Abstract
Traumatized axons possess an extremely limited ability to regenerate within the adult mammalian CNS. The myelin-derived axon outgrowth inhibitors Nogo, oligodendrocyte-myelin glycoprotein, and myelin-associated glycoprotein, all bind to an axonal Nogo-66 receptor (NgR) and at least partially account for this lack of CNS repair. Although the intrathecal application of an NgR competitive antagonist at the time of spinal cord hemisection induces significant regeneration of corticospinal axons, such immediate local therapy may not be as clinically feasible for cases of spinal cord injury. Here, we consider whether this approach can be adapted to systemic therapy in a postinjury therapeutic time window. Subcutaneous treatment with the NgR antagonist peptide NEP1–40 (Nogo extracellular peptide, residues 1–40) results in extensive growth of corticospinal axons, sprouting of serotonergic fibers, upregulation of axonal growth protein SPRR1A (small proline-rich repeat protein 1A), and synapse re-formation. Locomotor recovery after thoracic spinal cord injury is enhanced. Furthermore, delaying the initiation of systemic NEP1–40 administration for up to 1 week after cord lesions does not limit the degree of axon sprouting and functional recovery. This indicates that the regenerative capacity of transected corticospinal tract axons persists for weeks after injury. Systemic Nogo-66 receptor antagonists have therapeutic potential for subacute CNS axonal injuries such as spinal cord trauma.
- Nogo
- Nogo-66 receptor antagonist
- axon regeneration
- spinal cord injury
- trauma
- serotonergic fiber
- SPRR1A
- NEP1–40 peptide
Introduction
Adult mammalian CNS trauma interrupts axonal continuity and results in persistent functional deficits. The success or failure of axonal growth and reconnection with synaptic targets is a principal determinant of recovery in conditions such as spinal cord injury (SCI). CNS axonal regeneration is determined by both cell-autonomous and cell-extrinsic factors. Adult retinal axons can extend if provided with a favorable environment, but they do so with less alacrity than embryonic or peripheral neurons (Goldberg et al., 2002). Rapid peripheral axon regeneration is supported by the induction of regeneration-associated genes such as GAP-43 (Bomze et al., 2001) and SPRR1A (small proline-rich repeat protein 1A) (Bonilla et al., 2002), which are not upregulated after CNS axotomy. Changes in growth state may be mediated by increased levels of cAMP (Neumann et al., 2002; Qiu et al., 2002) and by the signal transducer and activator of transcription signaling (Liu and Snider, 2001).
There is also clear evidence that the environment surrounding CNS axons limits their growth. Although this may include a paucity of growth-promoting factors, such as neurotrophins (Schnell et al., 1994; Coumans et al., 2001), the presence of CNS inhibitors of axonal regeneration is now well documented. The glial scar produced by astrocytes is laden with inhibitory chondroitin sulfate proteoglycans (CSPG) (Snow et al., 1990; Dou and Levine, 1994; Davies et al., 1999). The digestion of CSPGs can provide a level of axon growth and recovery (Bradbury et al., 2002).
Several lines of evidence have identified CNS myelin components as prominent inhibitors of adult axon regeneration. CNS axons extend robustly into peripheral nerve grafts lacking oligodendrocytes (Richardson et al., 1980) or into the myelin-free CNS (Savio and Schwab, 1990). Three molecules of CNS myelin have been identified as axon-regeneration inhibitors: Nogo (Chen et al., 2000; GrandPre et al., 2000; Prinjha et al., 2000), myelin-associated glycoprotein (MAG) (Savio and Schwab, 1990; McKerracher et al., 1994; Mukhopadhyay et al., 1994), and oligodendrocyte myelin glycoprotein (Wang et al., 2002a). All three purified proteins inhibit axon outgrowth from mature neurons in vitro. Remarkably, a single neuronal protein, the Nogo-66 receptor (NgR) binds all three proteins and appears to be the primary mediator of their action (Fournier et al., 2001; Domeniconi et al., 2002; Liu et al., 2002; Wang et al., 2002a). The p75 lowaffinity neurotrophic receptor protein has been implicated in transducing a myelin/NgR signal to the axonal interior (Wang et al., 2002b; Wong et al., 2002).
