Growth-cone collapse: too much of a good thing?

Adult Mouse Retina Explants: From ex vivo to in vivo Model of Central Nervous System Injuries

In mammals, adult neurons fail to regenerate following any insult to adult central nervous system (CNS), which leads to a permanent and irreversible loss of motor and cognitive functions. For a long time, much effort has been deployed to uncover mechanisms of axon regeneration in the CNS. Even if some cases of functional recovery have been reported, there is still a discrepancy regarding the functionality of a neuronal circuit upon lesion. Today, there is a need not only to identify new molecules implicated in adult CNS axon regeneration, but also to decipher the fine molecular mechanisms associated with regeneration failure. Here, we propose to use cultures of adult retina explants to study all molecular and cellular mechanisms that occur during CNS regeneration. We show that adult retinal explant cultures have the advantages to (i) recapitulate all the features observed in vivo, including axon regeneration induced by intrinsic factors, and (ii) be an ex vivo set-up with high accessibility and many downstream applications. Thanks to several examples, we demonstrate that adult explants can be used to address many questions, such as axon guidance, growth cone formation and cytoskeleton dynamics. Using laser guided ablation of a single axon, axonal injury can be performed at a single axon level, which allows to record early and late molecular events that occur after the lesion. Our model is the ideal tool to study all molecular and cellular events that occur during CNS regeneration at a single-axon level, which is currently not doable in vivo. It is extremely valuable to address unanswered questions of neuroprotection and neuroregeneration in the context of CNS lesion and neurodegenerative diseases.

The making of successful axonal regeneration: Genes, molecules and signal transduction pathways

Unlike its central counterpart, the peripheral nervous system is well known for its comparatively good potential for regeneration following nerve fiber injury. This ability is mirrored by the de novo expression or upregulation of a wide variety of molecules including transcription factors, growth-stimulating substances, cell adhesion molecules, intracellular signaling enzymes and proteins involved in regulating cell-surface cytoskeletal interactions, that promote neurite outgrowth in cultured neurons. However, their role in vivo is less known. Recent studies using neutralizing antibodies, gene inactivation and overexpression techniques have started to shed light on those endogenous molecules that play a key role in axonal outgrowth and the process of successful functional repair in the injured nervous system. The aim of the current review is to provide a summary on this rapidly growing field and the experimental techniques used to define the specific effects of candidate signaling molecules on axonal regeneration in vivo.

Intracellular Calcium Increases in Growth Cones Exposed to Tetracaine

Neurotoxicity of local anesthetics has been reported for both matured and growing neurons. In the present study, we examined if tetracaine increases Ca(2+) concentration during growth cone collapse. Intracellular Ca(2+) concentration was measured by fura 2/AM after exposure to tetracaine. Tetracaine (1-2 mM) induced increases in intra-growth cone Ca(2+) concentration (P < 0.01). The Ca(2+) hot spot was expanded into the neurite from the periphery towards the cell body. When tetracaine was applied to growth cones in Ca(2+) free media, the increase was minor. However, tetracaine induced growth cone collapse even in the culture media, which did not contain Ca(2+). Ni(2+) (100 microM; a general Ca(2+) channel inhibitor) and BAPTA-AM (5 microM; intracellular Ca(2+) chelator) could not inhibit growth cone collapse induced by 1-2 mM tetracaine. Tetracaine (>1 mM) induces collapse and Ca(2+) increase at growth cones simultaneously; however, these two phenomena might be provoked independently.

IMPLICATIONS

Tetracaine induced intracellular Ca(2+) increases and growth cone collapse in dorsal root ganglion neurons. The Ca(2+) hot spot in the growth cone expanded into the neurite from periphery towards the cell body.

