Abstract
Precisely localized focal stereotaxic electrolytic lesions were made in the corticospinal tract at the level of the first to second cervical segments in the adult rat. This consistently destroyed all central nervous tissue elements (axons, astrocytes, oligodendrocytes, microglia, and microvessels) in a highly circumscribed area.
In a group of these rats immediately after lesioning, a suspension of cultured adult olfactory ensheathing cells was transplanted into the lesion site. Within the first week after transplantation, the cut corticospinal axons (identified by anterograde transport of biotin dextran) extended caudally along the axis of the corticospinal tract as single, fine, minimally branched sprouts that ended in a simple tip, often preceded by a small varicosity. By 3 weeks, the regenerating axons, ensheathed by P0-positive peripheral myelin had accumulated into parallel bundles, which now extended across the full length of the lesioned area and reentered the caudal part of the host corticospinal tract.
The transplants contained two main types of cells: (1) p75-expressing S cells, which later formed typical peripheral one-to-one myelin sheaths around individual ensheathed axons, and (2) fibronectin-expressing A cells, which aggregated into tubular sheaths enclosing bundles of myelinated axons. The point of reentry of the axons into the central nervous territory of the caudal host corticospinal tract was marked by the resumption of oligodendrocytic myelination. Thus the effect of the transplant was to form a “patch” of peripheral-type tissue across which the cut central axons regenerated and then continued to grow along their original central pathway.
- regeneration
- olfactory ensheathing cells
- corticospinal tract
- white matter
- adult spinal cord repair
- axon growth
- myelinated tracts
- transplantation
Transplants of peripheral nerve into the visual system have established that cut axons can reestablish functional connections in the adult CNS (Vidal-Sanz et al., 1987). The transplants recruited axons from the retinal ganglion cells, bypassed their normal retinofugal pathways through the optic nerve, and delivered the regenerating fibers directly to the deafferented terminal field in the tectum. In practice, however, most injuries involve multiple fiber systems. In these situations, repair would require that the regenerating axons reenter their original tracts to be distributed to their correct terminal sites.
Myelinated fiber tracts of the adult CNS have a complex and regular arrangement of three types of glial cells (Suzuki and Raisman, 1992). When a tract is damaged, the cut axons produce local sprouts at the site of injury (Ramon y Cajal, 1928; Li and Raisman, 1995), but even with minimal disturbance to the tract glial framework (Davies et al., 1996), the sprouts did not reenter the distal part of the tract.
To make the damaged tracts favorable for the regeneration of cut adult axons, we (Li and Raisman, 1994, 1997) and others (Xu et al., 1997) have studied transplantation of cultured Schwann cells. Schwann cells integrate into the host tract glial structure (Brook et al., 1993; Li and Raisman, 1997). They greatly increase axon sprouting in lesions of the corticospinal tract (CST), but few sprouts reenter the distal tract (Li and Raisman, 1994). The reluctance of axon sprouts to leave the Schwann cell environment of the transplant and reenter the glial environment of the distal CST resembles the inability of regenerating cut dorsal root fibers to leave the peripheral nerve/Schwann cell environment of the dorsal roots and reenter the glial environment of the dorsal spinal cord (Bignami et al., 1984).
To identify a source of cells that might enable the regenerating axons to reenter the host CST, we therefore sought a situation in which adult axons are normally able to enter the CNS. In the olfactory system, the sensory neurons are replaced throughout adult life, and the newly formed axons continually reenter the CNS (Moulton, 1974; Barber and Raisman, 1978a,b; Graziadei and Montigraziadei, 1979, 1980; Wilson and Raisman, 1981). The entry point of the olfactory axons into the olfactory bulb is associated with special glial cells, known as olfactory ensheathing cells (OECs) (Blanes, 1898; Raisman, 1985;Valverde and Lopez-Mascaraque, 1991; Ramón-Cueto and Nieto-Sampedro, 1992; Barnett et al., 1993). Ramón-Cueto and collaborators (Ramón-Cueto and Nieto-Sampedro, 1994) reported that transplants of cultured OECs mediate the reentry of regenerating dorsal root axons into the dorsal spinal gray matter and that injections of OECs increased axon growth into Schwann cell-filled guidance channels transplanted into the spinal cord (Ramón-Cueto et al., 1998).
