Sciatic nerve regeneration in mice and rats: recovery of sensory innervation is followed by a slowly retreating neuropathic pain-like syndrome

Peripheral nerve regeneration has been studied extensively in the sciatic nerve crush model, at the level of both function and gene expression. The crush injury allows full recovery of sensory and motor function in about 3 weeks as assessed by the foot reflex withdrawal test and De Medinacelli walking patterns. We used the recently developed CatWalk paradigm to study walking patterns in more detail in mice and rats. We found that, following the recovery of sensory function, the animals developed a state of mechanical allodynia, which retreated slowly over time. The motor function, although fully recovered with the conventional methods, was revealed to be still impaired because the animals did not put weight on their previously injured paw. The development of neuropathic pain following successful sensory recovery has not been described before in crush-lesioned animals and may provide an important new parameter to assess full sensory recovery.

Magnesium administration provokes motor unit survival, after sciatic nerve injury in neonatal rats

BACKGROUND

We examined the time course of the functional alterations in two types of muscles following sciatic nerve crush in neonatal rats and the neuroprotective effect of Mg2+.

METHODS

The nerve crush was performed on the 2nd postnatal day. MgSO4*7H2O was administered daily for two weeks. Animals were examined for the contractile properties and for the number of motor units of extensor digitorum longus and soleus muscles at three postnatal stages and adulthood. Four experimental groups were included in this study: i) controls, ii) axotomized rats, iii) magnesium treated controls and iv) axotomized and Mg2+-treated rats.

RESULTS

Axotomy resulted in 20% MU survival in EDL and 50% in soleus. In contrast, magnesium treatment resulted in a significant motor unit survival (40% survival in EDL and 80% in soleus). The neuroprotective effects of Mg2+ were evident immediately after the Mg2+-treatment. Immature EDL and soleus muscles were slow and fatigueable. Soleus gradually became fatigue resistant, whereas, after axotomy, soleus remained fatigueable up to adulthood. EDL gradually became fastcontracting. Tetanic contraction in axotomized EDL was just 3,3% of the control side, compared to 15,2% in Mg2+-treated adult rats. The same parameter for axotomized soleus was 12% compared to 97% in Mg2+-treated adult rats.

CONCLUSIONS

These results demonstrate that motoneuron death occurs mostly within two weeks of axotomy. Magnesium administration rescues motoneurons and increases the number of motor units surviving into adulthood. Fast and slow muscles respond differently to axotomy and to subsequent Mg2+ treatment in vivo.

Multidimensional long-term time-lapse microscopy of in vitro peripheral nerve regeneration

In order to test the effectiveness of a new advanced time-lapse microscopy imaging and image processing and analysis system, and to do quantitative and qualitative temporal analyses of in vitro peripheral nerve regeneration, long-term time-lapse imaging of cultures of mouse dorsal root ganglia (DRGs) was performed. DRGs were placed in a Petri dish, covered with collagen gel, their attached peripheral nerves were cut in the middle, creating a gap, and the dish was filled with culture medium. Six preparations were kept on the time-lapse imaging system, which provides a suitable incubation environment and enables to capture images from multiple coordinates at x,y,z axes at desired time intervals for 13 days. In general, the time-lapse imaging system proved quite stable and efficient, although some improvements are certainly required. Two main components of peripheral nerve regeneration, outgrowth of axons and activities of resident cells, were examined. Axons started to grow during the first hour of incubation with a 16.5 microm/h rate and showed the slowest rates (0.7 microm/h) on days 8 and 9, after which they resumed higher speeds again. The first cell came out of the proximal end of the cut nerve on the second day and it was a Schwann cell (SC), which was the prominent cell type in the preparations throughout the experiment. SCs were higher in number (83.15% of all cells) but slower in migration (3.4 vs. 7.3 microm/h, P < 0.001) than other cells. Other observed characteristics of axonal outgrowth and cellular activity and interactions between axons and the cells are discussed.

