Netrin-1 signaling for sensory axons: Involvement in sensory axonal development and regeneration

During development, dorsal root ganglion (DRG) neurons extend their axons toward the dorsolateral part of the spinal cord and enter the spinal cord through the dorsal root entry zone (DREZ). After entering the spinal cord, these axons project into the dorsal mantle layer after a “waiting period” of a few days. We revealed that the diffusible axonal guidance molecule netrin-1 is a chemorepellent for developing DRG axons. When DRG axons orient themselves toward the DREZ, netrin-1 proteins derived from the ventral spinal cord prevent DRG axons from projecting aberrantly toward the ventral spinal cord and help them to project correctly toward the DREZ. In addition to the ventrally derived netrin-1, the dorsal spinal cord cells adjacent to the DREZ transiently express netrin-1 proteins during the waiting period. This dorsally derived netrin-1 contributes to the correct guidance of DRG axons to prevent them from invading the dorsal spinal cord. In general, there is a complete lack of sensory axonal regeneration after a spinal cord injury, because the dorsal column lesion exerts inhibitory activities toward regenerating axons. Netrin-1 is a novel candidate for a major inhibitor of sensory axonal regeneration in the spinal cord; because its expression level stays unchanged in the lesion site following injury, and adult DRG neurons respond to netrin-1-induced axon repulsion. Although further studies are required to show the involvement of netrin-1 in preventing the regeneration of sensory axons in CNS injury, the manipulation of netrin-1-induced repulsion in the CNS lesion site may be a potent approach for the treatment of human spinal injuries.Key words: netrin-1, dorsal root ganglion, axon guidance, chemorepellent, Unc5, spinal cord, axon regenerationDeveloping axons navigate to their targets by responding to attractive and repulsive guidance cues working in a contact-dependent or diffusible fashion in their environment (reviewed in ref. ¹). During early development of the primary sensory system, centrally projecting sensory axons from dorsal root ganglion (DRG) neurons extend toward the dorsolateral region of the spinal cord (Fig. 1A and C), where they enter the spinal cord exclusively through the dorsal root entry zone (DREZ), and never orient themselves toward the notochord or the ventral spinal cord (Fig. 1A; reviewed in ref. ²). We previously showed that the notochord but not the ventral spinal cord secretes semaphorin 3A (Sema3A), which is known to be a chemorepellent for DRG axons at early developmental stages (Fig. 1A).³ This is the reason why DRG axons never project toward the notochord. Along the same line, it is highly possible that the ventral spinal cord may secrete some chemorepulsive cue other than Sema3A for DRG axons.Open in a separate windowFigure 1Netrin-1 plays a critical role in sensory axonal guidance as an axon chemorepellent. (A) A schematic diagram of a thoracic transverse section of an E10 mouse embryo, summarizing the possible mechanism of netrin-1 action in early DRG axonal guidance. When DRG axons project toward the DREZ in the dorsal spinal cord (dSC), ventrally derived netrin-1 chemorepels DRG axons to prevent them from orienting aberrantly toward the ventral spinal cord (vSC) (upper). NC; notochord. In netrin-1-deficient embryos, some DRG axons misorient themselves toward the ventral spinal cord, because of the absence of netrin-1 proteins in the ventral spinal cord (lower). (B) At E12.5 when DRG axons grow to the marginal zone of the spinal cord longitudinally (arrows) to form the dorsal funiculus (DF), netrin-1 proteins are transiently expressed in a subpopulation of dorsal spinal cord cells adjacent to the dorsal funiculus (upper). In netrin-1-deficient embryos, the dorsal funiculus is disorganized because DRG axons are no longer waiting for invading the dorsal mantle layer (lower). (C) Gain-of-function experiments by electroporation confirm the repulsive activity of netrin-1 toward DRG axons. When netrin-1 is misexpressed in the dorsal spinal cord, the number of DRG axons that enter the DREZ is significantly reduced compared with the control, because some DRG axons fail to project toward the DREZ and turn in the wrong direction.After entering the spinal cord, DRG axons grow to the marginal zone of the spinal cord longitudinally to form the dorsal funiculus without projecting to the dorsal mantle layer for a few days (this delay of the axonal projection to the mantle layer is referred to as the ‘waiting period;’ Fig. 1B). A few days later, proprioceptive afferents of DRGs begin to send collaterals into the dorsal layers, and cutaneous afferents project ventrally through the dorsal layers.⁴ This evidence raises the possibility that some repulsive cues transiently prevent the collaterals of DRGs from penetrating the dorsal spinal cord during this waiting period.Netrins are a family of secreted proteins that play a key role in axonal guidance, cell migration, morphogenesis and angiogenesis.