In the present study we injected cultured OECs into focal lesions in the rat CST. This experimental paradigm optimizes the opportunity for repair by ensuring that (1) damage is largely restricted to a single tract, (2) the cut axon sprouts come at once into direct contact with the transplanted cells, (3) the distance to be crossed by the regenerating axons is minimized, and (4) the advancing sprouts find themselves in direct contact and alignment with the distal part of their own tract.
Under these highly defined circumstances we observed that OECs induced rapid, aligned growth of cut CST axon sprouts across the lesion and into the caudal CST. In the present paper we describe the unique morphology of these regenerating axons and the cellular arrangements by which the OECs form a bridge conveying them across the lesion and mediating their reentry. In a companion study we have shown that this regeneration can restore lost functions (Li et al., 1997).
MATERIALS AND METHODS
Cell cultures. Syngeneic cells from the outer (nerve fiber and glomerular) layers of adult female AS rat olfactory bulbs were plated out, as in the method of Ramón-Cueto and Nieto-Sampedro (1992), but without purification. Before transplantation, the cells were cultured for 14–17 d in DMEM/F12 Nutrient Mix + 10% fetal calf serum (Life Technologies, Gaithersburg, MD). Immunostaining (Fig. 1) confirmed that after 10–20 d, the cultured cells had segregated into clusters of the two major cell types described by Doucette and Devon (1994),Barnett et al. (1993), and Ramón-Cueto and Nieto-Sampedro (1992): (1) p75LOW AFFINITY NEUROTROPHIN RECEPTOR +, S100+ S cells (named after their resemblance to Schwann cells), and (2) vimentin+ fibronectin (FN)+ A cells (named after a resemblance to astrocytes; but see comment in Discussion). A proportion of both cell types stained with GFAP. At higher power and lower cell density, individual S cells can be seen as elongated, fine spindles, and A cells as more flattened.
Surgical procedures. Details of the procedures are given inLi and Raisman (1994). Briefly, the corticospinal tract was destroyed in 129 adult female rats (200–240 gm body weight) of a locally bred AS strain by a current of 10 μA passed for 8–10 min through a stainless steel electrode inserted stereotaxically on one side between the first and second cervical segments. In 86 rats after lesioning, the electrode was withdrawn, a glass micropipette was inserted into the same position, and 3–5 μl of a suspension containing ∼100,000 cultured OECs was injected into the lesion site. In 73 rats (22 with lesions alone, 51 with lesions and transplanted OECs), the corticospinal axons were anterogradely labeled, at 6–10 d before rats were killed, by injection of biotin dextran (BD) either into the contralateral medullary pyramids or spanning the entire contralateral sensorimotor cortex.
Perfusion and preparation of material. After survivals of 6 d to 3 months (n = 10 at 6 d, 19 at 10 d, 7 at 2 weeks, 21 at 3 weeks, 51 at 4 weeks, 4 at 6 weeks, 3 at 7 weeks, 11 at 9 weeks, 3 at 3 months), (1) 26 operated rats (11 with lesions alone, 15 with lesions and transplanted OECs) and 5 normal rats were perfused with PBS, and immunohistochemical analysis was performed on 10 μm cryostat sections; (2) 73 rats (22 with lesion alone, 51 with lesions and transplanted OECs) were fixed by perfusion with a mixture of 4% paraformaldehyde and 0.15% glutaraldehyde and 0.4% picric acid in 0.1 m phosphate buffer (PB), and 100-μm-thick vibratome sections were used for light microscopic visualization of BD (n = 52), for confocal analysis of the whole transplant region (n = 15), or for electron microscope immunohistochemistry (n = 6); and (3) for electron microscopy, 30 rats (10 with lesions alone, 20 with lesions and transplanted OECs) were fixed with a mixture of 1% paraformaldehyde and 1% glutaraldehyde in PB, and 200-μm-thick vibratome sections taken through the CST were osmicated, dehydrated, and flat-embedded in resin, semithin (1–2 μm) sections were stained with 1% methylene blue and Azur II, and ultrathin sections were stained with uranyl acetate and lead citrate.