The presence of myelin-derived inhibitors suggests that blocking their action might allow the intrinsic growth potential of CNS axons to be unmasked, with resultant functional recovery after adult CNS axotomy. Indeed, neutralizing Nogo A with IN-1 antibody can induce CNS axon regeneration and improve recovery after various lesions (Bregman et al., 1995; Thallmair et al., 1998). Genetic studies of MAG depletion have met with mixed results (Bartsch et al., 1995; Schafer et al., 1996). Targeting the axonal NgR with a competitive antagonist compound has the potential to block the action of the three known myelin inhibitors. Indeed, intrathecal application of an NgR competitive antagonist, NEP1–40 (Nogo extracellular peptide, residues 1–40), produces significant axonal regrowth after spinal cord hemisection injury (GrandPre et al., 2002). However, local drug delivery initiated at the time of SCI may be logistically difficult for the treatment of many SCI patients. In the present study, we also demonstrate the therapeutic potential of an NgR antagonist peptide for SCI by systemic peptide administration at a postinjury time window.
Materials and Methods
Spinal cord dorsal hemisection and corticospinal fiber tracing. All surgical procedures and postoperative care were performed in accordance with guidelines of the Yale Animal Care and Use Committee. Adult female C57BL/6 mice (8–10 weeks of age, Charles River, Wilmington, MA) were deeply anesthetized with intramuscular ketamine (100 mg/kg) and intraperitoneal xylazine (15 mg/kg). A complete laminectomy was performed, and the dorsal part of spinal cord was fully exposed at levels T6 and T7 (GrandPre et al., 2002). A dorsal overhemisection was performed at T6 with a 30 gauge needle and a pair of microscissors to completely sever the dorsal and dorsolateral corticospinal tracts (CSTs). The depth of the lesion (1.0 mm) was ensured by passing the marked needle several times across the dorsal part of the spinal cord. The muscle layers over the laminectomies were sutured, and the skin on the back was closed with surgical staples. To trace the CSTs, a burr hole overlying the cerebral cortex on the right side was made into the skull. Biotin dextran amine [BDA; molecular weight (MW), 10,000; 10% in PBS] (Molecular Probes, Eugene, OR) was applied at four injection sites at a depth of 0.7 mm from the cortical surface. For the animals receiving treatment 7 d after SCI, the BDA injection was conducted on day 28 after spinal cord lesion.
NgR antagonist peptide administration. The NgR antagonist NEP1–40 peptide (acetyl-RI YKGVIQAIQKSDEGHPFRAYLESEVAISEELVQKYSNS-amide) was synthesized (GrandPre et al., 2002). We tested eight groups of animals (10–12 animals per group): four groups with subcutaneous injections starting at the time of initial injury, two with intraperitoneal injections given 3–4 hr after injury, and two with more delayed subcutaneous injections starting 7 d after SCI. In the animals treated immediately after initial injury, an Alzet osmotic minipump (model 2002, Alza, Mountain View, CA) was implanted after the hemisection of dorsal spinal cord and positioned to deliver reagents to the subcutaneous space. The pump was filled with vehicle (83% PBS plus 17% DMSO) or NEP1–40 in the vehicle. The vehicle or NEP1–40 was delivered continuously at a rate of 0.6 μl/hr for 14 d. NEP1–40 was administered at doses of 1.2, 3.9, and 11.6 mg · kg−1 · d−1. For the animals receiving 3 hr delayed treatment, the first injection of vehicle or vehicle plus peptide (11.6 mg · kg−1 · d−1) was administered intraperitoneally 3–4 hr after spinal cord lesion, and the same dose of peptide was given once daily for another 14 d. For the mice receiving posttraumatic treatment that was further delayed, the minipump (Alzet model 2002) was implanted subcutaneously 7 d after hemisection to deliver vehicle or vehicle plus NEP1–40 (11.6 mg · kg−1 · d−1) continuously for 2 weeks. In this study, 91 mice underwent the procedure: 34 received vehicle and 57 received NEP1–40.The mortality rate was 19.8% during the first postoperative week and did not differ significantly between groups.