⁵ Netrin-1 is a bifunctional axonal guidance cue, attracting some axons including commissural axons via the Deleted in Colorectal Cancer (DCC) receptor and repelling others via Unc5 receptors (reviewed in ref. ⁶). However, it has not been clear whether netrin-1 plays a role in sensory axonal guidance during development.Several observations strongly suggest a role for netrin-1 in DRG axonal guidance as a repulsive guidance cue during development.^7,8 First, in the mouse embryo at embryonic day (E) 10–11.⁵ when many DRG axons orient themselves to reach the DREZ, netrin-1 is strongly expressed in the floor plate of the ventral spinal cord but not in the dorsal spinal cord (Fig. 1A). Second, at E12.5 when DRG neurons extend their axons longitudinally along the dorsolateral margin of the spinal cord, netrin-1 is expressed in the dorsolateral region adjacent to the DREZ (Fig. 1B), but its expression is down-regulated in the dorsal spinal cord at E13.5 when many collaterals have entered the mantle layer. Third, repulsive netrin-1 receptor Unc5c is expressed in the DRG neurons during development.These observations motivated us to explore whether netrin-1/Unc5c signaling contributes to DRG axonal guidance. We used cell and tissue cultures combined with tissues from netrin-1-deficient mice. We clearly showed that netrin-1 exerts a chemorepulsive activity toward developing DRG axons and that the ventral spinal cord-derived repulsive activity depends on netrin-1 in vitro.⁸ Additional evidence for a chemorepulsive role of netrin-1 came from the observation of DRG axonal trajectories in netrin-1-deficient mice.^7,8 In netrin-1-deficient embryos at E10, we showed that some DRG axons became misoriented toward the ventral spinal cord, probably because of the absence of netrin-1 proteins in the ventral spinal cord (Fig. 1A). In addition, at E12.5 when DRG axons grow to the marginal zone of the spinal cord longitudinally to form the dorsal funiculus, the dorsal funiculus is disorganized in netrin-1-deficient embryos, because in the absence of netrin-1 DRG axons are not waiting for invading the dorsal mantle layer adjacent to the dorsal funiculus (Fig. 1B). Gain-of-function experiments further confirmed the repulsive activity of netrin-1 toward DRG axons (Fig. 1C). These lines of evidence lead us to the conclusion that dorsally derived netrin-1 plays an important role in providing the ‘waiting period’ for extension of collaterals from sensory afferents and that ventrally derived netrin-1 prevents sensory axons from misorienting themselves toward the ventral spinal cord.At later developmental stages (E13.5), DRG axons still possess a weak responsiveness to the chemorepulsive activity of netrin-1 in vitro.⁸ In addition, both postnatal and adult DRG neurons respond to netrin-1-induced axon inhibition.⁹ Consistent with these results, DRG neurons at not only later developmental stages (E13.5) but also postnatal stages express the repulsion-mediating netrin-1 receptor Unc5c.^8,9Generally, lesioning of the dorsal column projection of sensory axons results in a complete lack of regeneration. The possible explanation for the complete lack of regeneration is that the environment, the lesion site itself and/or oligodendrocytes adjacent to the lesion, may be non-permissive for regenerating axons.¹⁰ Sema3A and chondroitin sulfate proteoglycans (CSPGs) are candidates as major inhibitors of sensory axonal regeneration in the spinal cord, because they are expressed in the lesion site and can inhibit DRG axonal growth in vitro.^3,11–14 Recently, Kaneko et al. showed that a selective inhibitor of Sema3A also enhances axonal regeneration and functional recovery in a subpopulation of sensory neurons after lesioning of the dorsal column.¹² More recently, McMahon''s group clearly demonstrated that enzymatic degradation of CSPGs on the dorsal column lesion of the spinal cord promotes sensory axonal regeneration and functional recovery.^13,14 Although these treatments greatly improved functional recovery, complete sensory axonal growth and functional recovery have not been yet achieved after the spinal cord injury. To promote further recovery of sensory axonal regeneration in the CNS, we should focus on other candidate inhibitors of CNS injury sites.Following spinal cord injury, the expression of the attraction- mediating netrin-1 receptor DCC decreases, while the expression level of the repulsive receptor Unc5c returns to normal.¹⁵ Levels of netrin-1 expression also stay unchanged in neurons and oligodendrocytes adjacent to the lesion site. Together with the in vitro evidence described above, these data strongly suggest a possible role for netrin-1 as a novel inhibitor of CNS myelin for regenerating DRG axons in the dorsal column-lesioned spinal cord. Further studies will be required to show directly the functional recovery of sensory axons in the spinal cord by perturbation of netrin-1 in and around the lesion site after spinal cord injury.     