Sex-related differences in the regeneration of sensory axons and recovery of nociception after peripheral nerve crush in the rat

Sex-related differences regarding the regeneration of nociceptive axons and the recovery of nociception after sural nerve crush injury were examined in rats. The elongation rate of the fastest regenerating sensory axons in females started to increase after the first 6 days. This resulted in about 15% greater axon elongation distance at 8 days after crush in female than in male rats as determined by the nerve pinch test. The number of regenerating sensory axons in female and male rats, however, was not different. The recovery of nociception in the instep started earlier and was more extensive in females than in males during the entire 24-week recovery period, so that the pain sensitive area was finally about 20% larger in females than in males. Although ovariectomy significantly reduced plasma estradiol concentration in female rats, it did not change the elongation distance of regenerating nociceptive axons, which remained significantly greater than in male rats. Elimination of the cells in the distal nerve segment by freezing revealed that a more effective cell support in the distal nerve segment is probably responsible for faster regeneration of nociceptive axons in females than in males, rather than the circulating female sex hormones.

Induction of VEGF and its Flt-1 receptor after sciatic nerve crush injury

Expression of vascular endothelial growth factor and its receptors Flt-1 and Flk-1 was studied in lumbar spinal cord after sciatic nerve crush injury. Immunohistochemical staining revealed strikingly different distribution of VEGF, Flt-1, and Flk-1 in lumbar motor neurons. VEGF was observed both in the nuclei and perikarya, while Flk-1 had cytoplasmic and Flt-1 perinuclear localization. Real-time RT-PCR showed a significant increase in the expression of VEGF and Flt-1 on the injured side of the lumbar spinal cord. The increased level of VEGF was also detected by immunoblot. Here we show that lumbar motor neurons increase the expression of VEGF and Flt-1 in response to injury. We propose that VEGF/Flt-1 signaling may be involved in regeneration of the spinal motor neurons.

The spatiotemporal characterization of endplate reoccupation, with special reference to the superposition patterns of the presynaptic elements and the postsynaptic receptor regions during muscle reinnervation

In this study, an immunohistochemical investigation was carried out to define spatiotemporal characteristics of superposition patterns of the presynaptic elements and the postsynaptic acetylcholine receptor (AChR) sites during the period of endplate regeneration after sciatic nerve crush. The extent of close correspondence of terminal Schwann cell (TSC)-, or axon terminal-, apposing AChR sites was quantitated with three-dimensional images of neuromuscular junctions (NMJs) taken under confocal laser-scanning microscopy. After 3-weeks post-crush (wpc), reoccupation of regenerating TSCs and later arriving axon terminals proceeded within the scope of previously denervated AChR plaques. During this period, the areas of presynaptic elements and the areas of postsynaptic elements were highly correlated. TSCs rapidly reoccupied a greater part of the postsynaptic receptors. In contrast, there was a slower increase of the contact areas of AChR sites overlapped by the axon terminals. Reoccupation by the presynaptic elements at 20 wpc was almost completed in a majority of NMJs, but some anomalous changes still continued to occur in a small proportion of the NMJs (20-30%). Our results suggest that: (a) with gradual increase of the contact areas between presynaptic and postsynaptic elements, imperfect reinnervation and regeneration, due to spatial mismatching or unbalanced growth between presynaptic and postsynaptic elements, result in sporadic remodeling; (b) the difference in superposition patterns between TSCs and axon terminals depends on the ability of making alignment to the endplate gutters in regenerating NMJs; and (c) a complex set of anatomical relationships among the three endplate components affects the process of endplate reoccupation synthetically.