Histology and behavioral analysis. Animals starting treatment at the time of SCI or 3 hr after SCI were perfused transcardially 20 d after injury with PBS, followed by 4% paraformaldehyde. For the animals receiving treatment 7 d after SCI, the perfusion was performed on day 42 after the hemisection injury. The spinal cord was postfixed overnight. The spinal cord 4 mm rostral and 4 mm caudal to the lesion site (8 mm long) was embedded in a glutaraldehyde-polymerized albumin matrix and cut parasagittally on a vibratome (30μm thick). Transverse sections (50μm) were collected from the spinal cord 5–7 mm rostral and 5–7 mm caudal to the injury site. The freefloating sections were preincubated with 0.5% BSA/TBS for 1 hr and then processed with avidin-HRP (Vector Laboratories, Burlingame, CA), followed by a nickel-enhanced diaminobenzidine reaction (GrandPre et al., 2002). To visualize the lesion area, some sections were double-stained with antibodies directed against myelin basic protein (MBP; Sternberger Monoclonals, Lutherville, MD). The sections were mounted, dehydrated, and covered with mounting medium. Some transverse sections were immunostained with antibodies against SPRR1A (Bonilla et al., 2002), and 5-HT (Diasorin, Stillwater, MN). For other transverse sections 8–9 mm caudal to the lesion, tracer BDA was visualized with a streptavidin-Alexa Fluor 594 conjugate (Molecular Probes), and these sections were double-stained with primary antibodies against synaptophysin (Sigma, St. Louis, MO) or MBP. Double-stained sections were analyzed by confocal microscopy. For axon quantification, sections from the first five to seven animals processed were analyzed for each treatment group.
The Basso–Beattie–Bresnahan (BBB) locomotor rating scale (Basso et al., 1996), footprint analysis, and inclined grid walking were tested by two individuals. For footprint analysis, the walking patterns of mouse hindpaws were recorded with ink during a continuous locomotion across a 50 cm runway, and stride length on each side and strike width were calculated (Metz et al., 2000). For inclined grid walking, the mice were trained to climb a wire grid (35 cm long with 2.54 cm squares) at a slope of 45°. The number of instances in which the hindpaw dropped below the grid plane was scored for each excursion from bottom to top. Throughout the surgery, behavioral testing, and histologic analysis, researchers were unaware of the identity of the compound in the minipump or syringe.
Results
Systemic NEP1–40 results in extensive CST sprouting rostral to SCI
Previous studies have indicated that the blood–brain barrier is absent for weeks to months in an area of spinal cord trauma (Schnell et al., 1999). This suggested to us that systemic administration of the NEP1–40 peptide (MW, 4625) might be as efficacious as intrathecal treatment. We delivered NEP1–40 or vehicle subcutaneously to mice with midthoracic dorsal hemisection via an osmotic minipump implanted a few minutes after cord injury. Doses of 0, 1.2, 3.9, or 11.6 mg · kg−1 · d−1 were administered for the first 2 weeks of a 3 week survival period. These doses produced no evidence of overt toxicity. The integrity of descending CST was assessed by injecting BDA into the motor cortex on the right side. In the animals receiving vehicle injection, the prominent dorsal CST (dCST) is tightly bundled rostral to the lesion (Fig. 1A), and a few dorsolateral fibers are visible at the ipsilateral site. A few BDA-labeled collateral sprouts project into the gray matter, particularly in the ventral cord (Fig. 1B), but the sprouting is confined to the side of the cord contralateral to the tracer injection. In contrast, sections from injured animals treated with the NgR antagonist NEP1–40 exhibit an entirely different BDA labeling pattern. Rostral to the lesion site, a high density of fibers outside of the BDA-labeled dorsal CST (Fig. 1C,D) is present in all of the NEP1–40-treated samples. Ectopic fibers extend throughout the gray matter area, and some fibers reach into the lateral and dorsolateral white matter (Fig. 1C,D). A smaller number of fibers (5–10 sprouts per transverse section) are seen on the opposite side of the spinal cord in the gray matter (ipsilateral to the tracer injection site). The number of collateral sprouts is increased 10-fold in the NgR antagonist-treated animals at a dose of 11.6 mg · kg−1 · d−1 (Fig. 1G). The extent of axon growth is dose-dependent, with significant sprouting detectable at a dose of 1.2 mg · kg−1 · d−1. The degree of sprouting rostral to the lesion in mice treated subcutaneously compares favorably with that observed in rats treated intrathecally with NEP1–40 (GrandPre et al., 2002).