Netrin-1 signaling dampens inflammatory peritonitis

Previous studies implicated the anti-inflammatory potential of the adenosine 2B receptor (A2BAR). A2BAR activation is achieved through adenosine, but this is limited by its very short t(1/2). To further define alternative adenosine signaling, we examined the role of netrin-1 during acute inflammatory peritonitis. In this article, we report that animals with endogenous repression of netrin-1 (Ntn1(+/-)) demonstrated increased cell count, increased peritoneal cytokine concentration, and pronounced histological changes compared with controls in a model of zymosan A peritonitis. Exogenous netrin-1 significantly decreased i.p. inflammatory changes. This effect was not present in animals with deletion of A2BAR (A2BAR(-/-)). A2BAR(-/-) animals demonstrated no change in cell count, i.p. cytokine concentration, or histology in response to netrin-1 injection. These data strengthen the role of netrin-1 as an immunomodulatory protein exerting its function in dependence of the A2BAR and further define alternative adenosine receptor signaling.     

Eph:ephrin-B1 forward signaling controls fasciculation of sensory and motor axons

Axon fasciculation is one of the processes controlling topographic innervation during embryonic development. While axon guidance steers extending axons in the accurate direction, axon fasciculation allows sets of co-extending axons to grow in tight bundles. The Eph:ephrin family has been involved both in axon guidance and fasciculation, yet it remains unclear how these two distinct types of responses are elicited. Herein we have characterized the role of ephrin-B1, a member of the ephrinB family in sensory and motor innervation of the limb. We show that ephrin-B1 is expressed in sensory axons and in the limb bud mesenchyme while EphB2 is expressed in motor and sensory axons. Loss of ephrin-B1 had no impact on the accurate dorso-ventral innervation of the limb by motor axons, yet EfnB1 mutants exhibited decreased fasciculation of peripheral motor and sensory nerves. Using tissue-specific excision of EfnB1 and in vitro experiments, we demonstrate that ephrin-B1 controls fasciculation of axons via a surround repulsion mechanism involving growth cone collapse of EphB2-expressing axons. Altogether, our results highlight the complex role of Eph:ephrin signaling in the development of the sensory-motor circuit innervating the limb.     

Netrin-3 protein is localized to the axons of motor, sensory, and sympathetic neurons

The netrin family of axon guidance cues has been shown to play a pivotal role in the guidance of a variety of axon projections during embryonic development, both in the vertebrate and invertebrate. While the guidance potential of netrin-1 has been examined in depth in many regions of the developing mouse brain very little information is available on the expression and activity of netrin-3. Here we show that the netrin-3 protein is present on motor neurons and subpopulations of neurons within sensory and sympathetic ganglia. Moreover, significant levels of netrin-3 protein were found to be associated with the axons projecting from these neurons suggesting a role for netrin-3 in axon pathfinding and fasciculation within the peripheral nervous system.     

