After a lesion of the mature CNS, structural plasticity and functional recovery are very limited, in contrast to the developing CNS. The postnatal decrease in plasticity is correlated in time with the formation of myelin. To investigate the possible role of an important myelin-associated neurite growth inhibitor (NI-250; IN-1 antigen), one pyramidal tract of adult Lewis rats was lesioned (pyramidotomy), and the rats were treated with the antibody IN-1, a control antibody, or no antibody. Functional recovery was studied from postoperative day 14 until day 42 using a food pellet reaching task, rope climbing, and a grid walk paradigm. The corticofugal projections to the red nucleus and basilar pontine nuclei were analyzed after survival times of 2 and 16 weeks.Treatment with the monoclonal antibody IN-1 resulted in almost complete restoration of skilled forelimb use, whereas all the control groups showed severe and chronic impairments. This functional recovery was paralleled by sprouting of the corticorubral and the corticopontine fibers across the midline, thus establishing a bilateral, anatomically specific projection.
Key words: structural plasticity; rat reaching; motor function; motor system; nucleus ruber; pons; corticospinal tract; injuryFunctional and anatomical repair of the injured adult C NS is very limited (for review, see Donoghue, 1995Donoghue, , 1997Schwab and Bartholdi, 1996). In contrast, neuroanatomical plasticity, or the restructuring of neural connections in response to lesions of the CNS, is a well documented phenomenon in the neonatal age group. After unilateral neonatal pyramidotomy in rodents, corticoefferent fibers from the same side as the lesion were found to cross the midline to form new connections with medullary nuclei and to descend to spinal cord levels . Evidence that new neural connections occur after perinatal brain damage in children is supported by several clinical studies (Farmer et al., 1991;C arr et al., 1993;C ao et al., 1994). Structural neuroplasticity is thought to play an essential role in recovery of function, because animals sustaining C NS lesions at a young age are known to recover much better than those sustaining similar lesions at maturity (Kennard, 1936(Kennard, , 1938Whishaw and Kolb, 1988;Armand and Kably, 1993).The lack of large scale remodeling after adult C NS lesions is not well understood, but may be attributable to several reasons, including a limitation of adult neuronal growth potential, a lack or decrease in trophic factors or guidance molecules, or the presence of growth inhibitory molecules. In this regard, limits on the capacity for mature CNS plasticity may be similar to those recently identified for CNS regeneration, for which inhibitory signals present on CNS myelin have been shown to play a crucial role (for review, see Schwab and Bartholdi, 1996). These specific proteins (NI-35 and NI-250) induce long-lasting growth cone collapse and inhibition of neurite growth in vitro (Caroni and Schwab, 1988a;Bandtlow et al., 1990). Neutralization by the s...