Histology. For single antibody application, 10 μm cryostat sections were fixed in acid alcohol or 4% paraformaldehyde in PB and incubated with the primary antibody as in Table1. The secondary antibody (anti-mouse or anti-rabbit as appropriate) was either directly conjugated to HRP (1:100) or biotinylated (1:500) and developed in ABC (1:300; Vector, Burlingame, CA). For simultaneous visualization of p75 and FN or P0 and MOG, the fixed cultures or cryostat sections were incubated with the first primary and then the appropriate secondary antibodies (as in Table 1), visualized by diaminobenzidine (DAB) (brown) or by nickel-glucose oxidase (Ni-GOD) (black) (Li and Raisman, 1995), followed by incubation with the second primary antibody, and the appropriate secondary antibody was visualized with VIP (Vector) (purple).
For light microscopy, BD was visualized with Ni-GOD. For electron microscopy of BD, the sections were frozen and thawed (Henry et al., 1994) before ABC incubation. For confocal microscopy, the sections were incubated with p75 (1:100) and ABC overnight, washed in PBS, and incubated in biotinylated secondary antibody (1:200) for 1 hr. The BD-labeled axons were visualized with avidin–fluorescein (green), and the transplanted OECs were visualized with avidin–rhodamine (red).
RESULTS
The corticospinal axons were identified by BD anterograde labeling and by selective immunostaining for α calcium/calmodulin-dependent protein kinase II (CaMII) ((Terashima, 1995) (Fig.2A,B). They form a compact, well delineated tract of ∼0.5 mm diameter, located in the ventromedial part of the dorsal columns, ventral to the gracile and cuneate fasciculi. The CST consists of ∼50,000 axons on each side; the large majority are myelinated. In semithin or ultrathin sections or with neurofilament (NF) immunohistochemistry (Fig. 2C), they are distinguished from the larger myelinated ascending sensory axons of the gracile and cuneate fasciculi by their rather uniform diameter (∼1 μm) and by their much higher glial density.
Lesions
The lesions were largely confined to the CST (Fig.3), and they destroyed an ovoid area of tissue ∼0.5 mm in width and 0.5–1.0 mm in rostrocaudal length. The area of total destruction of the host spinal tissue was clearly demarcated from the myelinated fiber bundles of the adjacent intact spinal tracts with their associated cellular framework of astrocytes, oligodendrocytes, and microglia. Within the lesioned areas, all CNS components were completely eliminated. This was shown by light microscopic immunohistochemistry of CAMII and NF for axons, CC1 for oligodendrocytes (Shuman et al., 1997), OX42 for ramified microglia, and GFAP for astrocytes. Semithin and ultrathin sections confirmed these conclusions and showed that the lesioned area contained only debris and amoeboid macrophages.
As described in a previous publication (Li and Raisman, 1995), the cut ends of the CST axons arborized in the rostral part of the lesioned area (Fig. 4), but in none of the 69 animals with lesions alone (i.e., with no transplanted OECs) in this or the previous series were there any situations in which we have observed such axons to cross the lesioned area.
General morphology of OEC transplants
The transplanted OECs formed a conspicuous, densely hypercellular mass, enclosed within the ovoid, smoothly outlined lesioned area, and elongated along the axis of the host CST. Immunostaining for p75, fibronectin, GFAP, L1, and laminin (Fig.5) clearly shows the position, size, and shape of the mass of transplanted cells. Compared with lesions alone, where a dense astrocytic scar develops in the host CST (Li and Raisman, 1995), there is only a slight upregulation of GFAP in the immediately adjacent host tract astrocytic processes. As in the case of transplants of embryonic central neural tissue (e.g., Lawrence et al., 1984) or cultured peripheral nerve Schwann cells (Brook et al., 1993; Li and Raisman, 1997), the transplanted OECs are highly angiogenic, and from the earliest times they induce a dense plexus of microvessels (clearly shown by laminin immunostaining) (Fig. 5E,F), which contrasts conspicuously with the low vascularity characteristic of the surrounding white matter.