PlexinA1 signaling directs the segregation of proprioceptive sensory axons in the developing spinal cord

As different classes of sensory neurons project into the CNS, their axons segregate and establish distinct trajectories and target zones. One striking instance of axonal segregation is the projection of sensory neurons into the spinal cord, where proprioceptive axons avoid the superficial dorsal horn-the target zone of many cutaneous afferent fibers. PlexinA1 is a proprioceptive sensory axon-specific receptor for sema6C and sema6D, which are expressed in a dynamic pattern in the dorsal horn. The loss of plexinA1 signaling causes the shafts of proprioceptive axons to invade the superficial dorsal horn, disrupting the organization of cutaneous afferents. This disruptive influence appears to involve the intermediary action of oligodendrocytes, which accompany displaced proprioceptive axon shafts into the dorsal horn. Our findings reveal a dedicated program of axonal shaft positioning in the mammalian CNS and establish a role for plexinA1-mediated axonal exclusion in organizing the projection pattern of spinal sensory afferents.     

Netrin-1 and axonal guidance: signaling and asymmetrical translation

More than 10 years after its initial discovery, netrin-1 - the first described chimioattractive molecule controlling the guidance of the commissural axons - has recently known a unsuspected wave of interest because of its implication in the development of the nervous system but also, more recently, fot its role in angiogenesis and tumorigenesis. Because, of a series of recent publications on netrin-1 signaling, we propose here to describe the recent insight in netrin-1 signaling via its main receptor DCC (deleted in colorectal cancer), and the recent discovery that netrin controls the assymetric distribution of beta-actin in the growth cone. Thus, it seems that netrin-1, but also the neurotrophic factor BDNF, controls acute growth cone responses such as collapse and turning by the regulation of localized protein translation, such as beta-actin. This process involves both transport of beta-actin mRNA, bound to Vg1RBP, to specific locations, and mRNA translation upon stimulation by local activation of the translation initiation regulator eIF-4E-binding protein 1. Indeed, Netrin-1 induces the movement of Vg1RBP granules into filopodia, and triggers a polarized increase in beta-actin translation on the near side of the growth cone before growth cone turning. The binding of BDNF to its receptor Trk has a similar effect for growth cone attraction, althought it is differentially regulated. Thus, this asymetrically synthesized beta-actin may direct actin polymerization and consequently the migration of the growth cone toward the cue.     

cGMP-mediated signaling via cGKIalpha is required for the guidance and connectivity of sensory axons

Previous in vitro studies using cGMP or cAMP revealed a cross-talk between signaling mechanisms activated by axonal guidance receptors. However, the molecular elements modulated by cyclic nucleotides in growth cones are not well understood. cGMP is a second messenger with several distinct targets including cGMP-dependent protein kinase I (cGKI). Our studies indicated that the alpha isoform of cGKI is predominantly expressed by sensory axons during developmental stages, whereas most spinal cord neurons are negative for cGKI. Analysis of the trajectories of axons within the spinal cord showed a longitudinal guidance defect of sensory axons within the developing dorsal root entry zone in the absence of cGKI. Consequently, in cGKI-deficient mice, fewer axons grow within the dorsal funiculus of the spinal cord, and lamina-specific innervation, especially by nociceptive sensory neurons, is strongly reduced as deduced from anti-trkA staining. These axon guidance defects in cGKI-deficient mice lead to a substantial impairment in nociceptive flexion reflexes, shown using electrophysiology. In vitro studies revealed that activation of cGKI in embryonic dorsal root ganglia counteracts semaphorin 3A-induced growth cone collapse. Our studies therefore reveal that cGMP signaling is important for axonal growth in vivo and in vitro.     

Type III Nrg1 back signaling enhances functional TRPV1 along sensory axons contributing to basal and inflammatory thermal pain sensation

Type III Nrg1, a member of the Nrg1 family of signaling proteins, is expressed in sensory neurons, where it can signal in a bi-directional manner via interactions with the ErbB family of receptor tyrosine kinases (ErbB RTKs). Type III Nrg1 signaling as a receptor (Type III Nrg1 back signaling) can acutely activate phosphatidylinositol-3-kinase (PtdIns3K) signaling, as well as regulate levels of α7* nicotinic acetylcholine receptors, along sensory axons. Transient receptor potential vanilloid 1 (TRPV1) is a cation-permeable ion channel found in primary sensory neurons that is necessary for the detection of thermal pain and for the development of thermal hypersensitivity to pain under inflammatory conditions. Cell surface expression of TRPV1 can be enhanced by activation of PtdIns3K, making it a potential target for regulation by Type III Nrg1. We now show that Type III Nrg1 signaling in sensory neurons affects functional axonal TRPV1 in a PtdIns3K-dependent manner. Furthermore, mice heterozygous for Type III Nrg1 have specific deficits in their ability to respond to noxious thermal stimuli and to develop capsaicin-induced thermal hypersensitivity to pain. Cumulatively, these results implicate Type III Nrg1 as a novel regulator of TRPV1 and a molecular mediator of nociceptive function.     

