Scientific Commentary |
Promoting anatomical plasticity and recovery of function after traumatic injury to the central or peripheral nervous system
Neuroscience Centre, Institute of Cell and Molecular Science, Queen Mary University of London, 4 Newark Street, London E1 2AT, UK
Correspondence to: E-mail: j.v.priestley{at}qmul.ac.uk
Traumatic brain or spinal cord injury (SCI) has devastating consequences for patients, and can lead to life-long disability. However, even in the most serious cases, there is normally some recovery of function. For example, 73% of patients who initially present with complete paralysis but sacral sensory sparing recover some motor function within a year (Marino et al., 1999
). The mechanisms of this recovery are still poorly understood and are likely to include the following: reduction of local ischaemia, oedema and inflammation; recovery from spinal shock of traumatized but undamaged pathways; remyelination of demyelinated axons; functional synaptic plasticity allowing spared pathways to take over the lost functions; and anatomical plasticity leading to new, and functionally effective, circuitry. In the past few years it has become apparent that the last of these possibilities, anatomical plasticity, may play a significant role. Although the CNS is not able to regenerate a major pathway such as the corticospinal tract, there is accumulating evidence that some pathways are able to sprout locally to establish novel circuits that restore a limited degree of function. The key question is, can such plasticity be promoted to enable patients to recover complex functions such as fine hand control? This exciting possibility is addressed by two papers in this issue of Brain from James Fawcett and colleagues at the Cambridge Centre for Brain Repair (Galtrey et al., 2007; Smith et al., 2007).
After injury to a pathway such as the corticospinal tract, axons normally die back a short distance but then initiate a regenerative response which is unsuccessful and confined to local sprouts at the injury site (Kerschensteiner et al., 2005). However recent studies have demonstrated that both damaged and undamaged pathways distant from the injury site can sprout to establish functional connections (Raineteau and Schwab, 2001). For example, a complete cervical transection of the dorsal corticospinal tract results in sprouting across the midline by axons from the spared ventral corticospinal tract. Some of these axons innervate motoneurons and contribute to recovery of function (Weidner et al., 2001; Bareyre et al., 2005). In addition, lesioned corticospinal tract axons can sprout into the intact grey matter and establish novel circuits with long axon propriospinal neurons that bypass the lesion site (Bareyre et al., 2004). This ‘natural’ anatomical plasticity is very limited, but there is a growing literature showing that it can be enhanced by pharmacological procedures that counteract CNS growth-inhibitory components. These components fall into two main categories, namely constituents of CNS myelin such as Nogo-A, myelin-associated glycoprotein (MAG) and oligodendrocyte myelin glycoprotein (OMgp) and extracellar matrix molecules such as chondroitin sulphate proteoglycans (CSPGs). Nogo-A, MAG and OMgp signal through the Nogo-A receptor (NgR) to activate the small GTPase RhoA and downstream pathways that cause growth cone collapse (Filbin, 2003). Strategies for overcoming this inhibition include Nogo-A blocking antisera; NgR antagonists or soluble forms of NgR which sequester Nogo-A; and agents that block Rho. Less is known about the pathways that underlie inhibition by CSPGs, but they may also act to stimulate Rho. In addition CSPGs bind many growth stimulatory and inhibitory factors and affect the way such factors interact with their receptors (Carulli et al., 2005). CSPGs are important constituents of glial scars, but are also major components of perineuronal nets. CSPG inhibition can be reduced by removing their glycosaminoglycan (GAG) sidechains with the enzyme chondroitinase ABC (ChABC).