Remodelling of connections in pelvic ganglia after hypogastric nerve crush

Pelvic ganglia innervate the urogenital organs and contain both sympathetic and parasympathetic neurons. Previous studies have shown that within days of cutting either the lumbar or sacral preganglionic axons that innervate pelvic ganglia, many axon collaterals grow and appear to form specific connections with denervated pelvic neurons. Here we have examined the longer term consequences of partial deafferentation by studying pelvic ganglia up to 7 weeks after hypogastric nerve (HGN) crush, a lesion which also allows faster regeneration of spinal axons. Noradrenergic neurons were denervated by HGN crush, as demonstrated by loss of varicosities immunostained for the synaptic proteins, synaptophysin and synapsin. A week after HGN crush, axon collaterals grew from parasympathetic pelvic ganglion neurons, shown by the presence of numerous varicose fibers immunostained for vasoactive intestinal peptide (VIP). These VIP fibers were poorly stained or unstained for synaptophysin, even after 7 weeks. At early post-operative times the VIP fibers grew irregularly; however, with longer post-operative times they appeared to target particular VIP-negative, noradrenergic neurons. Our results also indicate that some lumbar preganglionic axons regenerated during the post-operative period, although this only affected a minority of sympathetic neurons. These reinnervated sympathetic neurons were not associated with VIP fibers, suggesting that the new intrinsic connections may have precluded regeneration or targeting of preganglionic axons. Together these results demonstrate that there is considerable remodelling within pelvic ganglia after partial deafferentation. This occurs under conditions where spinal preganglionic axons can regenerate. New intra-ganglionic connectivity may be permanent and may impact on this regeneration.

Brain-derived neurotrophic factor reduces TrkB protein and mRNA in the normal retina and following optic nerve crush in adult rats

Brain-derived neurotrophic factor (BDNF) is a well-known retinal neuroprotectant, but its effectiveness is limited: higher doses do not yield increased cell survival, multiple applications are not additive, and long-term delivery does not reverse, ganglion cell death. These limitations might reflect either injury- or BDNF-induced retinal changes in TrkB, the high affinity tyrosine kinase receptor used by BDNF. Retinal levels of TrkB protein and mRNA were measured in rats following intravitreal application of BDNF alone, optic nerve crush alone, and both. Full-length receptor protein levels (TrkB.FL) were determined by Western blot analysis and mRNA (trkB.FL) levels were measured using RNAse protection assay (RPA). BDNF alone produced a rapid and prolonged decrease in normal retina TrkB.FL. Nerve crush also resulted in decreased TrkB.FL, but the reduction was not apparent before 2-week post-crush. BDNF applied at the time of the crush yielded reductions in TrkB.FL similar to that of BDNF alone. With respect to TrkB mRNA levels, injection of BDNF into normal eyes and optic nerve crush alone showed bell-shaped patterns of change: approximately 50% below normal at 24-h post-procedure, approximately 50% above normal at 3 days, normal at 7 days, and approximately 50% below normal at 2-week post-procedure. When BDNF and nerve crush were combined, trkB-FL levels reached 90% of normal 1-week post-crush/injection. The data suggest that the limitation of BDNF in promoting ganglion cell survival following optic nerve injury results, in part, due to drug-induced down-regulation of the full-length TrkB receptor needed to activate intracellular pathways.

Neuroregenerative and neuroprotective actions of neuroimmunophilin compounds in traumatic and inflammatory neuropathies

FK506 (tacrolimus, Prograf is an immunosuppressant drug that also has profound neuroregenerative and neuroprotective actions independent of its immunosuppressant activity. The separation of these properties has led to the development of non-immunosuppressant derivatives that retain the neurotrophic activity. This review focuses on the peripheral nerve actions of these compounds following mechanical injury (nerve crush or transection with graft repair) and in models of inflammatory neuropathies. Whereas FK506 may be indicative for the treatment of inflammatory neuropathies where its immunosuppressive action would be advantageous, non-immunosuppressant derivatives represent a new class of potential therapeutic agents for the treatment of human neurological conditions in general. Moreover, these studies have led to the discovery of a novel mechanism whereby these compounds activate intrinsic neuroregenerative and neuroprotective pathways in the neuron.