Neurotrophic factors can partially reverse morphological changes induced by mepivacaine and bupivacaine in developing sensory neurons

Both bupivacaine and mepivacaine induce morphological changes in growing neurons. We designed this study to investigate the role of some neurotrophic factors (NTFs) in supporting developing neurons exposed to the deleterious effects of these drugs. Dorsal root ganglia were isolated from chick embryos and exposed to either bupivacaine or mepivacaine. After 60 min of exposure, the culture media were replaced with fresh culture media free from local anesthetics. NTFs-brain-derived NTF, glial-derived NTF, or neurotrophin-3-were added to the replacement media, and the cells were examined up to 48 h after the washout. The growth cone collapse assay was applied by a quantitative method of assessment. When the replacement media were not supported by any NTF, the growth cone collapse values were significantly larger than the control values at 20 h after the washout of mepivacaine and 48 h after the washout of either bupivacaine or mepivacaine (P < 0.05). However, when any of the NTFs were used, the collapsing activity was significantly attenuated, and growth cone collapse values showed no statistically significant differences in comparison with the control values at these time points (P > 0.05). We conclude that several NTFs support the recovery of neurons after exposure to local anesthetics. The supporting effects of NTFs on the reversibility of mepivacaine-induced collapse tended to be more obvious than those seen after the bupivacaine washout.

IMPLICATIONS

Three neurotrophic factors (NTFs) can partially support the reversibility of mepivacaine- and bupivacaine-induced growth cone collapse in growing primary cultured sensory neurons. The effect of NTFs is more apparent after mepivacaine than after bupivacaine washout.

The neurotoxicity of local anesthetics on growing neurons: a comparative study of lidocaine, bupivacaine, mepivacaine, and ropivacaine

Local anesthetics can be neurotoxic. To test the hypothesis that exposure to local anesthetics produces morphological changes in growing neurons and to compare this neurotoxic potential between different local anesthetics, we performed in vitro cell biological experiments with isolated dorsal root ganglion neurons from chick embryos. The effects of lidocaine, bupivacaine, mepivacaine, and ropivacaine were examined microscopically and quantitatively assessed using the growth cone collapse assay. We observed that all local anesthetics produced growth cone collapse and neurite degeneration. However, they showed significant differences in the dose response. The IC(50) values were approximately, 10(-2.8) M for lidocaine, 10(-2.6) M for bupivacaine, 10(-1.6) M for mepivacaine, and 10(-2.5) M for ropivacaine at 15 min exposure. Some reversibility was observed after replacement of the media. At 20 h after washout, bupivacaine and ropivacaine showed insignificant percentage growth cone collapse in comparison to their control values whereas those for lidocaine and mepivacaine were significantly higher than the control values. Larger concentrations of the nerve growth factor (NGF) did not improve this reversibility. In conclusion, local anesthetics produced morphological changes in growing neurons with significantly different IC(50). The reversibility of these changes differed among the four drugs and was not influenced by the NGF concentration.

IMPLICATIONS

Local anesthetics induce growth cone collapse and neurite degeneration in the growing neurons. Mepivacaine was safer than lidocaine, bupivacaine, and ropivacaine for the primary cultured chick neurons.

Target cell contact suppresses neurite outgrowth from soma-soma paired Lymnaea neurons