Initial studies with agents such as Nogo-A blocking antisera or ChABC focused mainly on their ability to promote regeneration (e.g. Schnell and Schwab, 1993; Bradbury et al., 2002). However several recent papers have demonstrated spectacular effects on anatomical plasticity, which may be more important for functional recovery than the effects on regeneration (Bradbury and McMahon, 2006). Thus anti-Nogo-A treatment following a corticospinal tract lesion promotes sprouting into the contralateral red nucleus and pons by lesioned axons above the injury site and this sprouting appears to contribute to functional recovery (Thallmair et al., 1998). Sprouting by intact rubrospinal pathways into denervated areas is increased below the injury site (Raineteau et al., 2001). A similar reorganization of motor pathways takes place when anti-Nogo-A is given after unilateral ablation of the motor cortex. The intact corticospinal tract sprouts into the contralateral denervated red nucleus and pons (Wenk et al., 1999) and electrical stimulation of the intact cortex promotes movement of the ipsilateral lesion-impaired forelimb (Emerick et al., 2003). The article in this issue of Brain by Smith and colleagues (Smith et al., 2007) provides another example of such anatomical plasticity, but with a different injury model and a different pharmacological agent (the purine nucleoside, inosine). Inosine has previously been shown to promote anatomical sprouting by intact corticospinal and corticobulbar projections after a cortical infarct or corticospinal tract lesion (Benowitz et al., 1999; Benowitz et al., 2002; Chen et al., 2002). Smith and colleagues now show that inosine also promotes anatomical sprouting and recovery of function after traumatic brain injury. In a rodent impact injury model, a 2-week intraventricular infusion of inosine led to a more rapid and complete recovery of skilled forelimb use, which was accompanied by sprouting of corticorubral and corticospinal projections across the midline into denervated areas. The exact mechanism of action of inosine is unknown, but it has recently been shown to activate a protein kinase (Mst3b) that is also activated by NGF and BDNF and that regulates axonal outgrowth (Irwin et al., 2006).
The second article in this issue of Brain also addresses the question of whether anatomical plasticity can be harnessed to promote recovery of precise motor function, but in the context of peripheral nervous system (PNS) injury (Galtrey et al., 2007). Although regeneration in the PNS is very efficient, functional recovery is often only partial. For example, satisfactory sensory recovery following median or ulnar nerve injuries is achieved in only 43% of patients, and satisfactory motor recovery in only 52% (Ruijs et al., 2005). The main reason for this appears to be misdirected re-innervation, i.e. motor and sensory axons reconnecting to inappropriate targets, and a consequent scrambling of the cortical somatosensory map (Lundborg, 2000). Various attempts have been made to improve the accuracy of reinnervation by treating the PNS injury site with factors that either promote and direct regeneration, or reduce polyinnervation. However they have had only limited success (e.g. Angelov et al., 2005). Galtrey and colleagues now show that treatment of the spinal cord with an agent that is known to promote anatomical plasticity (ChABC) can compensate for poor PNS regeneration. In a rodent injury model, they examined the effect on skilled forelimb use of various types of injury and repair to the median and ulnar nerves, including either crush, cut and correct repair, or cut and incorrect repair (median to ulnar, ulnar to median). As would be expected, skilled forelimb use and grip strength recovered best after crush injury, and were worst after incorrect repair. However ChABC injected into the cervical cord 4 weeks after surgery led to an improved recovery of skilled forelimb use after correct repair, and improved recovery of grip strength after incorrect repair. The authors demonstrate that the ChABC treatment promotes sprouting in the spinal cord (probably due to digestion of perineuronal nets), but otherwise did not examine the mechanism responsible for functional recovery. However, they propose that rewiring of spinal circuits may compensate for misdirected peripheral re-innervation by motor and sensory neurons.
These results show that recovery of fine motor function after traumatic brain or peripheral nerve injury can be promoted by enhancing anatomical sprouting in the CNS. However, several key questions remain to be answered, some of which are critical for translation to the clinic. First, since the agents in question have effects not only on anatomical plasticity but also on axonal regeneration and possibly also cell survival (see e.g. Hasko et al., 2004), there is the problem of determining which particular effect is responsible for the functional improvements. Secondly, it is still not clear what exactly the triggers are for anatomical sprouting and which systems are susceptible. For example, the extent of sprouting appears highly dependent on the type of injury (compare Bareyre et al., 2004; Vavrek et al., 2006) and the particular anatomical system (Oudega et al., 2000; MacDermid et al., 2004). In the case of ChABC, application to the intact spinal cord has no effect (Barritt et al., 2006) but with peripheral nerve injury (which involves no direct injury to the spinal cord) it is effective (Galtrey et al., 2007). Most studies have examined acute effects and little is known about the extent to which delayed treatment is effective (Li and Strittmatter, 2003). Thirdly, and most crucially, not all sprouting is beneficial. In addition to sprouting that appears to be anatomically appropriate, aberrant sprouting has been reported (Barritt et al., 2006). In the case of primary afferents, such sprouting may give rise to neuropathic pain (Hofstetter et al., 2005; Barritt et al., 2006). It would be disastrous if a plasticity-promoting treatment made a patient worse. We currently know very little about how to direct anatomical plasticity to beneficial ends. However one study indicates that a process of pruning takes place, whereby functionally beneficial pathways are consolidated and ‘inappropriate’ ones lost over time (Bareyre et al., 2004). If this is the case, the solution may be to combine a pharmacological treatment with physiotherapy. Smith and colleages suggest that in patients ‘the most effective use of plasticity-inducing treatments will be to open a window during which intensive rehabilitation can drive plasticity in useful directions’ (Smith et al., 2007). This is a very exciting possibility, and likely to be a very fruitful area for further investigation.