Rostral and caudal to the transplants, there is considerable disorganization of the proximal and distal host CST caused by retrograde and orthograde axonal degeneration, fragmentation of myelin, and major invasion of macrophages, and phagocytic activity by microglia, macrophages, and astrocytes. From the earliest times observed, the individual transplanted OECs in the lesioned area become elongated along the tract axis and migrate both rostrally and caudally into the host CST. Later (see Fig. 11) the caudally directed migration becomes very prominent.
Axon response
From the earliest times observed (6 d), the BD-labeled regenerating cut corticospinal axons in contact with the transplanted OECs adopt a unique morphology (Fig. 6). The regenerating axons are slightly expanded in diameter as they enter the transplanted area, and they have a moderate number of varicosities. The trajectory of the individual BD-labeled axons is constrained within the longitudinal rostrocaudal axis of the CST. The axons appear almost entirely unbranched, except for occasional spine-like protrusions, and they taper to a diameter of ∼0.1–0.2 μm. Through-focus examination of the full thickness of the 100-μm-thick vibratome sections clearly shows that at earlier survivals (6–10 d), the axons have minute, simple tips (Fig. 6, asterisks), which can be clearly seen to end freely, within the thickness of the block of tissue included in the sections. From as early as 10 d, some regenerating axons have completely traversed the central part of the transplants, and their free tips have already left the caudal end of the mass of transplanted OECs and continued in a straight line, to end at a distance of ≥1 mm into the distal part of the host CST.
Electron microscopy of transplanted cell types
S cells
We identify the S cells by their resemblance to the transplanted Schwann cells seen in our previous studies (Li and Raisman, 1994). The S cells (Fig.7A, indicated by S) are solitary and have overall rounded outlines with dark cytoplasm and smooth, rounded dark nuclei with dark areas of heterochromatin. The cell surfaces emit microvillous processes, and from the earliest times observed, S cell processes make direct membrane contact with the axons, forming very thin, single layers, intimately investing the individual axons and their varicosities, and extending all the way to their tips (Fig. 8). Cross sections (Fig.9) show that the single S cell processes can ensheathe multiple, small-diameter axon sprouts (as in developing or unmyelinated peripheral nerve). From as early as 10 d, the abaxonal surfaces of the S cells are covered by a basal lamina (Fig. 9,arrowheads) facing a collagen-containing extracellular space.
A cells
Compared with the S cells, the A cells (Fig. 7A, indicated by A) are larger and more elongated, with paler cytoplasm, containing lipid droplets, and larger, paler nuclei with more irregularly shaped, somewhat rectangular outlines. They lie in the collagen-containing extracellular space and do not contact axons. The A cells aggregate in close contact with each other, with membrane thickenings over much of the contact area. In longitudinal sections, the clusters of A cells and their processes (Fig. 7B) extend in parallel arrays along the rostrocaudal axis of the CST. At the leading edge of the cluster, the A cells are prolonged into two or three long, thin, filopodia-like streamers (Fig. 7A, indicated by f). In cross section, the sheet-like, curving A cell processes (Fig. 9, indicated by a) can be seen to form layered shells, enclosing groups of axons and their associated S cell wrapping.
Longer-term axon and olfactory-ensheathing cell configuration
In 15 rats at 3 weeks to 3 months survival, we prepared confocal pictures of the whole transplant area in consecutive 1 μm steps throughout the entire thickness in each of the five to six members of a continuous series of longitudinal 100-μm-thick vibratome sections through the 10–15 mm longitudinal block of spinal cord containing the transplant (i.e., an aggregate of 500–600 scans from each transplant). We used BD to identify the regenerating corticospinal axons and concomitant p75 to identify the transplanted OECs. This provided a complete visualization of the whole cross-sectional area of each 100-μm-thick section of the transplant region (Fig.10). The regenerating corticospinal axons form parallel bundles confined to the transplant area. They were almost entirely unbranched, in direct alignment with the rostrocaudal axis of the CST, and passed uninterruptedly into the distal host CST caudal to the transplant.