Neurite extension from developing and/or regenerating neurons is terminated on contact with their specific synaptic partner cells. However, a direct relationship between the effects of target cell contact on neurite outgrowth suppression and synapse formation has not yet been demonstrated. To determine whether physical/synaptic contacts affect neurite extension from cultured cells, we utilized soma-soma synapses between the identified Lymnaea neurons. A presynaptic cell (right pedal dorsal 1, RPeD1) was paired either with its postsynaptic partner cells (visceral dorsal 4, VD4, and Visceral dorsal 2, VD2) or with a non-target cell (visceral dorsal 1, VD1), and the interactions between their neurite outgrowth patterns and synapse formation were examined. Specifically, when cultured in brain conditioned medium (CM, contains growth-promoting factors), RPeD1, VD4, and VD2 exhibited robust neurite outgrowth within 12-24 h of their isolation. Synapses, similar to those seen in vivo, developed between the neurites of these cells. RPeD1 did not, however, synapse with its non-target cell VD1, despite extensive neuritic overlap between the cells. When placed in a soma-soma configuration (somata juxtaposed against each other), appropriate synapses developed between the somata of RPeD1 and VD4 (inhibitory) and between RPeD1 and VD2 (excitatory). Interestingly, pairing RPeD1 with either of its synaptic partner (VD4 or VD2) resulted in a complete suppression of neurite outgrowth from both pre- and postsynaptic neurons, even though the cells were cultured in CM. A single cell in the same dish, however, extended elaborate neurites. Similarly, a postsynaptic cell (VD4) contact suppressed the rate of neurite extension from a previously sprouted RPeD1. This suppression of the presynaptic growth cone motility was also target cell contact specific. The neurite suppression from soma-soma paired cells was transient, and neuronal sprouting began after a delay of 48-72 h. In contrast, when paired with VD1, both RPeD1 and this non-target cell exhibited robust neurite outgrowth. We demonstrate that this neurite suppression from soma-soma paired cells was target cell contact/synapse specific and Ca(2+) dependent. Specifically, soma-soma pairing in CM containing either lower external Ca(2+) concentration (50% of its control level) or Cd(2+) resulted in robust neurite outgrowth from both cells; however, the incidence of synapse formation between the paired cells was significantly reduced. Taken together, our data show that contact (physical and/or synaptic) between synaptic partners strongly influence neurite outgrowth patterns of both pre- and postsynaptic neurons in a time-dependent and cell-specific manner. Moreover, our data also suggest that neurite outgrowth and synapse formation are differentially regulated by external Ca(2+) concentration.

Cholinesterase inhibitors induce growth cone collapse and inhibit neurite extension in primary cultured chick neurons

Cholinesterase inhibitors are commonly prescribed medicines in neurological and anesthesiological clinical practices at relatively high doses. Recent studies report that cholinesterases, originally described as neurotransmitter degradation enzymes, are expressed in the developing central nervous systems. They are hypothesized to play an important role during the establishment of neuronal cytoarchitecture. In this study, the effects of several clinically utilized cholinesterase inhibitors on one potential aspect of neuronal development were examined using a primary culture system of chick central and peripheral neurons. Three cholinesterase inhibitors, physostigmine, neostigmine, and edrophonium, suppressed the activity of the leading edges of the extending axons (the nerve growth cones) dose dependently. Filopoda and lamellipodia of nerve growth cones were collapsed by the exposure to the cholinesterase inhibitors. This action was quick, mostly within 5 min, and partly irreversible. The lowest concentration that could induce statistically significant growth cone collapse was 10(-5) M for physostigmine, 10(-4) M for neostigmine, and 10(-2) for edrophonium, respectively. The ED50 values for the growth cone collapsing activity were approximately, 10(-3) M for physostigmine. 10(-2.5) M for neostigmine, and 10(-2) M for edrophonium both in dorsal root ganglion culture and in retinal culture. Even though the result of this in vitro study cannot be applied directly to the in vivo situation, physicians should consider the potential detrimental effects of cholinesterase inhibitors to growing and regenerating nervous tissues.

Real time imaging of calcium-induced localized proteolytic activity after axotomy and its relation to growth cone formation

The emergence of a neuronal growth cone from a transected axon is a necessary step in the sequence of events that leads to successful regeneration. Yet, the molecular mechanisms underlying its formation after axotomy are unknown. In this study, we show by real time imaging of the free intracellular Ca2+ concentration, of proteolytic activity, and of growth cone formation that the activation of localized and transient Ca2+-dependent proteolysis is a necessary step in the cascade of events that leads to growth cone formation. Inhibition of this proteolytic activity by calpeptin, a calpain inhibitor, abolishes growth cone formation. We suggest that calpain plays a central role in the reorganization of the axon's cytoskeleton during its transition from a stable differentiated structure into a dynamically extending growth cone.