 |
Acknowledgements |
|---|
Work in the author's laboratory is supported by the Corporate Action Trust, International Spinal Research Trust, and BBSRC.
|
References |
|---|
 Top References |
|---|
Angelov DN, Guntinas-Lichius O, Wewetzer K, Neiss WF, Streppel M. (2005) Axonal branching and recovery of coordinated muscle activity after transection of the facial nerve in adult rats. Adv Anat Embryol Cell Biol 180:1–130.[Medline]
Bareyre FM, Kerschensteiner M, Misgeld T, Sanes JR. (2005) Transgenic labeling of the corticospinal tract for monitoring axonal responses to spinal cord injury. Nat Med 11:1355–60.[CrossRef][ISI][Medline]
Bareyre FM, Kerschensteiner M, Raineteau O, Mettenleiter TC, Weinmann O, Schwab ME. (2004) The injured spinal cord spontaneously forms a new intraspinal circuit in adult rats. Nat Neurosci 7:269–77.[CrossRef][ISI][Medline]
Barritt AW, Davies M, Marchand F, Hartley R, Grist J, Yip P, et al. (2006) Chondroitinase ABC promotes sprouting of intact and injured spinal systems after spinal cord injury. J Neurosci 26:10856–67.
Benowitz LI, Goldberg DE, Madsen JR, Soni D, Irwin N. (1999) Inosine stimulates extensive axon collateral growth in the rat corticospinal tract after injury. Proc Natl Acad Sci USA 96:13486–90.
Benowitz LI, Goldberg DE, Irwin N. (2002) Inosine stimulates axon growth in vitro and in the adult CNS. Prog Brain Res 137:389–99.[ISI][Medline]
Bradbury EJ and McMahon SB. (2006) Spinal cord repair strategies: why do they work? Nat Rev Neurosci 7:644–53.[CrossRef][ISI][Medline]
Bradbury EJ, Moon LD, Popat RJ, et al. (2002) Chondroitinase ABC promotes functional recovery after spinal cord injury. Nature 416:636–40.[CrossRef][Medline]
Carulli D, Laabs T, Geller HM, Fawcett JW. (2005) Chondroitin sulfate proteoglycans in neural development and regeneration. Curr Opin Neurobiol 15:116–20.[CrossRef][ISI][Medline]
Chen P, Goldberg DE, Kolb B, Lanser M, Benowitz LI. (2002) Inosine induces axonal rewiring and improves behavioral outcome after stroke. Proc Natl Acad Sci USA 99:9031–6.
Emerick AJ, Neafsey EJ, Schwab ME, Kartje GL. (2003) Functional reorganization of the motor cortex in adult rats after cortical lesion and treatment with monoclonal antibody IN-1. J Neurosci 23:4826–30.
Filbin MT. (2003) Myelin-associated inhibitors of axonal regeneration in the adult mammalian CNS. Nat Rev Neurosci 4:703–13.[CrossRef][ISI][Medline]
Galtrey CM, Asher RA, Nothais F, Fawcett JW. (2007) Promoting plasticity in the spinal cord with chondroitinase improves functional recovery after peripheral nerve repair. Brain.