Delayed NEP1–40 induces extensive axonal sprouting rostral to SCI
When subcutaneous infusions begin at the time of lesion, it is probable that hours to days elapse before peak intrathecal levels are achieved. Thus, it seems plausible that initiation of treatment during the first few hours is not critical. Moreover, the mechanism of NEP1–40 is thought to be dependent on the chronic blockade of axon growth inhibitors, and not on acute neuroprotection. For these reasons, we considered whether the peptide might promote axonal growth when administered in a therapeutic rather than a prophylactic time frame. Systemic NEP1–40 administration was delayed for 3–4 hr after the spinal cord hemisection. To avoid a second period of anesthesia and surgery, once-daily intraperitoneal injections of NEP1–40 were used rather than subcutaneous minipump infusion. This delayed systemic treatment produced the same degree and pattern of CST sprouting as did the immediate subcutaneous and intrathecal infusions (Fig. 1H, gray bars).
To consider the extent of this window of NEP1–40 responsiveness, we began vehicle or NgR antagonist peptide systemic administration 7 d after trauma. Treatment with a full week delay yielded a CST sprouting pattern at 42 d after injury that is remarkably similar to the NEP1–40 treatment immediately after injury at 20 d (Fig. 1E,F). Quantification of these sprouts revealed essentially equal degrees of BDA-labeled CST sprouting (Fig. 1H, black bar).
Examination of parasagittal longitudinal sections from 1 to 4 mm rostral to the lesion reveals that dCST fibers exhibit a large number of branching sprouts in the ventral gray matter area of the NEP1–40-treated animals (Fig. 2C–E) in contrast to the vehicle-treated group (Fig. 2A,B). Counts of such fibers show a >10-fold increase in sprouting density after peptide treatment (Fig. 2F). Sections from animals receiving 7 d delayed systemic NEP1–40 display a similar degree and pattern of CST sprouting (Fig. 2G–I). These findings suggest that systemic NEP1–40 treatment several hours or several days after injury induces almost the same sprouting response as does treatment immediately after injury.
Systemic NEP1–40 is expected to access the CNS and promote sprouting because of the increased permeability in and around the SCI site. To assess the distribution of NEP1–40 effects, we examined sections ranging from the level of the injury rostral to the cervicomedullary junction. The degree of ectopic sprouting is graded along the neuraxis, with the greatest sprouting closer to the lesion site (Fig. 1I). It may be that this distribution is attributable to increased NEP1–40 access near the injury and/or the proximity of the site of sprouting to the axotomy itself. Nonetheless, it is clear that the effects of the systemic NEP1–40 are significant >20 mm rostral to the injury itself.
CST axonal sprouting induced by systemic NEP1–40 crosses the lesion site into the distal spinal cord
Delayed systemic injection of the NgR antagonist peptide induces the rostral CST sprouting. But do these fibers cross the lesion site into the caudal spinal cord to provide functional recovery? Parasagittal sections from vehicle-treated mice show no CST fibers extending beyond the injury site (Fig. 3A,B). Similar sections from delayed systemic NEP1–40-treated mice contain numerous CST fibers that cross the lesion and project into the distal gray and white matter areas in a highly branched pattern (Fig. 3C–F). Immunohistochemical localization of MBP demonstrates that the interruption of myelinated tracts extends from the dorsal surface past the central canal (Fig. 3C, inset). In the vicinity of the lesion, the course of these fibers was typically tortuous (Fig. 3D–F, see Fig. 5B) and quite distinct from the normal straight fibers in the rostral CST. Collaterals and arborized fibers are most frequently seen in the gray matter area. Reconstructions of consecutive sections as camera lucida drawings display the overall distribution pattern of the regenerating CST fibers several millimeters from the lesion (Fig. 4). In control animals, no CST axons extend past the lesion (Fig. 4 A). In the animals treated with systemic NEP1–40 after a 3 hr delay (Fig. 4B–D), some of the regenerating axons bypass the lesion site through remaining tissue bridges of the ventral and ventrolateral gray and white matter, whereas other CST fibers cross the transection area via the lesioned dorsal and dorsolateral part of the spinal cord into distal regions. Notably, in the mice treated with systemic NEP1–40 7 d after SCI, a similar regeneration pattern is seen as in animals treated 3 hr after injury (Fig. 4 E).