Phosphorylation of DCC by Fyn mediates Netrin-1 signaling in growth cone guidance

Netrin-1 acts as a chemoattractant molecule to guide commissural neurons (CN) toward the floor plate by interacting with the receptor deleted in colorectal cancer (DCC). The molecular mechanisms underlying Netrin-1-DCC signaling are still poorly characterized. Here, we show that DCC is phosphorylated in vivo on tyrosine residues in response to Netrin-1 stimulation of CN and that the Src family kinase inhibitors PP2 and SU6656 block both Netrin-1-dependent phosphorylation of DCC and axon outgrowth. PP2 also blocks the reorientation of Xenopus laevis retinal ganglion cells that occurs in response to Netrin-1, which suggests an essential role of the Src kinases in Netrin-1-dependent orientation. Fyn, but not Src, is able to phosphorylate the intracellular domain of DCC in vitro, and we demonstrate that Y1418 is crucial for DCC axon outgrowth function. Both DCC phosphorylation and Netrin-1-induced axon outgrowth are impaired in Fyn(-/-) CN and spinal cord explants. We propose that DCC is regulated by tyrosine phosphorylation and that Fyn is essential for the response of axons to Netrin-1.     

Loss of floor plate Netrin-1 impairs midline crossing of corticospinal axons and leads to mirror movements

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Netrin-1: diversity in development

In 1990, the discovery of three Caenorhabditis elegans genes (unc5, unc6, unc40) involved in pioneer axon guidance and cell migration marked a significant advancement in neuroscience research [Hedgecock EM, Culotti JG, Hall DH. The unc-5, unc-6, and unc-40 genes guide circumferential migrations of pioneer axons and mesodermal cells on the epidermis in C. elegans. Neuron 1990;4:61-85]. The importance of this molecular guidance system was exemplified in 1994, when the vertebrate orthologue of Unc6, Netrin-1, was discovered to be a key guidance cue for commissural axons projecting toward the ventral midline in the rodent embryonic spinal cord [Serafini T, Kennedy TE, Galko MJ, Mirzayan C, Jessell TM, Tessier-Lavigne M. The netrins define a family of axon outgrowth-promoting proteins homologous to C. elegans UNC-6. Cell 1994;78:409-424]. Since then, Netrin-1 has been found to be a critical component of embryonic development with functions in axon guidance, cell migration, morphogenesis and angiogenesis. Netrin-1 also plays a role in the adult brain, suggesting that manipulating netrin signals may have novel therapeutic applications.     

Consequences of slow Wallerian degeneration for regenerating motor and sensory axons.

The time course of Wallerian degeneration in the tibial and saphenous nerves was compared in Balb/c mice and mice of the C57BL/Ola strain (Lunn et al., 1989). Axons, particularly myelinated ones, in nerves of C57BL/Ola mice are very slow to degenerate, many still being present 3 weeks after axotomy. Nuclear numbers in the distal stump peak much later and do not reach the levels found in Balb/c mice; debris removal is very slow, and Schwann cell numbers only rise slightly above normal levels in the long term. Regeneration was investigated electrophysiologically and by electron microscopy (EM). Myelinated sensory axons regenerated slowly and incompletely compared with motor ones which were only slightly slowed after nerve crush (although they were significantly hindered after nerve section). Total myelinated axon numbers were still some 20% less than normal even after 200 days in sensory nerves. Even after all axons had degenerated in C57BL/Ola mice, regeneration rates of neither myelinated nor unmyelinated sensory axons reached those achieved in Balb/c mice. It is concluded that while regeneration can eventually proceed slowly when Wallerian degeneration is much delayed, the usual rapid time course of Wallerian degeneration is necessary if axons, particularly sensory ones, are to regenerate at optimal rates and to maximum extent. While local obstruction to axon growth probably impedes the early phase of regeneration in C57BL/Ola mice, it seems possible that a lack of adequate early signals affects regeneration permanently by minimizing the cell body reaction to injury.     