Hasko G, Sitkovsky MV, Szabo C. (2004) Immunomodulatory and neuroprotective effects of inosine. Trends Pharmacol Sci 25:152–7.[CrossRef][Medline]
Hofstetter CP, Holmstrom NA, Lilja JA, et al. (2005) Allodynia limits the usefulness of intraspinal neural stem cell grafts; directed differentiation improves outcome. Nat Neurosci 8:346–53.[CrossRef][ISI][Medline]
Irwin N, Li YM, O'Toole JE, Benowitz LI. (2006) Mst3b, a purine-sensitive Ste20-like protein kinase, regulates axon outgrowth. Proc Natl Acad Sci USA 103:18320–5.
Kerschensteiner M, Schwab ME, Lichtman JW, Misgeld T. (2005) In vivo imaging of axonal degeneration and regeneration in the injured spinal cord. Nat Med 11:572–7.[CrossRef][ISI][Medline]
Li S and Strittmatter SM. (2003) Delayed systemic Nogo-66 receptor antagonist promotes recovery from spinal cord injury. J Neurosci 23:4219–27.
Lundborg G. (2000) A 25-year perspective of peripheral nerve surgery: evolving neuroscientific concepts and clinical significance. J Hand Surg [Am] 25:391–414.[Medline]
MacDermid VE, McPhail LT, Tsang B, Rosenthal A, Davies A, Ramer MS. (2004) A soluble Nogo receptor differentially affects plasticity of spinally projecting axons. Eur J Neurosci 20:2567–79.[CrossRef][ISI][Medline]
Marino RJ, Ditunno JF Jr, Donovan WH, Maynard F Jr. (1999) Neurologic recovery after traumatic spinal cord injury: data from the Model Spinal Cord Injury Systems. Arch Phys Med Rehabil 80:1391–6.[CrossRef][ISI][Medline]
Oudega M, Rosano C, Sadi D, Wood PM, Schwab ME, Hagg T. (2000) Neutralizing antibodies against neurite growth inhibitor NI-35/250 do not promote regeneration of sensory axons in the adult rat spinal cord. Neuroscience 100:873–83.[CrossRef][ISI][Medline]
Raineteau O, Fouad K, Noth P, Thallmair M, Schwab ME. (2001) Functional switch between motor tracts in the presence of the mAb IN-1 in the adult rat. Proc Natl Acad Sci USA 98:6929–34.
Raineteau O and Schwab ME. (2001) Plasticity of motor systems after incomplete spinal cord injury. Nat Rev Neurosci 2:263–73.[CrossRef][ISI][Medline]
Ruijs AC, Jaquet JB, Kalmijn S, Giele H, Hovius SE. (2005) Median and ulnar nerve injuries: a meta-analysis of predictors of motor and sensory recovery after modern microsurgical nerve repair. Plast Reconstr Surg 116:484–94.[CrossRef][ISI][Medline]
Schnell L and Schwab ME. (1993) Sprouting and regeneration of lesioned corticospinal tract fibres in the adult rat spinal cord. Eur J Neurosci 5:1156–71.[CrossRef][ISI][Medline]
Smith JM, Lunga P, Story D, Harris N, Le Belle J, James MF, et al. (2007) Inosine promotes recovery of skilled motor function in a model of focal brain injury. Brain.
Thallmair M, Metz GA, Z'Graggen WJ, Raineteau O, Kartje GL, Schwab ME. (1998) Neurite growth inhibitors restrict plasticity and functional recovery following corticospinal tract lesions. Nat Neurosci 1:124–31.[CrossRef][ISI][Medline]
Vavrek R, Girgis J, Tetzlaff W, Hiebert GW, Fouad K. (2006) BDNF promotes connections of corticospinal neurons onto spared descending interneurons in spinal cord injured rats. Brain 129:1534–45.
Weidner N, Ner A, Salimi N, Tuszynski MH. (2001) Spontaneous corticospinal axonal plasticity and functional recovery after adult central nervous system injury. Proc Natl Acad Sci USA 98:3513–8.
Wenk CA, Thallmair M, Kartje GL, Schwab ME. (1999) Increased corticofugal plasticity after unilateral cortical lesions combined with neutralization of the IN-1 antigen in adult rats. J Comp Neurol 410:143–57.[CrossRef][ISI][Medline]
CiteULike 
Connotea 
Del.icio.us What's this?
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||