The reconstructions demonstrate 9–24 BDA-labeled regenerated fibers coursing in the rostrocaudal axis at any one level between 1 and 4 mm caudal to the lesion in each NEP1–40-treated mouse (Fig. 5C). These sections demonstrate that axons sprout for millimeters beyond the lesion site in the presence of NEP1–40. For transverse sections 5–7 mm below the injury site, NEP1–40 dose-dependently increases the number of CST fibers (Fig. 5D–F). The fiber counts for the systemic NEP1–40-treated animals are approximately half of those at more proximal levels in the sagittal sections. In the more delayed NEP1–40-treated mice (NEP1-40 delivery 7 d after injury), a similar pattern and degree of CST regeneration is observed in sections 5–7 mm distal to hemisection (Fig. 5G–I).
For regenerating CST fibers to contribute to functional recovery, they must form synapses in the caudal spinal cord. Anatomically, synapse formation by CST fibers can be assessed by examining the colocalization of BDA-positive varicosities with synaptophysin. Although ventral fibers are not severed in this model and might theoretically produce such labeling, no double-labeling was observed in over 100 such lumbar sections from untreated SCI mice. This is because of the extremely rare occurrence of ventral spared CST fibers in this mouse model, as opposed to a rat model (Weidner et al., 2001). It is most likely that the easily identified BDA/synaptophysin double-labeling in the NEP1–40-treated samples (Fig. 6A) are associated with fibers regenerating under the influence of the peptide treatment and are consistent with synapse formation. Not surprisingly, these caudal sprouting CST fibers are unmyelinated at this point, 3 weeks after injury (Fig. 6B).
NEP1–40 induces SPRR1A expression and serotonergic fiber sprouting after dorsal spinal cord hemisection
Evidence for axonal regeneration by systemic NEP1–40 treatment can be detected by molecular as well as anatomical methods. One molecular correlate of axonal regeneration is the induction of “growth-associated proteins,” such as SPRR1A (Bonilla et al., 2002). Although peripheral nerve injury induces SPRR1A dramatically, central injury such as SCI does not do so (Bonilla et al., 2002). The combination of systemic NEP1–40 treatment and central axotomy leads to the induction of SPRR1A expression in spinal interneurons and motoneurons both rostral and caudal to the injury (Fig. 7A,B). Numerous SPRR1A-positive axons are also detected in the NEP1–40-treated injured spinal cords (data not shown). In addition to providing additional evidence for NEP1–40-induced axon regeneration, these data suggest that NgR activation may limit axon growth both by acute inhibitory effects on axon growth and by chronic suppression of gene expression patterns associated with successful regeneration. Because SPRR1A expression was not apparent in the motor cortex or in CST fibers (data not shown), this mechanism does not appear to be essential for NEP1–40-induced sprouting after axotomy.
Both descending raphespinal and CST fibers contribute to locomotor function. Dorsal hemisection injures a majority of the serotonergic fibers, decreasing the density of these fibers by >75% in the ventral horn in this mouse SCI model (Fig. 7D). Systemic NEP1–40 dose-dependently restores serotonin fiber density in the ventral horn of the caudal spinal cord to the levels present before injury (Fig. 7C). Thus, the growth-promoting effects of NEP1–40 treatment are not limited to one axonal pathway.