Microtubule reorganization is obligatory for growth cone turning

To examine the role of microtubules in growth cone turning, we have compared the microtubule organization in growth cones advancing on uniform laminin substrates with their organization in growth cones turning at a laminin-tenascin border. The majority (82%) of growth cones on laminin had a symmetrical microtubule organization, in which the microtubules entering the growth cone splay out toward the periphery of the growth cone. Growth cones at tenascin borders had symmetrically arranged microtubules in only 34% of cases, whereas in the majority of cases the microtubules were displaced toward one-half of the growth cone, presumably stabilizing in the direction of the turn along the tenascin border. These results suggest that reorganization of microtubules could underlie growth cone turning. Further evidence for the involvement of microtubule rearrangement in growth cone turning was provided by experiments in which growth cones approached tenascin borders in the presence of nanomolar concentrations of the microtubule stabilizing compound, Taxol. Taxol altered the organization of microtubules in growth cones growing on laminin by restricting their distribution to the proximal regions of the growth cone and increasing their bundling. Taxol did not stop growth cone advance on laminin. When growing in the presence of Taxol, growth cones at tenascin borders were not able to turn and grow along the laminin-tenascin border, and consequently stopped at the border. Growth cones were arrested at borders for as long as Taxol was present (up to 6 h) without showing any signs of drug toxicity. These effects of Taxol were reversible. Together, these results suggest that microtubule reorganization in growth cones is a necessary event in growth cone turning.

Mitotic neuroblasts determine neuritic patterning of progeny

Neuronal precursor proliferation and axodendritic outgrowth have been regarded as strictly sequential, with process formation presumably beginning after mitotic activity ceases. We now report that sympathetic precursors in vitro often elaborate long neurites before dividing. Of 437 neuroblasts observed in 48 time-lapse recordings, 42 neuroblasts divided. Thirty (71%) of these mitotic neuroblasts had neurites prior to cytokinesis. "Paramitotic" neurites were found to contain microtubules (MTs), indicating that precursors elaborate neuritic cytoskeleton during proliferation. Remarkably, the precise neuritic pattern exhibited by parental neuroblasts was consistently reproduced by daughter cell pairs. Preservation of neuritic morphology occurred through asymmetric division, with individual neurites allocated to specific daughter cells. Paramitotic neurites either remained intact throughout mitosis (12 of 65), or "retracted" into the soma during prophase and then "regrew" within minutes after cytokinesis (53 of 65). "Retraction" and "regrowth" involved resorption of cytoplasm into the soma, then refilling of residual cell membrane, resulting in recapitulation of the parental neurite pattern. Paramitotic neuritogenesis appears to be intrinsically driven, but is responsive to environmental signals. The culture substrate influenced neurite length, but not the response of paramitotic neurites during mitosis or the preservation of neuritic morphology. However, the incidence of neurite-bearing neuroblasts increased from 38 +/- 1.3% to 94 +/- 1.1% with growth factor treatment. The surprisingly high incidence of paramitotic neurites and the fidelity with which patterning was conserved across cell generations raise the possibility that mitotic precursors engage in pathfinding. Our studies suggest a novel link between neurogenesis and cytoarchitectonic patterning.

Response of radixin to perturbations of growth cone morphology and motility in chick sympathetic neurons in vitro

The ERM protein--ezrin, radixin, moesin--localize to a variety of cortical structures, where they may participate in connecting the cytoskeleton to components of the plasma membrane. Antibodies that recognize the ERM proteins specifically stain growth cones of various neurons [Goslin et al., 1989: J. Cell Biol. 109:1621-1631; Birgbauer et al., 1991: J. Neurosci. Res. 30:232-241]. To probe the function of ERM proteins in growth cones, we studied the consequences of perturbing growth cone morphology and motility of cultured chick sympathetic neurons. We demonstrate that radixin is present in these growth cones. Withdrawal of nerve growth factor (NGF) induces rapid collapse of the growth cones; concomitantly, radixin staining in these growth cones are greatly diminished. Upon readdition of NGF, rapid growth cone formation is accompanied by relocalization of radixin. Induction of growth cone collapse by either growth cone-growth cone contact or exposure to brain membrane extract results in a similar diminution of radixin staining. We induced a more subtle change in the organization of the growth cones by subjecting them to an electric field. These growth cones rapidly orient toward the cathode. We show that the radixin staining of the growth cones is also asymmetrically localized toward the leading edges in the new direction of growth. The results suggest that the localization of radixin may be essential for the normal expression of growth cone morphology and function.