Vesicular acetylcholine transporter can be a morphological marker for the reinnervation to muscle of regenerating motor axons

This study was designed to evaluate whether the vesicular acetylcholine transporter (VAChT), which packages acetylcholine into synaptic vesicles, can be used as a marker for regenerating motor axon terminal. We examined motor axon regeneration in the tongue after hypoglossal nerve axotomy, using an anterograde tracer biotin-dextran (BD), retrograde tracer Fluoro-Gold (FG), electron microscopic (EM) observation, and VAChT immunocytochemistry. BD study demonstrated that outgrowth of thin regenerating axons into the frontal area of the tongue was firstly observed at 14 post-operative days, and presynaptic formation of neuromuscular junction (NMJ) was observed from 21 post-operative days. Under electron microscopic observation, reconstruction of new NMJs was observed within the interval between 21 and 28 days. VAChT-immunoreactive nerve terminals disappeared by 3 days after axotomy, slightly appeared at 14 post-operative days, and thereafter gradually increased in number from 21 to 28 post-operative days. The re-expression of VAChT positive presynaptic terminal was almost the same as those obtained in BD, FG and EM studies. Regenerating axons tip in the crush model of the hypoglossal nerve exhibited prominent VAChT immunoreactivity in growing tip of regenerating axons. These indicate that VAChT is an excellent morphological indicator for regenerating nerve terminals of motor neurons.

Changes in electrophysiological properties of regenerating rat peripheral nerves after crush injury

The conduction of action potential in peripheral nerves requires the coordinated opening and closing of Na(+) and K(+) channels. In the present study, we used the sucrose-gap recording technique to determine the electrophysiological changes of the regenerating nerves after sciatic nerve injury by using 4-aminopyridine (4-AP) and tetraethylammonium (TEA), and lidocaine. 4-AP enhanced the amplitude and duration of the compound action potentials (CAPs) of regenerating sciatic nerve 15 days post crush (15 dpc), and elicited delayed depolarizations (Del-dep) in 38 dpc and intact groups. Hyperpolarizing afterpotentials elicited by 4-AP were completely removed by TEA in both 15 and 38 dpc. Lidocaine effectively blocked the CAP amplitude. This blockage was more pronounced in 15 dpc than 38 dpc. This agent also exhibited a partial blockage on the Del-dep amplitude. These results may indicate that the changes in the activities of 4-AP- and TEA-sensitive K(+) channels and slow Na(+) channels may play critical roles in nerve excitability and conduction.

The recovery of blood-nerve barrier in crush nerve injury--a quantitative analysis utilizing immunohistochemistry

The purpose of this study is to reveal whether the application of immunohistochemical examinations to the peripheral nervous system (PNS) can be a reliable method for the quantitative analysis of the blood-nerve barrier (BNB) and the relationship between restoration of BNB and nerve regeneration. Sciatic nerves in rats were examined after nerve crush. Immunohistochemical staining with anti-rat endothelial cell antigen-1 (anti-RECA-1) that recognizes endothelial cells and anti-endothelial barrier antigen (anti-EBA) for the detection of barrier-type endothelial cells were used. Neurofilament for staining axons was also performed. A quantitative analysis of the BNB was assessed using the ratio of EBA positive cells and RECA-1 positive cells. The ratio of EBA/RECA-1 decreased significantly 3 days postoperatively and reached its lowest level at day 7 in the segment 5 mm proximal and the entire distal stump. The ratio gradually recovered from the proximal and the regeneration of axons started a week earlier than BNB. The ratio of EBA/RECA-1 applied to the PNS can be a reliable method for the quantitative analysis of BNB. In crush injuries, the breakdown of BNB occurred simultaneously in the segment 5 mm proximal and the entire distal stump; restoration began from the proximal to distal and followed a week later to nerve regeneration.