Neuregulin 1 type III/ErbB signaling is crucial for Schwann cell colonization of sympathetic axons

Analysis of Schwann cell (SC) development has been hampered by the lack of growing axons in many commonly used in vitro assays. As a consequence, the molecular signals and cellular dynamics of SC development along peripheral axons are still only poorly understood. Here we use a superior cervical ganglion (SCG) explant assay, in which axons elongate after treatment with nerve growth factor (NGF). Migration as well as proliferation and apoptosis of endogenous SCG-derived SCs along sympathetic axons were studied in these cultures using pharmacological interference and time-lapse imaging. Inhibition of ErbB receptor tyrosine kinases leads to reduced SC proliferation, increased apoptosis and thereby severely interfered with SC migration to distal axonal sections and colonization of axons. Furthermore we demonstrate that SC colonization of axons is also strongly impaired in a specific null mutant of an ErbB receptor ligand, Neuregulin 1 (NRG1) type III. Taken together, using a novel SC development assay, we demonstrate that NRG1 type III serves as a critical axonal signal for glial ErbB receptors that drives SC development along sympathetic axons.     

The neural adhesion molecule TAG-1 modulates responses of sensory axons to diffusible guidance signals

When the axons of primary sensory neurons project into the embryonic mammalian spinal cord, they bifurcate and extend rostrocaudally before sending collaterals to specific laminae according to neuronal subclass. The specificity of this innervation has been suggested to be the result both of differential sensitivity to chemorepellants expressed in the ventral spinal cord and of the function of Ig-like neural cell adhesion molecules in the dorsal horn. The relationship between these mechanisms has not been addressed. Focussing on the pathfinding of TrkA+ NGF-dependent axons, we demonstrate for the first time that their axons project prematurely into the dorsal horn of both L1 and TAG-1 knockout mice. We show that axons lacking TAG-1, similar to those lacking L1, are insensitive to wild-type ventral spinal cord (VSC)-derived chemorepellants, indicating that adhesion molecule function is required in the axons, and that this loss of response is explained in part by loss of response to Sema3A. We present evidence that TAG-1 affects sensitivity to Sema3A by binding to L1 and modulating the endocytosis of the L1/neuropilin 1 Sema3A receptor complex. However, TAG-1 appears to affect sensitivity to other VSC-derived chemorepellants via an L1-independent mechanism. We suggest that this dependence of chemorepellant sensitivity on the functions of combinations of adhesion molecules is important to ensure that axons project via specific pathways before extending to their final targets.     

Target-derived GFRalpha1 as an attractive guidance signal for developing sensory and sympathetic axons via activation of Cdk5

Immobilized and diffusible molecular cues regulate axon guidance during development. GFRalpha1, a GPI-anchored receptor for GDNF, is expressed as both membrane bound and secreted forms by accessory nerve cells and peripheral targets of developing sensory and sympathetic neurons during the period of target innervation. A relative deficit of GFRalpha1 in developing axons allows exogenous GFRalpha1 to capture GDNF and present it for recognition by axonal c-Ret receptors. Exogenous GFRalpha1 potentiates neurite outgrowth and acts as a long-range directional cue by creating positional information for c-Ret-expressing axons in the presence of a uniform concentration of GDNF. Soluble GFRalpha1 prolongs GDNF-mediated activation of cyclin-dependent kinase 5 (Cdk5), an event required for GFRalpha1-induced neurite outgrowth and axon guidance. Together with GDNF, target-derived GFRalpha1 can function in a non-cell-autonomous fashion as a chemoattractant cue with outgrowth promoting activity for peripheral neurons.     