Developmental changes of NADPH-diaphorase neurons in the forebrain of neonatal and adult cat

We examined morphological changes of neurons stained for NADPH-diaphorase (a marker for nitric oxide synthase, NOS) in maturing cat brains. In the newborn and 2-week-old kittens reactive neurons were dispersed throughout the cortical layers, in the white matter and in subcortical structures, with dense staining in some thalamic nuclei. In the adult, the density of reactive neurons was considerably decreased in the cortex and the white matter. In the thalamus, only some nuclei retained a faint labeling. Morphological changes also occurred at the cellular level. In the neonate, stained cells had prominent, thick processes with numerous beads and varicosities. In the adult, the processes were longer and thinner, with smaller varicosities. These observations provide further evidence that NOS may play a role during development.

Calyculin-A-induced fast neurite retraction in nerve growth factor-differentiated rat pheochromocytoma (PC12) cells

Rat pheochromocytoma (PC12) cells were treated with nerve growth factor (NGF) for 3-4 days. They formed growth cones and extended neurites. Addition of the phosphatase inhibitor calyculin A (CL-A) caused a concentration-dependent complete retraction of neurites within 15 min. Retraction of growth cones started with the filopodia still present. The cell bodies acquired a grape-like shape opposite to the cell nucleus. These morphological changes were reversible. After washout of the inhibitor, the cell bodies recovered to normal shape within about 30-60 min while neurites started to grow again within 1 day. Okadaic acid (OA) which, compared to CL-A, is less potent as a PP-1 and equally potent as a PP-2A class inhibitor, caused neurite retraction only when added at more than a thousand-fold higher concentration than CL-A. Ca2+ levels within neurites and cell bodies remained stable and low during neurite retraction as measured with fura-2. However, cells treated with CL-A showed reduced activity of voltage-gated Ca2+ channels. The results suggest that the observed reversible changes in cell morphology occur at a constant low Ca2+ level and are most likely due to the inhibition of PP-1 class phosphatases.

Long-lasting accumulation of hemopexin in permanently transected peripheral nerves and its down-regulation during regeneration

We have previously demonstrated that hemopexin is present in the intact sciatic nerve and is overproduced in the distal stump after nerve transection (Swerts et al.: J Biol Chem 267:10596-10600, 1992). To get further insight into the function of this hemoprotein in nervous tissue, we have documented long-term changes in hemopexin levels in permanently degenerated (transected) and regenerating (crush-lesioned) sciatic nerves of adult rats, using immunochemical techniques. As early as a couple of days after nerve transection, the amount of hemopexin was raised in the distal stump and at the end of the proximal stump. Similarly, after a crush lesion hemopexin was rapidly increased at the injury site and in the distal part of the nerve. Subsequently, in transected nerves the level of hemopexin rose steadily and remained elevated, representing, three months after injury, over 20 times the amount found in intact contralateral nerves. In contrast, in crush-lesioned nerves, hemopexin level declined progressively in a proximodistal direction and returned to basal values 2 months after injury, together with axonal regeneration. This long-term increase in hemopexin in permanently degenerated nerves and its progressive return to normal levels during nerve regeneration suggests that hemopexin content could be regulated negatively, directly or indirectly, by growing axons. In turn, these results support the idea that hemopexin could be involved in the process of Wallerian degeneration and/or in nerve repair.

Inhibitory factors controlling growth cone motility and guidance

Recent advances in the identification of factors that inhibit axon extension lead us to suggest that there exist at least two functionally distinct categories of inhibitory factors: those that inhibit the motile apparatus of the growth cone, and those that destabilize interactions of the growth cone with the substratum. These two types of inhibitory factors could play an important role in growth cone guidance.