Calpain inhibitor 2 prevents axonal degeneration of opossum optic nerve fibers

The ultrastructural change that characterizes the onset of Wallerian degeneration is the disintegration of axoplasmic microtubules and neurofilaments, which are converted into an amorphous and granular material, followed by myelin breakdown. The mechanism underlying such processes is an increase in the amount of intracellular calcium, leading to activation of proteases called calpains. The aim of this study was to evaluate by quantitative ultrastructural analysis whether nerve fibers can be preserved by the use of an exogenous inhibitor of these proteases (calpain inhibitor-2, Mu-F-hF-FMK), after optic nerve crush. For that, the left optic nerves of opossums, Didelphis aurita, were crushed with the aid of a fine forceps, and half of them received a calpain inhibitor mixed with Elvax resin. Ninety-six hours after the lesion, the animals were reanesthetized and transcardially perfused, and the optic nerves were removed, the right ones being used as normal nerves. Afterward, the optic nerves were dissected and processed for routine transmission electron microscopy and quantitative and statistical analysis. The results of this analysis showed that the group that received the calpain inhibitor presented a reduction of astrogliosis, maintaining the optic nerve structure in an organized state; a significant decrease in the number of degenerating fibers; and a significant increase in the number of fibers with preserved cytoskeleton and preservation of axonal and myelin area and integrity, reducing the enlargement and edema of the axon. In conclusion, our findings suggest that calpain inhibitor is able to provide neuroprotection of the central nervous system fibers after a crush lesion.

Intraocular injection of dibutyryl cyclic AMP promotes axon regeneration in rat optic nerve

The optic nerve is a CNS pathway containing molecules capable of inhibiting axon elongation. The growth program in embryonic retinal ganglion cell (RGC) neurons enables axons to regenerate in the optic nerve through at least two mechanisms. Namely, high cyclic AMP (cAMP) levels abrogate the ability of CNS molecules to inhibit elongation, and the pattern of gene expression enables axons to undergo rapid, sustained, and lengthy elongation. In adult mammals, recovery of visual function after optic nerve injury is limited by both the death of most RGC neurons and the inability of surviving axons to regenerate. We now report that a single intraocular injection of the membrane-permeable cAMP analogue dibutyryl cAMP (db cAMP) promotes the regeneration of RGC axons in the optic nerves of adult rats, but does not prevent the death of RGC neurons. This regeneration in optic nerves crushed within the orbit (2 mm from the eye) was equally effective either 1 day before or 1 day after db cAMP injection. The number of regenerating axons, which was maximal 14 days after crush, declined with increasing time after injury (i.e., 28, 56, and 112 days) and distance beyond the crush site (i.e., 0.25, 0.5, and 1.0 mm). Thus, db cAMP promotes optic nerve regeneration without increasing the survival of axotomized RGC neurons. Furthermore, since db cAMP does not enable axons to undergo rapid, sustained, and lengthy elongation, strategies that increase survival and promote these changes in elongation may critically complement the ability of db cAMP to promote regeneration.

The extent of cytokine induction in peripheral nerve lesions depends on the mode of injury and NMDA receptor signaling

We compared cytokine and chemokine induction in mice after sciatic nerve crush and chronic constriction injury (CCI) by quantitative reverse transcriptase polymerase chain reaction. In both nerve lesion paradigms, transcripts for tumor necrosis factor alpha (TNF-alpha), interleukin (IL)-1beta, IL-10, and monocyte chemoattractant protein-1 (MCP-1) were significantly increased in degenerating nerve stumps already at day 1, with a greater magnitude and longer duration in CCI. NMDA receptor blockade significantly reduced cytokine expression after CCI on the mRNA and protein level. In dorsal root ganglia, only IL-10 mRNA levels were modified after nerve injury. Our study indicates that the mode of nerve injury influences the extent of cytokine expression, and identifies NMDA-mediated signaling as one mechanism of cytokine induction in peripheral nerves.

Early structural effects of oestrogen on pudendal nerve regeneration in the rat

OBJECTIVE

To determine the early effects of oestrogen on the ultrastructure of the pudendal nerve and distal nerve fascicles near the external urethra sphincter (EUS) after a pudendal nerve crush injury. The pudendal nerve is one of the pelvic floor tissues injured during vaginal delivery, possibly contributing to the development of stress urinary incontinence (SUI) in women, the symptoms of which often do not appear until menopause, implicating hormonal factors.