Type III neuregulin 1 regulates pathfinding of sensory axons in the developing spinal cord and periphery

Sensory axons must develop appropriate connections with both central and peripheral targets. Whereas the peripheral cues have provided a classic model for neuron survival and guidance, less is known about the central cues or the coordination of central and peripheral connectivity. Here we find that type III Nrg1, in addition to its known effect on neuron survival, regulates axon pathfinding. In type III Nrg1(-/-) mice, death of TrkA(+) nociceptive/thermoreceptive neurons was increased, and could be rescued by Bax elimination. In the Bax and type III Nrg1 double mutants, axon pathfinding abnormalities were seen for TrkA(+) neurons both in cutaneous peripheral targets and in spinal cord central targets. Axon guidance phenotypes in the spinal cord included penetration of axons into ventral regions from which they would normally be repelled by Sema3A. Accordingly, sensory neurons from type III Nrg1(-/-) mice were unresponsive to the repellent effects of Sema3A in vitro, which might account, at least in part, for the central projection phenotype, and demonstrates an effect of type III Nrg1 on guidance cue responsiveness in neurons. Moreover, stimulation of type III Nrg1 back-signaling in cultured sensory neurons was found to regulate axonal levels of the Sema3A receptor neuropilin 1. These results reveal a molecular mechanism whereby type III Nrg1 signaling can regulate the responsiveness of neurons to a guidance cue, and show that type III Nrg1 is required for normal sensory neuron survival and axon pathfinding in both central and peripheral targets.     

Netrin-1-independent adenosine A2b receptor activation regulates the response of axons to netrin-1 by controlling cell surface levels of UNC5A receptors

Growth cone response to the bifunctional guidance cue netrin-1 is regulated by the activity of intracellular signaling intermediates such as protein kinase C-alpha (PKCα) and adenylyl cyclase. Among the diverse cellular events these enzymes regulate is receptor trafficking. Netrin-1, itself, may govern the activity of these signaling intermediates, thereby regulating axonal responses to itself. Alternatively, other ligands, such as activators of G protein-coupled receptors, may regulate responses to netrin-1 by governing these signaling intermediates. Here, we investigate the mechanisms controlling activation of PKCα and the subsequent downstream regulation of cell surface UNC5A receptors. We report that activation of adenosine receptors by adenosine analogs, or activation of the putative netrin-1 receptor, the G protein-coupled receptor adenosine A2b receptor (A2bR) results in PKCα-dependent removal of UNC5A from the cell surface. This decrease in cell surface UNC5A reduces the number of growth cones that collapse in response to netrin-1 and converts repulsion to attraction. We show these A2bR-mediated alterations in axonal response are not because of netrin-1 because netrin-1 neither binds A2bR, as assayed by protein overlay, nor stimulates PKCα-dependent UNC5A surface loss. Our results demonstrate that netrin-1-independent A2bR signaling governs the responsiveness of a neuron to netrin-1 by regulating the levels of cell surface UNC5A receptor.     

Reduced number of unmyelinated sensory axons in peripherin null mice

Peripherin is a type III intermediate filament (IF) abundantly expressed in developing neurons, but in the adult, it is primarily found in neurons extending to the peripheral nervous system. It has been suggested that peripherin may play a role in axonal elongation and/or cytoskeletal stabilization during development and regeneration. To further clarify the function of peripherin, we generated and characterized mice with a targeted disruption of the peripherin gene. The peripherin null mice were viable, reproduced normally and did not exhibit overt phenotypes. Microscopic analysis revealed no gross morphological defects in the ventral and dorsal roots, spinal cord, retina and gut, but protein analyses showed increased levels of the type IV IF alpha-internexin in ventral roots of peripherin null mice. Whereas the number and caliber of myelinated motor and sensory axons in the L5 roots remained unchanged in peripherin knockout mice, there was a substantial reduction ( approximately 34%) in the number of L5 unmyelinated sensory fibers that correlated with a decreased binding of the lectin IB4. These results demonstrate a requirement of peripherin for the proper development of a subset of sensory neurons.     

A quantitative study of microtubules in motor and sensory axons

The number, density and distribution of microtubules were compared in the myelinated motor and sensory axons of the spinal roots of lizard (Lacerta muralis). In both motor and sensory axons the average number and density of microtubules were found to be related to the axonal size: the average number of microtubules rose, while the microtubular density decreased with an increase in the cross-sectional area of the axon. More precisely, a linear relationship was observed between the logarithm of the microtubular density and the cross-sectional area of the axon. No significant differences in the microtubular number and density were found between motor and sensory axons of corresponding size. Microtubules were unevenly distributed throughout the cross section of both motor and sensory axons. In particular, a nonaccidental association between microtubules and mitochondria was found in both axon types.