From 3 weeks onward, the regenerating axons become ensheathed by P0-immunoreactive myelin, which is characteristic of peripheral myelin [as in the dorsal roots (Fig.11A)], but which is completely absent from the normal CST or other spinal tracts. The P0 immunostaining provides a striking overall picture of the regenerating axons passing through the transplanted region and their reentry into the distal host CST. Concomitant with the expression of P0, the expression of p75, which was a conspicuous marker of S cells at earlier times, becomes reduced throughout most of the transplant (although not as much as in the case of Schwann cells when they form myelin in developing or regenerating peripheral nerve (Taniuchi et al., 1988) or after transplantation into the CST (Li and Raisman, 1997). L1 was also greatly downregulated, although still present at low levels throughout the transplants. Fibronectin immunostaining remained as dense as at the earlier times.
Longitudinal semithin and ultrathin sections (Fig.12) show that the axons are traveling through regions that have a structure that closely resembles peripheral nerve and remains devoid of any central glial cell types (astrocytes, oligodendrocytes, or microglia). The S cells no longer enwrap multiple axons but now consistently express the characteristic peripheral-type, one-to-one myelinating relationship with the axons, in which the S cell outer cytoplasmic tongues and all their abaxonal surfaces are closely and uniformly clothed by a basal lamina. Apart from their contact with their individual axons, the S cells do not make contact with other S cells or any other cell type. The S cell myelin is thicker (∼20 turns) and (with our fixative procedure) better-preserved than the central, oligodendrocytic myelin in the adjacent host spinal white matter tracts, and the periodicity of the peripheral myelin is 10% greater than that of the central myelin (Peters et al., 1976; Li and Raisman, 1997). There are frequent nodes and Schmidt-Lantermann clefts. Electron microscopy of the anterogradely transported BD label clearly confirms the corticospinal identity of the peripherally myelinated regenerating axons (Fig. 11D).
As the S cells form myelin, the A cells become compacted into tubular sheaths (Fig. 12) that span the length of the transplants. The sheaths consist of reduplicated, closely apposed thin sheets of cytoplasmic A cell processes (Fig. 12, indicated by a) bound by extensive, complex intercellular junctions (Fig. 12, arrows). As in the case of the perineurial sheaths of peripheral nerve, the A cell sheaths lie in a collagen-containing extracellular space and enclose a territory of ∼5–10 μm in diameter, containing ∼3–10 S cells and their associated axons.
Reentry of the regenerating axons into the CNS
P0 immunostaining shows that the distal part of the host CST becomes selectively infiltrated by a dense mass of transplanted OECs (Fig. 11), extending caudally within the boundaries of the host CST for distances of ∼5 mm at 3–4 weeks and >10 mm at 3 months. At the caudal boundary, there is no appreciable disruption of the alignment of the host glial cells, and the streams of OECs and P0 myelinated axons interdigitate smoothly with the longitudinal interfascicular glial rows (Suzuki and Raisman, 1992) of the distal host CST. After crossing the transplants, the peripherally myelinated regenerating corticospinal axons continue uninterruptedly into the distal part of the host CST, coextensive with the mass of caudally migrating OECs. Combined P0 and MOG immunostaining (Fig.13A,B) shows the transition, at a single internode, from the peripheral myelin of the transplant region (black = P0) to the oligodendrocytic territory of the distal host CST (purple = MOG). In electron micrographs this transition was represented by “mixed” nodes with peripheral myelin rostrally and central myelin caudally (Fig. 13C).
DISCUSSION
The axonal response
The tip of a growing axon acts as a sensory structure, exploring the environment and changing shape (Mason and Wang, 1997) in response to the molecular signals that determine advance, collapse, or turning (Fan et al., 1993; Tessier-Lavigne and Goodman, 1996; Mason and Wang, 1997).