MATERIALS AND METHODS

Twenty-seven virgin female Sprague-Dawley rats were anaesthetized and underwent ovariectomy. Three days later, they had one of four procedures: bilateral pudendal nerve crush plus implant of a subcutaneous oestrogen-containing capsule (NC+E); nerve crush plus implant of a sham saline-containing capsule (NC+S); no nerve crush with an oestrogen capsule; or no nerve crush with a sham capsule. After 2 weeks the pudendal nerves and urethral tissues were prepared for light and electron microscopy. The number of axons, myelin figures and endoneurial nuclei in the pudendal nerve segment distal to the lesion were counted. Nerve fascicles near the EUS were also counted and categorized as normal or showing signs of degeneration and/or regeneration. The location of each nerve fascicle was specified as either ventral or dorsal.

RESULTS

As there were no significant differences between the two control groups they were combined to form a single control group. In the distal pudendal nerve there were significantly fewer myelinated axons and large myelinated axons in the NC+E and NC+S groups than in the control group. There were three times as many large unmyelinated axons in the NC+E group than in either the NC+S or control groups (P < 0.05). There were only half as many nerve fascicles near the ventral side of the EUS in the NC+S group than in both the control and NC+E groups (P < 0.05).

CONCLUSION

Oestrogen appears to affect large unmyelinated axons in both the injured pudendal nerve and at the denervated EUS target. After pudendal nerve crush, nerve fascicles with evidence of degeneration or regeneration near the EUS appear to be spared with oestrogen treatment, particularly in the ventral region. These observations may reflect the early stages of a neuroregenerative effect of oestrogen. Additional studies are needed to confirm these results at later periods and with functional methods.

Heightened pain and delayed regeneration of galanin axons in diabetic mice

Galanin peptide in primary sensory neurons may confer analgesia following injury. Its presence in regenerative axon sprouts where pain may be initiated has not been examined. We examined very early outgrowth of peptidergic axon sprouts after sciatic nerve crush in mice with experimental streptozotocin-induced diabetes. Diabetic mice had a retarded wave of outgrowing galanin axons, but those expressing calcitonin gene-related peptide grew normally. Diabetic mice also developed early, then persistent excessive autotomy behaviour, an index of pain behaviour in complete nerve lesions. Diabetes is associated with variations in the early outgrowth of peptide-containing axons. A relative delay in galanin axon outgrowth could contribute to heightened neuropathic pain in diabetes.

Peripheral axon crush elevates transport of p75NTR in the central projection of sensory neurones of rats

The effect of peripheral axon crush on the axonal transport of the neurotrophin receptors, p75(NTR) and trkA, was studied in dorsal roots of adult rats. Lumbar dorsal roots were crushed for 3-6 h to cause accumulation of p75(NTR) and trkA. Immunohistochemistry showed the presence of the NGF receptors in axons, indicating retrograde and anterograde axonal transport in the dorsal root. Western blots confirmed that the time course of accumulation of p75(NTR) was consistent with fast axonal transport. However, trkA accumulation was too low to indicate significant levels of axonal transport. Sciatic nerve crush induced a 2-fold increase (P<0.05) in the bidirectional axonal transport of p75(NTR) in the dorsal root while trkA transport remained below detectable levels.

Macrophage stimulation using a group B-streptococcus exotoxin (CM101) leads to axonal regrowth in the injured optic nerve

PURPOSE

A group B-streptococcus exotoxin (CM101) was administered following optic nerve injury in adult rats in order to analyze putative effects on macrophages, glial scar formation and regrowth of axons in the lesioned optic nerve.

METHODS

After a standardized intraorbital optic nerve crush, animals were randomized to treatment with CM101 (30 microm/kg body weight, iv, repeated every other day) or vehicle alone. Morphology (semithin sections) and immunohistochemistry directed towards macrophages (ED1), neurofilament (NF), astrocytes (GFAP) and regenerative sprouts (GAP43) were employed at different time-points up to 28 dpi.

RESULTS

A significant increase of ED1-positive macrophages (p < 0.05) was observed at 7, 14 and 28 dpi in treated animals compared to untreated, indicative of macrophage stimulation. Less degenerative structures were found in sections distal to the injury in treated animals, seemingly due to a pro-phagocytic effect. Reactive gliosis was significantly (p < 0.05) less pronounced in CM101-treated animals. The presence of GAP43-positive sprouts and neurofilament-positive neurites distal to the lesion in treated animals indicate regrowth of axons crossing the glial scar.

