Readiness of Zebrafish Brain Neurons to Regenerate a Spinal Axon Correlates with Differential Expression of Specific Cell Recognition Molecules

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The Journal of Neuroscience, August 1, 1998, 18(15):5789-5803

Readiness of Zebrafish Brain Neurons to Regenerate a Spinal Axon Correlates with Differential Expression of Specific Cell Recognition Molecules
Thomas Becker¹, Robert R. Bernhardt¹, Eva Reinhard³, Mario F. Wullimann², Enrico Tongiorgi¹, and Melitta Schachner¹^,⁴
¹ Department of Neurobiology, Swiss Federal Institute of Technology, Hönggerberg, CH-8093 Zürich, Switzerland, ² Brain Research Institute, University of Bremen, D-28334 Bremen, Germany, ³ Department of Pharmacology, Biozentrum, University of Basel, CH-4056 Basel, Switzerland, and ⁴ Zentrum für Molekulare Neurobiologie Hamburg, Universität Hamburg, D-20246 Hamburg, Germany

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

We analyzed changes in the expression of mRNAs for the axonal growth-promoting cell recognition molecules L1.1, L1.2, andneural cell adhesion molecule (NCAM) after a rostral (proximal)or caudal (distal) spinal cord transection in adult zebrafish.One class of cerebrospinal projection nuclei (represented by thenucleus of the medial longitudinal fascicle, the intermediatereticular formation, and the magnocellular octaval nucleus) showeda robust regenerative response after both types of lesions asdetermined by retrograde tracing and/or in situ hybridizationfor GAP-43. A second class (represented by the nucleus ruber,the nucleus of the lateral lemniscus, and the tangential nucleus)showed a regenerative response only after proximal lesion. Afterdistal lesion, upregulation of L1.1 and L1.2 mRNAs, but not NCAMmRNA expression, was observed in the first class of nuclei. Thesecond class of nuclei did not show any changes in their mRNAexpression after distal lesion. After proximal lesion, both classesof brain nuclei upregulated L1.1 mRNA expression (L1.2 and NCAMwere not tested after proximal lesion). In the glial environmentdistal to the spinal lesion, labeling for L1.2 mRNA but not L1.1or NCAM mRNAs was increased. These results, combined with findingsin the lesioned retinotectal system of zebrafish (Bernhardt etal., 1996), indicate that the neuron-intrinsic regulation of cellrecognition molecules after axotomy depends on the cell type aswell as on the proximity of the lesion to the neuronal soma. Glialreactions differ for different regions of the CNS.

Key words: CNS regeneration; teleost; Mauthner cell; L1; NCAM; axotomy

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Axonal regrowth after a lesion depends on the balance of axonal growth-promoting and growth-inhibiting molecules expressedby the glial environment of severed axons (Schwab et al., 1993;Martini, 1994) and on neuron-intrinsic properties, such as thecapability to (re)express molecules associated with axonal growth(Fawcett, 1992). Recently it has been demonstrated by retrogradetracing that neurons in some cerebrospinal projection nuclei consistentlyregenerate their axons after a distal lesion of the spinal cordin adult zebrafish (Becker et al., 1997). In contrast, the individuallyidentifiable Mauthner cell showed no axonal regrowth to the levelof tracer application, ~3.5 mm caudal to the lesion site.

The capacity for axonal regrowth by a third group of nuclei remains questionable (Becker et al., 1997). In unlesioned controlanimals, most spinal axons of neurons in these nuclei, althoughreaching the level of spinal cord transection, did not reach themore caudal application site of the retrograde tracer. Thus, evenif these neurons had regrown their axons to the original lengththey would not have been detected (Becker et al., 1997). We thereforehave decided to use an alternative strategy to detect a regenerativeresponse in axotomized neurons. The growth-associated protein43 (GAP-43) is a widely accepted marker of axonal growth (Skene,1989) and has recently been shown to promote axonal growth (Aigneret al., 1995; Holtmaat et al., 1995; Shea and Benowitz, 1995;Strittmatter et al., 1995). Assessing changes in the expressionof GAP-43 mRNA after axotomy offers the possibility to confirmour previous findings and to gain additional information on theresponse to a spinal lesion of those cerebrospinal projectionneurons of which the regenerative potential could not be determinedpreviously.