The regenerating CST axons induced by OEC transplants have three characteristic morphological features. (1) At shorter survivals, they have simple, unbranched tips, ending freely in the transplants. They resemble the simple tips of developing axons in the optic stalk (Chan et al., 1998, their Fig. 3). We do not see the expanded, hand-like growth cones with filopodia found in tissue culture (Argiro et al., 1984) or at choice points in developing systems (Bovolenta and Mason, 1987). (2) The regenerating axons form parallel fascicles aligned with the long axis of the CST. This is in contrast to the highly tortuous, varicose, branching neuromatous masses and pseudoterminal arborizations found after transplantation of Schwann cells (Li and Raisman, 1994). (3) At longer survivals, the regenerating axons traverse the entire rostrocaudal axis of the transplants and continue uninterruptedly into the denervated host CST.
We believe these to be regenerating axons that have been cut (rather than surviving uncut axons that have been demyelinated and remyelinated by the transplanted OECs) because (1) the lesioning procedure results in a circumscribed area of macrophage-infiltrated debris, totally devoid of central glia and axons (Fig. 3), indicating that all components of CNS tissue have been totally destroyed. In 69 rats (from this and the previous studies) with lesions alone and BD labeling of the CST, the swollen ends of the cut axons produced branching sprays of short sprouts in the rostral edge of the lesions (Fig. 4) (Li and Raisman, 1994, their Fig. 3; Li and Raisman, 1995, their Figs. 3, 4), but we have never seen axon sprouts traversing a lesion without transplanted OECs. (2) At increasing survival times after transplantation of OECs into the lesioned area, we see the free tips of the regenerating cut axons extending progressively into and through the transplants (Figs. 6, 8).
Reentry of the regenerating CST axons into the host CST
Because of the caudal migration of the transplanted OECs, the regenerating axons reenter the distal host CST up to 10 mm caudal to the injection site. After approximately 3 weeks, these axons are myelinated, for their course through the transplants, by peripheral myelin formed by the transplanted S-type OECs. From the internode at the point where they reenter the distal part of the CST, however, they become myelinated by oligodendrocytes. For individual axons the point of reentry is indicated by the presence of a mixed peripheral-to-central myelin node, which can be identified by P0/MOG combined immunohistochemistry or in electron micrographs (Fig. 13). The reformation of central myelin indicates that the axons have left the peripheral environment of the transplant and reentered the oligodendrocytic CNS environment of the host CST.
At present we have not established how far the regenerating CST axons grow or the nature of their terminal distribution. However, it seems likely that they do form effective contacts, because in a functional study we found that OEC-induced regeneration of cut CST fibers across a complete unilateral CST lesion restores a specific directed forepaw reaching function (Li et al., 1997).
The composition and behavior of the transplanted OECs
There are two distinct types of transplanted cells, differing in their phenotype, structure, and behavior. One of the most striking features of the OEC transplants is the “cooperation” between these two cell types. At the earlier stages the A cells form clusters with pioneering filopodia, advancing around the S cell-ensheathed axons. At later stages the S cells myelinate the axons and the A cell clusters coalesce into tubular, perineurial-like structures traversing the whole rostrocaudal length of the transplants (Fig. 14). A cells were named after a supposed resemblance to astrocytes (based on the expression of GFAP) (Barber and Lindsay, 1982; Franceschini and Barnett, 1996). However, both the expression of fibronectin in culture (Fig. 1) and their tissue arrangement after transplantation (Fig. 12), indicate a strong resemblance to fibroblasts.
Like transplanted Schwann cells (Li and Raisman, 1997), transplanted OECs suppress scar formation by the host astrocytes. There was no long-term astrocytic hypertrophy or reorganization to form the thick, reduplicated astrocytic scars that are typically found after comparably sized CST lesions without transplants (Li and Raisman, 1995). At the caudal end of the columns of migrating OECs, the longitudinal glial cell alignment of the distal host CST was preserved.
The ability of transplanted OECs to myelinate central axons is all the more striking because the axons with which they are normally associated, in the olfactory system, are totally unmyelinated (Doucette, 1991). Devon and Doucette (1992) demonstrated that OECs myelinate the neurites of dorsal root ganglion cells in culture, and transplanted OECs (Imaizumi et al., 1998) or an OEC cell line (Franklin et al., 1996) is able to remyelinate axons and enhance conduction in a gliotoxic lesion of the spinal cord. In both of these situations, as in the present study, they produce peripheral-type myelin.