Systemic treatment with NgR antagonist peptide improves locomotor function
Do mice treated with systemic NEP1–40 walk better than control animals after injury? A standardized rat locomotor scoring system was used to assess outcome (Basso et al., 1996). A dose-dependent benefit of systemic NEP1–40 treatment was detectable by 17 d after injury (Fig. 8A). The intermediate dose was nearly as effective as the maximal dose of 11.6 mg · kg−1 · d−1. Although less than half of the vehicle-treated mice (4 of 9) were capable of weight-bearing on the hindlimbs at 17 d after injury, all (14 of 14) mice treated with 3.9 or 11.6 mg · kg−1 · d−1 were weight-bearing at this stage. In contrast to rats treated intrathecally with NEP1–40, no benefit of NEP1–40 was detectable at the earliest stages after injury (GrandPre et al., 2002). This may reflect a more delayed time for systemic NEP1–40 to reach therapeutic levels in the spinal cord.
Our CST tracing experiments indicate that the delayed blockade of NgR with systemic NEP1–40 1 week after axotomy stimulates extensive anatomical regeneration of injured spinal cord descending axons. To determine whether this therapeutic strategy benefits late functional recovery, we examined a battery of behavioral tests. The locomotor BBB score in control animals reaches a stable level of 13 at 3 weeks after the hemisection (Fig. 8B). The slight differences of BBB recovery between these controls and the controls receiving vehicle treatment at the time of injury (Fig. 8A) may be attributable to the toxic effects of systemic DMSO (Cavaletti et al., 2000). At 6 weeks after SCI, all the control mice have frequent, consistent weight-supported plantar steps, but most of them (5 of 7) have only occasional forelimb–hindlimb coordination, with rotation of the predominant paw position when making initial contact with a surface. In contrast, the locomotor score of the delayed systemic NEP1–40-treated mice continues to increase between 2 and 6 weeks after trauma. At 6 weeks after injury, most of the delayed NEP1–40-treated animals (8 of 9) have consistent forelimb–hindlimb coordination and parallel paw position at initial contact with the testing surface.
Two other behavioral tests were used to additionally characterize the performance of the delayed systemic NEP1–40-treated mice. Analysis of hindpaw footprints in vehicle-treated mice demonstrates that stride length is significantly decreased at 6 weeks after SCI, but the stance width is close to normal. For the NEP1–40 mice, the stride length at 6 weeks after injury is close to that of uninjured mice (Fig. 8C,D). In a second test, mice climbed a grid placed at a 45° angle to vertical, and excursions of the hindlimbs below the plane of the grid were counted (Metz et al., 2000). Uninjured mice make no errors on this test (data not shown). In control mice, there are numerous errors, with only minimal improvement between 2 and 6 weeks after injury. In contrast, mice treated systemically with NgR antagonist peptide exhibit a progressive improvement in grid climbing during this period, with the majority of the improvement occurring between 2 and 4 weeks after injury (Fig. 8E).
Discussion
Encouraging progress toward promoting axonal regeneration in the damaged spinal cord has been achieved recently by a variety of methods. Suppression of the action of myelin-derived growth inhibitors (Bregman et al., 1995; Thallmair et al., 1998; GrandPre et al., 2002), reduction of the scar-issue barrier (Bradbury et al., 2002), enhancement of the growth potential of neurons (Bomze et al., 2001; Dergham et al., 2002; Neumann et al., 2002; Qiu et al., 2002), replacement of cells (Li et al., 1997; Ramon-Cueto et al., 2000; Takami et al., 2002), and supplementation with neurotrophic factors (Schnell et al., 1994; Coumans et al., 2001) have been shown to stimulate axonal regrowth and/or functional recovery of injured spinal cord. Nevertheless, these therapies have been administered locally and initiated at the time of spinal cord lesions in most instances. From a clinical point of view, such immediate local therapy may pose logistical problems for the treatment of most human SCIs. In the present study, we show that subcutaneous or intraperitoneal treatment with NgR antagonist peptide induces extensive axonal sprouting and significantly improves locomotive functional recovery. It is likely that NEP1–40 enters the spinal cord through a focally disrupted blood–brain barrier at the SCI site. To our knowledge, this is the first report to describe a systemic therapy to promote axonal regeneration after CNS trauma.