To identify additional molecular correlates of successful axonal regeneration, both in the environment of the lesioned axonsand in the axotomized neurons, we examined the expression of themRNAs encoding L1.1, L1.2, both of which are closely related tomouse L1 (Tongiorgi et al., 1995), and the zebrafish neural celladhesion molecule (NCAM) which is closely related to the mammalianand avian NCAM (Bernhardt et al., 1996). These three recognitionmolecules of the immunoglobulin (Ig) superfamily (Reichardt etal., 1990; Schachner et al., 1990; Rathjen et al., 1992) werechosen because they are known to promote neurite outgrowth invitro (Appel et al., 1993; Sandig et al., 1994; Zhao and Siu,1995) and are upregulated during axonal regrowth by both regeneratingneurons (Bastmeyer et al., 1990; Vielmetter et al., 1991; Beckeret al., 1993; Bernhardt et al., 1996) and glial cells (Nieke andSchachner, 1985; Daniloff et al., 1986; Martini and Schachner,1988; Bernhardt et al., 1996).

After a distal spinal lesion, the neurons in those brain nuclei that had previously been shown to regenerate their spinalprojections strongly upregulated the expression GAP-43, L1.1,and L1.2 but not NCAM mRNAs. In contrast, expression of thesemRNAs was not significantly increased in the brain nuclei forwhich axonal regrowth could previously not be determined. However,after a more proximal spinal lesion, which axotomized similarnumbers of neurons as the distal lesion, L1.1 and GAP-43 mRNAexpression was found to be strongly upregulated in these nuclei.Concomitantly, axonal regrowth could be demonstrated. The Mauthnercell, which regrew its axon in some cases after proximal lesion,showed only a slight upregulation of GAP-43 mRNA expression andno increase in the expression of mRNAs for cell recognition molecules.In the spinal cord caudal to the lesion site, L1.2 but not L1.1or NCAM mRNA expression was increased in putative glial cells.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Animals. Adult zebrafish, Danio rerio (n = 88; body length, 2-3 cm), were analyzed in this study. They were taken from ourbreeding colony or bought at a local pet shop. Before surgery,fish were kept in groups of 10 animals on a 14 hr light/10 hrdark cycle and at a temperature of 28.5 °C.

Antibodies. The mouse monoclonal antibody 4C4 is a marker of macrophages/microglial cells in fish and was a gift of Dr. J.Scholes (University College, London). The antibody CON1, an axonalmarker in zebrafish (Bernhardt et al., 1990), was a gift fromDr. J. Y. Kuwada (University of Michigan, Ann Arbor).

cRNA probes. Digoxigenin (DIG)-labeled cRNA sense and antisense probes for L1.1 mRNA and L1.2 mRNA were generated as describedpreviously (Tongiorgi et al., 1995). The L1.1 probe comprisespart of the third Ig-like domain at its 5' end and includes ~400base pairs of the 3' noncoding region. The L1.2 probe comprisespart of the fifth fibronectin type III (FN III)-like domain atits 5' end and includes the transmembrane and cytoplasmic regionsbut not the noncoding region (Tongiorgi et al., 1995; Bernhardtet al., 1996). Two additional L1.2 probes, one including all sixFN III-like domains and the second one the five Ig-like domains,yielded the same results. The NCAM probe, comprising the secondto fifth Ig-like domain, thus detecting all major splice variantsof NCAM mRNA, was derived from a zebrafish clone that was a giftof Dr. D. Grunwald (University of Utah). Generation of the zebrafishGAP-43 probe has also been reported previously (Reinhard et al.,1994).

Spinal cord lesion. Spinal cord transection was performed as described previously (Becker et al., 1997). Briefly, fish wereanesthetized by immersion in 0.033% aminobenzoic acid ethylmethylester(MS222; Sigma, St. Louis, MO) for 5 min. A longitudinal incisionwas made at the side of the fish to expose the vertebral column,which was then cut either at a level halfway between the dorsalfin and the operculum, i.e., 3.5 mm caudal to the brainstem/spinalcord transition zone [level 2, distal lesion (see Fig. 1)], orat the level of the operculum, corresponding to the brainstem/spinalcord transition zone [level 1, proximal lesion (see Fig. 1)].Wounds were sealed with histoacryl (B. Braun, Melsungen, Germany),and the fish were kept at room temperature after surgery for 6-12weeks.