In contrast to transplanted Schwann cells (Li and Raisman, 1994, 1997), the greater caudal migration of the OECs (of up to 10 mm) (also seeImaizumi et al., 1998) may be important for maintaining the alignment of the CST axons and presenting the regenerating axon tips to the caudal part of the host tract.
Anton and collaborators have shown the importance of p75 for Schwann cell migration in vitro (Anton et al., 1994). The expression of p75 on transplanted OECs and Schwann cells (Li and Raisman, 1997) may similarly be involved in their migration in vivo. In our previous experiments (Li and Raisman, 1997), p75 had disappeared from the transplanted Schwann cells by 2 months. In the present material a proportion of the transplanted OECs were still expressing p75 at 3 months. This prolonged maintenance of p75 expression may contribute to the enhanced migration of OECs compared with Schwann cells. The transplanted OECs also express high levels of molecules such as laminin (Liesi, 1985) and L1, which may contribute to both the cell migration and the induction of axon growth (Burden-Gulley et al., 1997; Lahrtz et al., 1997).
Relationship to central myelin
There have been previous reports of regeneration of corticospinal axons after intracerebral transplantation of hybridoma cells secreting an antibody against a central myelin-associated molecule (Schnell and Schwab, 1990; Schnell et al., 1994; Bregman et al., 1995). These axons were reported as branched, and their course was deflected by extensive cyst formation at the lesion site, so that they did not reenter the distal CST but descended in abnormal locations in the spinal gray matter. Further work will be needed to elucidate the relationship to the present observations, where we found cyst formation to be minimal and the regenerating axons were unbranched, maintained their original position and alignment, and directly reentered the white matter of the caudal CST, where they became remyelinated by oligodendrocytes.
In view of the evidence that myelin-associated proteins are inhibitory to axon growth (Bandtlow et al., 1990; DeBellard et al., 1996), our observation that the regenerating axons ultimately become myelinated by oligodendrocytes does not necessarily mean that at the time when the regenerating sprouts are reentering the host CST they have made contact with central myelin. As shown by the present electron microscopic study, the newly growing axon sprouts traverse the lesion enwrapped in the cytoplasm of S cells and flanked by migrating A cells and are not in contact with central myelin. On their reentry into the caudal host CST, they may continue to be isolated from any residual myelin by the phagocytic cells, which engulf the degenerating myelin associated with the degenerating distal parts of the cut corticospinal axons and by the membranes of the array of numerous, longitudinal astrocytic processes present in the host tract.
Conclusion and forward look
The conditions of the present experiment were designed to optimize the possibility for repair. The corticospinal fibers form one of the most circumscribed tracts in the spinal cord. The lesion was small, and the reparative cells were injected into it immediately after axotomy. The observed regeneration distance of 10 mm is sufficient for the CST axons to reach the level of the motoneuron pools supplying the forelimb muscles. In a preliminary series (unpublished data) we have obtained functionally effective repair when transplantation was delayed for 5 weeks after the lesion. However, to obtain a comparable result in the larger, more disorganized spinal cord lesions, including much longer term lesions typically encountered in clinical situations in which several different tracts are involved, further interventions will probably be needed to enable the regenerating axons to bridge the greater distances and correctly realign with the appropriate distal tracts (Cheng et al., 1996; Xu et al., 1997).
Footnotes
This project was supported by the British Neurological Research Trust, the International Spinal Research Trust, the Barnwood House Trust, and Smith’s Charity. Dr. Daqing Li provided invaluable consultation and collaboration. We are grateful to Yewande Ajayi, Bernice Watt, and Tammaryn Johnson for their excellent and innovative technical support.
Correspondence should be addressed to Dr. Geoffrey Raisman, Division of Neurobiology, National Institute for Medical Research, The Ridgeway, Mill Hill, London NW7 1AA, UK.