We also show that delayed NEP1–40 treatment stimulates axonal sprouting and promotes locomotor recovery. The therapeutic window for NgR antagonist treatment of subacute SCI is at least 1 week in these studies. At this time point, there is no decrease in the degree of axonal sprouting compared with immediate therapy with NEP1–40. Whether responsiveness declines after several weeks or months in chronic SCI remains to be examined. It is clear that the inherent regenerative capacity of lesioned cortical motor neurons persists at least into the subacute stage of axotomy. In this regard, our results are consistent with the previous reports showing axonal regrowth in chronic injury treated with combinations of neurotrophic factors, fetal spinal cord transplantation, and IN1 antibody (Ye and Houle, 1997; von Meyenburg et al., 1998; Coumans et al., 2001). Our findings demonstrate an extended therapeutic window for the systemic treatment of SCI with Nogo receptor antagonists.
NEP1–40 was identified as an NgR competitive antagonist (GrandPre et al., 2002), and this antagonism is the most probable in vivo mode of action. Several factors argue against an alternative mechanism based on a beneficial immune response to NEP1–40 administration resembling that described for anti-Nogo or antimyelin antibodies (Bregman et al., 1995; Thallmair et al., 1998; Huang et al., 1999). First, the peptide was administered as a lowmolecular-weight soluble compound without adjuvant; therefore, it is highly unlikely to incite an antibody response. Second, immunization studies with a glutathione S-transferase–Nogo-66 protein containing the NEP1–40 sequence in the presence of adjuvant yield no detectable antibody titer to Nogo and no enhanced axonal regenerative response after SCI (S. M. Strittmatter, unpublished observation). Third, a much lower dose of intrathecal NEP1–40 produces an outcome essentially identical to that of systemic NEP1–40 (GrandPre et al., 2002).
SCI is a relatively specific model for studying CNS axon regeneration because the majority of the SCI-related anatomical and functional deficit is attributable to axonal interruption. Several SCI models, including contusions, compressions, and transections (incomplete or complete), have been used for examining experimental treatments. Contusion or compression injuries are widely accepted because they resemble the complex lesions of many clinical SCI cases. Because such models usually produce central gray matter necrosis with variable white matter damage, the discreteness of the anatomical result and its correlation with physiological performance is limited. In contrast, incomplete spinal cord transection, such as dorsal hemitransection, interrupts a group of defined pathways, making it easier to investigate regeneration-promoting therapy (Huang et al., 1999; Brosamle et al., 2000; Coumans et al., 2001; Qiu et al., 2002). Moreover, this model has been used frequently for studying the regeneration-related behavioral alterations (Huang et al., 1999; Bradbury et al., 2002; Dergham et al., 2002; Schucht et al., 2002). Such spinal injuries produce less scar tissue and tissue cavitation in mice than in larger mammals (Steward et al., 1999). Because the primary target of NEP1–40 treatment is myelin-derived inhibition rather than scar-derived inhibition of axon regeneration, the benefits may be more pronounced in mice than in other species. From the current study, it is clear that systemic NEP1–40 treatment induces dramatic improvements in mouse locomotor scores. When administered during the first 2 weeks, NgR antagonist treatment induces a return to weight-bearing on the hindlimbs (BBB score, >9) that is twice as rapid as in control mice. When the NgR antagonist is administered during the 1–3 week period after SCI, significant and persistent locomotor improvements in the 2–6 week period are observed in several measures. Scores of hindlimb coordination and placement are improved compared with vehicle-treated animals (BBB score), stride length returns to that of uninjured mice, and the ability to climb a grid is close to that of uninjured animals.
