration

Chiu

Alqadah

Chuang

et al. 2011

Cell Adhesion & Migration

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Research into conditions that improve axon regeneration has the potential to open a new door for treatment of brain injury caused by stroke and neurodegenerative diseases of aging, such as Alzheimer, by harnessing intrinsic neuronal ability to reorganize itself. Elucidating the molecular mechanisms of axon regeneration should shed light on how this process becomes restricted in the postnatal stage and in the CNS and therefore could provide therapeutic targets for developing strategies to improve axon regeneration in the adult CNS. In this review, we first discuss the general view about nerve regeneration and the advantages of using C. elegans as a model system to study axon regeneration. We then compare the conserved regeneration patterns and molecular mechanisms between C. elegans and vertebrates. Lastly, we discuss the power of femtosecond laser technology and its application in axon regeneration research.

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Axonal Protein Synthesis and Degradation Are Necessary for Efficient Growth Cone Regeneration

Cited by 363 publications

References 56 publications

The RNA binding and transport proteins staufen and fragile X mental retardation protein are expressed by rat primary afferent neurons and localize to peripheral and central axons

The RNA binding and transport proteins staufen and fragile X mental retardation protein are expressed by rat primary afferent neurons and localize to peripheral and central axons

Targeting Axonal Protein Synthesis in Neuroregeneration and Degeneration

C. elegansas a genetic model to identify novel cellular and molecular mechanisms underlying nervous system regeneration

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