In situ hybridization. Nonradioactive detection of mRNAs in sections of adult zebrafish CNS was performed as published previously(Bernhardt et al., 1996). Briefly, consecutive coronal 14-µm-thicksections of brains and spinal cords were cut from fresh-frozentissue on a cryostat. The sections were fixed overnight in 4%paraformaldehyde in PBS, pH 7.3, acetylated, dehydrated, air-dried,prehybridized for 3 hr at 37°C, and hybridized with the DIG-labeledprobes at 55°C overnight. After extensive washing (3 × 90 minat 55°C), alkaline phosphatase-coupled anti-DIG Fab fragment antibodies(Boehringer Mannheim, Mannheim, Germany) were applied overnight.Antibody-binding was detected using an alkaline phosphatase reactionwith nitro blue tetrazolium and 5-bromo-4-chloro-3-indolyl phosphateas substrates. Developing times were 3-6 hr for the brains and18-48 hr for the spinal cords to enhance the relatively weak upregulationof mRNA expression in the spinal cord. Sense probes, developedin parallel under the same conditions as the antisense probes,never showed any labeling (see Fig. 3D). Control and lesionedfish were analyzed in the same experiments on the same microscopicslides. Sections were viewed and photographed using differentialinterference contrast microscopy, to visualize anatomical landmarks.To further facilitate the anatomical analysis, cell nuclei werefluorescently labeled by adding ~1 mg/l bisbenzimide (Hoechst33258, Sigma) to the final washing solution after the alkalinephosphatase reaction. For all probes (GAP-43, L1.1, L1.2, NCAM)at least three brains for each time point were analyzed afterdistal lesion at 7 and 14 d post-lesion. For determination ofL1.1 mRNA expression in the brain after distal lesion, three brainsfor each time point were additionally analyzed at 2, 3, and 56d post-lesion, and one brain was analyzed at 84 d post-lesion.After proximal lesion, the regulation of expression of GAP-43and L1.1 mRNAs was examined in three brains for each time pointand probe at 7 and 14 d post-lesion. At least three control brainswere included for each RNA probe. For the analysis of L1.1, L1.2,and NCAM mRNA expression in the spinal cord, at least three unlesionedcontrol and three lesioned distal spinal cords were analyzed foreach probe at 7 and 14 d post-lesion.

Whole-mount in situ hybridization followed by immunohistochemistry was performed on embryonic zebrafish (27 hr post-fertilization)as described previously (Tongiorgi et al., 1995). DIG-labeledprobes were detected with the alkaline phosphatase reaction asdescribed above, yielding a blue reaction product. After thisprocedure, immunocytochemistry for the CON1 antigen was performedon the same embryos using diaminobenzidine as substrate for horseradishperoxidase, resulting in a brown reaction product.

Quantification. The quantification of mRNA expression by in situ hybridization is not straightforward. The strength of thehybridization signal can vary as a result of the time during whichthe tissue was stored, even at $-$ 80°C, of individual batches ofcRNA probe, of slight variations in section thickness, etc. Toarrive at an objective evaluation of the changes in mRNA expression,we chose two complementary approaches, one qualitative, the otherquantitative. In the qualitative assessment, a brain nucleus wasscored as having significantly upregulated a specific mRNA whenthe in situ labeling intensity throughout the nucleus was clearlyincreased as compared with the unlesioned control, in at leasttwo consecutive sections. In the case of the L1.1, L1.2, and NCAMmRNAs, an additional frame of reference was provided by populationsof neurons that constitutively displayed intense labeling withthe respective mRNA probes and that were not axotomized by thelesion (e.g., neurons in motor nuclei in the brain for the L1.1and L1.2 mRNA probes, and cerebellar Purkinje cells for the NCAMprobe).

To examine the validity of the qualitative assessment, we also counted all cellular profiles that displayed strong GAP-43and L1.1 mRNA labeling in the nuclei of interest, in both unlesionedcontrol and experimental animals at 7 and 14 d post-lesion. Thecounts were performed in all animals for which complete seriesof sections through the brain were available. Anatomical landmarksused to delineate the brain nuclei were the same as those usedfor anatomical tracing (Becker et al., 1997). Because the samecell can be counted twice (or more) in adjacent sections, thenumber of cellular profiles we determined does not directly correspondto the absolute number of labeled cells (Coggeshall and Lekan,1996).