After SCI, the extent of motor function improvement depends on both the reorganization of segmental circuitry and the restoration of supraspinal input. Our morphologic studies are consistent with previous studies (Bregman et al., 1993) in demonstrating that segmental mechanisms play a major role in the locomotor recovery of spinally injured rodents under control conditions, because no CST regrowth is detected. In principle, enhanced plasticity at the segmental level might contribute to functional improvement in the NgR antagonist-treated mice. However, we have no anatomical data to support this hypothesis. There are several lines of evidence indicating that the restoration of supraspinal input to the lumbar cord participates in the functional improvement. First, BDA traces regenerated fibers across the lesion site and into the caudal part of the spinal cord after NgR antagonist treatment. For example, at 1–4 mm caudal to the transection site, 9–24 regenerated fibers were seen in each NEP1–40-treated mice. Near the lesion site, some regenerating dCST fibers circumvent the lesion through the ventral part of gray or white matter of the cord, whereas others course through the lesioned dorsal or lateral spinal cord. Even at 5–7 mm distal to SCI, 5–18 BDA-labeled fibers are detectable in transverse sections of NEP1–40-treated mice. The total number of regenerated axons may be much greater than that observed here, because this anterograde BDA tracing method labels only a fraction of total CST fibers (Brosamle and Schwab, 1997). Second, the synaptic marker synaptophysin is localized to the varicosities of BDA-labeled axons at the lumbar levels of spinal cord, demonstrating anatomical reconnection between sprouting CST fibers and distal spinal cord neurons. On a numerical basis, the camera lucida reconstructions suggest that a majority of such distal CST fibers in systemic NEP1–40-treated mice derive from sprouted dCST fibers. However, it remains plausible that distal sprouts from the rare ventral CST (vCST) fibers are also involved in the synaptic reorganization after NEP1–40 application. Spontaneous structural plasticity in vCST is known to correlate with rat functional recovery after SCI (Weidner et al., 2001). Third, the serotonergic axon growth induced by peptide NEP1–40 demonstrates that NgR antagonism can promote regeneration in multiple descending pathways that may play a role in locomotor recovery. The widespread neuronal distribution of the NgR (Wang et al., 2002c) makes it likely that additional fiber systems are responsive to NEP1–40 and contribute to the improved performance of spinal cord-injured mice after NEP1–40 treatment. In particular, the sprouting of injured rubrospinal fiber may also contribute to functional improvements. Similarly, the reorganization of spared pathways, such as descending ventrolateral fibers (Brustein and Rossignol, 1998), may also contribute to functional recovery (Raineteau et al., 2001). Together, the CST tracing, the 5-HT staining and the BDA/synaptophysin colocalization indicate the restoration of supraspinal inputs plays a significant role in the pronounced functional recovery after systemic NgR antagonist treatment.
The present study reveals that systemic NgR antagonist peptide stimulates anatomical sprouting and caudal growth of both CST and raphespinal fibers, and induces upregulation of growth-associated proteins in the spinal cord. Importantly, systemic administration of NgR antagonist, even applied in the subacute/chronic stage, yields a concomitant improvement in locomotor function. The ability of systemic NEP1–40 treatment in mice to match intrathecal effects in rats supports the notion that the blood–brain barrier breakdown after trauma provides a therapeutic window for the administration of regeneration-promoting reagents that might not otherwise gain access to the CNS. It is clear that subacute traumatic CNS axonal injuries can be successfully treated in mice by the delayed systemic administration of an NgR antagonist. The NEP1–40 peptide selectively blocks Nogo-66 action (GrandPre et al., 2002) but not myelin-associated glycoprotein action (Liu et al., 2002) at the NgR. Thus, more general NgR antagonists might be even more effective systemic therapeutics for promoting recovery after adult CNS axotomies such as SCI.
Footnotes
This work was supported by grants from the Christopher Reeve Paralysis Foundation (S.L.) and from the National Institutes of Health, the McKnight Foundation for Neuroscience, and Biogen, Inc.(S.M.S.).S.M.S.is an Investigator of the Patrick and Catherine Weldon Donaghue Medical Research Foundation. We thank Yiguang Fu for expert technical assistance.
Correspondence should be addressed to Dr. Stephen M. Strittmatter, Department of Neurology and Section of Neurobiology, Yale University School of Medicine, P.O. Box 208018, New Haven, CT 06520. E-mail: stephen.strittmatter{at}yale.edu.
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