CONCLUSION

Treatment with group B-streptococcus exotoxin leads to macrophage stimulation, increased phagocytosis of inhibitory debris, and a less dense reactive gliosis, which in turn allows for regrowth of axons through the glial scar.

Inhibition of calpains, by treatment with leupeptin, improves motoneuron survival and muscle function in models of motoneuron degeneration

The effect of treatment with leupeptin, a calpain inhibitor, on motoneuron survival and muscle function was examined in in vitro and in vivo models of motoneuron degeneration. Exposure of primary rat motoneurons to alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid (AMPA) is an established in vitro model of excitotoxic motoneuron death. Here we show that leupeptin treatment improved motoneuron survival following exposure to AMPA (50 microM). Application of leupeptin (100 microM) to AMPA treated cultures rescued many motoneurons so that 74% (+/-3.4 S.E.M., n=5) survived compared with only 49% (+/-2.4 S.E.M., n=5) in untreated cultures. The effect of treatment with leupeptin on motoneuron survival and muscle function was also examined in vivo. In 3 day-old rats, the sciatic nerve was crushed and at the time of injury, a silicon implant containing leupeptin was inserted onto the lumbar spinal cord. The effect on long-term motoneuron survival and muscle function was assessed 12 weeks after injury. The results showed that there was long-term improvement in motoneuron survival in the leupeptin treated group. Thus, in untreated animals 12 weeks after nerve crush only 30% (+/-2.8. S.E.M., n=3) of sciatic motoneurons survived compared with 43% (+/-1.5 S.E.M., n=3) in the leupeptin-treated group. This improvement in motoneuron survival was reflected in a significant improvement in muscle function in the leupeptin-treated group. For example in the soleus muscle of treated rats 20.8 (+/-1.40 S.E.M., n=5) motor units survived compared with only 14.6 (+/-1.21 S.E.M., n=5) in untreated animals. Thus, treatment with leupeptin, a calpain inhibitor, rescues motoneurons from cell death and improves muscle function following nerve injury.

Failure to restore vision after optic nerve regeneration in reptiles: Interspecies variation in response to axotomy

Optic nerve regeneration within the reptiles is variable. In a snake, Viper aspis, and the lizard Gallotia galloti, regeneration is slow, although some retinal ganglion cell (RGC) axons eventually reach the visual centers (Rio et al. [1989] Brain Res 479:151-156; Lang et al. [1998] Glia 23:61-74). By contrast, in a lizard, Ctenophorus ornatus, numerous RGC axons regenerate rapidly to the visual centers, but unless animals are stimulated visually, the regenerated projection lacks topography and animals remain blind via the experimental eye (Beazley et al. [2003] J. Neurotrauma 20:1263-1269). V. aspis, G. galloti, and C. ornatus belong respectively to the Serpentes, Lacertidae, and Agamidae within the Eureptilia, the major modern group of living reptiles comprising the Squamata (snakes, lizards, and geckos) and the Crocodyllia. Here we have extended the findings on Eureptilia to include two geckos (Gekkonidae), Cehyra variegata and Nephrurus stellatus. We also examined a turtle, Chelodina oblonga, the Testudines being the sole surviving representatives of the Parareptilia, the more ancient reptilian group. In all three species, visually elicited behavioral responses were absent throughout regeneration, a result supported electrophysiologically; axonal tracing revealed that only a small proportion of RGC axons crossed the lesion and none entered the contralateral optic tract. RGC axons failed to reach the chiasm in C. oblonga, and in G. variegata, and N. stellatus RGC axons entered the opposite optic nerve; a limited ipsilateral projection was seen in G. variegata. Our results support a heterogeneous response to axotomy within the reptiles, each of which is nevertheless dysfunctional.