Cells were scored as having upregulated L1.1 mRNA expression if they displayed labeling intensity equal to or greater thanthe constitutively L1.1-expressing cells in the motor nuclei ofthe same animal. Because there are no populations of cells thatconstitutively express high levels of GAP-43 mRNA, we had to usea different criterion to evaluate changes in GAP-43 mRNA expression.All cells that showed stronger labeling than cells in the tectumopticum or the cerebellum of the same animal were counted.

Because counting criteria were different for L1.1 and GAP-43 mRNA-expressing cells, the numbers obtained by the counts cannotbe compared directly. Also, the counts based on in situ labelingof the cryosections (thickness, 14 µm) cannot be related directlyto those obtained by retrograde axonal tracing performed on vibratomesections (thickness, 50 µm). This is because the counting error(see above) depends on the section thickness and is greater forthin than for thick sections (Coggeshall and Lekan, 1996). Toallow for a comparison between the different data sets we havedetermined an induction index. This relative value is independentof the counting protocol and also takes into account that differentnumbers of neurons will be axotomized by lesions at differentspinal levels. The induction index is defined as [(n in situ 1)/(nin situ 2)]/[(n retrograde 1)/(n retrograde 2)], where (n in situ1) and (n in situ 2) are the numbers of cellular profiles showingstrong in situ labeling after level 1 and level 2 lesion, respectively,and (retrograde 1) and (retrograde 2) are the numbers of cellularprofiles retrogradely labeled from level 1 and level 2, respectively,in unlesioned control fish. An induction index >1 indicates thata specific mRNA is upregulated in a higher proportion of cellsin a particular nucleus after level 1 than after level 2 lesion,independent of differences in the number of axotomized neurons.For example, an induction index of 5 indicates that five timesmore cells are induced to express high levels of a specific mRNAafter a proximal than after a distal lesion. An induction indexof 1 means that proximal and distal lesions do not differ in theirpotency to induce the upregulation of a certain mRNA. An inductionindex <1 means that a proximal lesion induces mRNA upregulationless efficiently than a distal lesion.

Axonal tracing. Tracing of axons was performed as described previously (Becker et al., 1997). Briefly, 6 weeks after spinalcord transection at level 2 for distal lesions or level 1 forproximal lesions, anesthetized fish received a second spinal cordtransection at level 3 (~3.5 mm caudal to level 2) for distallesions (see Fig. 1C) or level 2 for proximal lesions (see Fig.1D). A small piece of gelatin foam (gel foam; Upjohn, Kalamazoo,MI) soaked with biocytin (Sigma) was applied to the transectionsite. After 24 hr, fish were perfused with 2% paraformaldehyde/2%glutaraldehyde in PBS, pH 7.3. Brains were sectioned at 50 µmon a vibratome, and the signal was developed using the VectastainABC-kit (Vector Laboratories, Burlingame, CA) with diaminobenzidineas substrate.

Neuroanatomy. Brain structures were identified using the zebrafish brain atlas (Wullimann et al., 1996). Neuronal profilesin different brain nuclei in axonal tracing experiments were countedwithout corrections for split somata as described previously (Beckeret al., 1997) (see also above).

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

We have previously presented evidence for differences in the regenerative capacity of different classes of cerebrospinal projectionneurons (Becker et al., 1997). One aim of the present study wasto extend these results, by additional experiments using retrogradetracing and by analyzing GAP-43 mRNA expression. The main focuswas on the question of whether a relationship exists between successfulaxonal regrowth and a neuron's capacity to upregulate the expressionof specific cell recognition molecules.

To test this hypothesis, three classes of brain nuclei were analyzed after lesion on the basis of the previous study (Beckeret al., 1997): (1) brain nuclei with demonstrated regenerativecapacity; (2) brain nuclei for which the response to axotomy couldpreviously not be determined; and (3) the individually identifiableMauthner cell. The expression patterns of the recognition moleculeswere examined by in situ hybridization, after two types of spinallesions: (1) at the same distal spinal level as in the previousstudy and (2) after a more proximal lesion (Fig. 1A,B) (see Materialand Methods). Additionally, to complement our previous study ofaxonal regrowth after a distal spinal lesion (Becker et al., 1997),axonal regrowth after the proximal lesion was determined by retrogradetracing (Fig. 1C,D).

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Figure 1. A-D, Schematic representation of different experiments. Different lesion or tracing levels are indicated by numbers 1-3. A, B, To analyze changes in the expression of cell recognition molecules by in situ hybridization, spinal cords of fish were transected (scissors) either at level 2 (distal lesion, A) or at level 1 (proximal lesion, B). C, D, To assess regenerative success, 6 or more weeks after spinal cord transection, neurons in the brain were retrogradely labeled from level 3 after transection at level 2 (C) (published previously in Becker et al., 1997) or from level 2 after transection at level 1 (D).

Brain nuclei with demonstrated regenerative capacity

Axonal regrowth
Neurons in the nucleus of the medial longitudinal fascicle, the intermediate reticular formation, and the magnocellular octavalnucleus had previously been shown to consistently regrow axonsto a level 3.5 mm caudal to the site of the distal transection(Becker et al., 1997). In the following, these two spinal levelswill be referred to as level 3 and level 2, respectively. Herewe show that axonal regeneration also occurs after a proximallesion (n = 7 animals), at the hindbrain-spinal cord boundary(Table 1). This lesion site will be referred to in the followingas level 1; it is located ~3.5 mm rostral to level 2. After lesionat level 1, neurons were traced from level 2 (Fig. 1C,D).


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Table 1. Comparison of numbers of neuronal profiles back-labeled from different spinal levels in unlesioned control animals and animals with transected spinal cord

The proportion of neurons that grew their axons beyond the lesion site to the level of tracer application was similar in bothsets of experiments. After level 2 lesions, 33% of the neuronsin the nucleus of the medial longitudinal fascicle that normallyproject to level 3 had regenerated axons. For neurons in the intermediatereticular formation, this proportion was 41%, and in the magnocellularoctaval nucleus it was 43% (Table 1). After lesions at level1, the number of neurons projecting from the nucleus of the mediallongitudinal fascicle to level 2 was 32% of that in unlesionedfish. For the intermediate reticular formation the proportionwas 51%, and for the magnocellular octaval nucleus it was 32%(Table 1). This indicates that the regenerative success of axotomizedneurons in the three nuclei is independent of the distance betweenthe soma and the lesion site.

Expression of mRNAs
GAP-43 proved to be a reliable marker of a regenerative response in the three nuclei. In both lesion paradigms, and correlatingwith successful axonal regeneration, the intensity of GAP-43 mRNAlabeling was always (n = 4 animals) markedly increased in thenucleus of the medial longitudinal fascicle (Fig. 2E,F, and seeFig. 6D,F), the intermediate reticular formation (Fig. 2G,H),and the magnocellular octaval nucleus (data not shown).

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Figure 2. A-H, Cerebrospinal projection nuclei differ in the expression of different mRNAs 14 d after distal spinal cord transection. Expression of L1.2 (A, B), NCAM (C, D), and GAP-43 (E-H) mRNAs in the nucleus of the medial longitudinal fascicle (A-F) and the intermediate reticular formation (G, H). All images are cross sections; dorsal is up. Large arrows indicate the brain midline. Small arrows point out individual neurons in the nucleus of the medial longitudinal fascicle (A-F) and in the intermediate reticular formation (G, H). A, B, Expression of L1.2 mRNA was increased in lesioned animals (B) as compared with unlesioned controls (A). C, D, NCAM mRNA expression was not increased in lesioned animals (D) as compared with unlesioned controls (C). Asterisks indicate the overlying Purkinje cells of the cerebellum that constitutively show intense NCAM mRNA labeling. E-H, In lesioned animals, there was a strong upregulation of GAP-43 mRNA expression in the nucleus of the medial longitudinal fascicle (F), compared with unlesioned control fish (E) and in the intermediate reticular formation (H), compared with unlesioned controls (G). Arrowhead in H points at a part of the ventral Mauthner cell dendrite. Scale bars: A-F (shown in F), 100 µm; G, H (shown in H), 150 µm.