A temporal study of axonal degeneration and glial scar formation following a standardized crush injury of the optic nerve in the adult rat

PURPOSE

In this methodological study, we describe a standardized optic nerve injury model in adult rats. The temporal pattern of the glial response is mapped in relation to axonal regeneration and degeneration.

METHODS

A standardized optic nerve crush injury was made in adult rats, using a fine pair of forceps with a preset pressure of 0.6 N during 10 seconds.

RESULTS

This crush injury resulted in a pronounced astroglial and microglial proliferation 2-7 dpi. Degenerative axons distal to the lesion presented a gradual decrease in neurofilament immunoreactivity. In contrast, Fluoro-Jade staining was gradually increased in these degenerative axons from 2-7 dpi. Regeneration was observed proximal to the lesion in sprouts double labeled with the tracer Fluoro-Gold and anti-GAP43.

CONCLUSION

The standardized optic nerve crush injury model used in the present study resulted in a reproducible degenerative pattern including a pronounced astroglial and microglial proliferation. The gradual decrease in Neurofilament immunoreactivity in degenerative axons, and a gradual increase in Fluoro-Jade staining was paralleled with a spontaneous regeneration proximal to the lesion, shown with tracing and GAP43-immunoreactivity. The combination of these markers and this experimental setup thus allows analysis of the entire degenerative/regenerative process in a standardized CNS axotomy model.

Extracellular matrix and matrix metalloproteinases in sciatic nerve

Although matrix metalloproteinases (MMPs) are increasingly being implicated in several pathologies of the nervous system, it is not yet clear what role they play in normal neurobiological processes. We review the expression of extracellular matrix (ECM) components as well as MMPs and tissue inhibitors of metalloproteinases (TIMPs) in the peripheral nervous system. We explore the expression of certain MMPs and the four TIMPs at the mRNA level in the postnatal mouse sciatic nerve. In addition, we have used substrate gel and in situ zymography to determine levels of MMP-2 and -9 and TIMP activity in rat sciatic nerve after crush and during regeneration. A rapid and transient increase in MMP-9 localised at and immediately distal to the site of injury was observed, whereas an increase in MMP-2 activity was delayed, prolonged, and extended proximal and distal to the injury site. This activity coincides with periods of axonal elongation, suggesting that it could act to facilitate axonal extension along the nerve matrix. We also detected multiple species of gelatinolytic inhibitory activity, including TIMP-1 and -3 in control and injured nerve. These activities probably act to prevent uncontrolled gelatinolytic activity, maintaining nerve integrity at the level essential for axonal regrowth.

Effects of FK506 on regeneration and macrophages in injured rat sciatic nerve

Effects of FK506 [5.0 mg/kg body weight (BW), subcutaneous, daily] on nerve regeneration and presence of macrophages in lesioned rat sciatic nerves were studied. Models of autologous nerve graft or a nerve crush lesion were used and regeneration was evaluated by immunocytochemistry (also used to detect ED1/ED2 macrophages) and sensory pinch reflex test, respectively. Treatment with FK506 did not increase regeneration distance or regeneration rate in the autologous nerve grafts. However, regeneration distances after nerve crush were significantly longer following treatment with FK506. The number of macrophages (ED1/ED2) in nerve grafts increased over time, but treatment with FK506 had limited effects only in the presence of ED2 macrophages. Present and previously published studies may imply that there is a time-related and type-of-injury-related profile of FK506's pro-regenerative effect.

Therapeutic gene transfer with herpes-based vectors: studies in Parkinson's disease and motor nerve regeneration

We have examined the possibility of using herpes simplex virus (HSV)-based vectors to prevent neuronal cell death and enhance functional recovery after injury. In the 6-hydroxydopamine (6-OHDA) model of Parkinson's disease (PD) and after proximal spinal root injury, direct stereotactic injection of HSV-based vectors constructed to express the glial cell derived neurotrophic factor (GDNF) or the anti-apoptotic peptide Bcl-2 prevented neuronal death and enhanced recovery. Gene transfer may be useful in the treatment of neurologic disorders in which neuronal cell death occurs in a restricted anatomic distribution.