To determine whether an upregulation of cell recognition molecules occurs during axonal regrowth, expression of L1.1, L1.2,and NCAM mRNAs was analyzed by in situ hybridization. At 7-14d after a level 2 lesion, expression of L1.1 (Figs. 3, 4, 5) (n= 14 animals) and L1.2 (Fig. 2A,B) (n = 12 animals) mRNAs wasconsistently increased in the three nuclei when compared withunlesioned control fish. No such upregulation was observed forNCAM mRNA expression (Fig. 2C,D) (n = 13 animals). At 7-14 d aftera level 1 lesion, only the expression of L1.1 mRNA was assayed.It was always found to be strongly increased (Fig. 6E) (n = 9animals).

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Figure 3. A-D, Expression of L1.1 mRNA in the nucleus of the medial longitudinal fascicle was rapidly upregulated after distal spinal cord transection. All images are cross sections; dorsal is up. Small arrows indicate individual cells in the nucleus of the medial longitudinal fascicle. Large arrow in D indicates the position of the brain midline for all panels. A, In situ labeling was faint in unlesioned controls. B, Labeling was increased at 3 d post-lesion. C, In situ labeling was very strong at 14 d post-lesion. D, The L1.1 sense RNA probe showed no staining. Scale bar (shown in D for A-D): 100 µm.

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Figure 4. A, B, L1.1 mRNA expression was strongly increased in the magnocellular octaval nucleus after distal spinal cord transection. All images are cross sections; dorsal is up, lateral is left. A, Unlesioned control; B, 14 d post-lesion. Arrows point to individual neurons in the magnocellular octaval nucleus. The sensory root of the facial nerve (VIIs) is indicated as an anatomical landmark. In situ labeling after spinal cord transection (B) was very strong, compared with unlesioned controls (A). Scale bar (shown in B for A and B): 50 µm.

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Figure 5. A-F, Expression of L1.1 mRNA was increased between 3 and 56 d after distal lesion. All images are cross sections; dorsal is up. A, Unlesioned control; B, 3 d post-lesion; C, 7 d post-lesion; D, 14 d post-lesion; E, 56 d post-lesion; F, 84 d post-lesion. Large arrows indicate the midline of the brain. Small arrows point to individual cells in the intermediate reticular formation. Asterisks indicate the trigeminal motor nucleus, which constitutively shows intense labeling for L1.1 mRNA as an internal positive control. Arrowheads in A, C, D, and F indicate the ventral dendrite of the Mauthner cell as an additional landmark. A, Labeling was faint in unlesioned controls. B-E, Expression of L1.1 mRNA was increased between 3 and 56 d post-lesion. F, Staining intensity was similar to that in unlesioned controls at 84 d post-lesion (compare with A). Scale bar (shown in F for A-F): 150 µm.

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Figure 6. A-F, Expression of L1.1 and GAP-43 mRNA in the nucleus ruber was not significantly upregulated after distal but was upregulated after proximal lesion. L1.1 (A, C, E) and GAP-43 (B, D, F) mRNA expression in the nucleus ruber in unlesioned control fish (A, B), 14 d after distal lesion (C, D), and 14 d after proximal lesion (E, F) are shown. All images are cross sections; dorsal is up, lateral is left. Arrows depict individual neurons of the nucleus ruber. Arrowheads indicate individual neurons of the nucleus of the medial longitudinal fascicle. The fasciculus retroflexus (FR) is indicated as an anatomical landmark. A, B, In unlesioned control fish, labeling for L1.1 (A) and GAP-43 mRNAs (B) was weak. C, D, After distal lesion, expression of L1.1 (C) and GAP-43 mRNAs (D) was not significantly upregulated in the nucleus ruber but was upregulated in the nucleus of the medial longitudinal fascicle. Asterisk in D indicates one of the few cells in the nucleus ruber that was strongly labeled for GAP-43 mRNA after distal lesion (see Results). E, F, After proximal lesion, neurons in the nucleus ruber were strongly labeled for L1.1 (E) and GAP-43 mRNAs (F). The increase in L1.1 and GAP-43 mRNA expression in individual cells in the nucleus ruber (arrows) after proximal lesion (E, F) was comparable to the increase in the nucleus of the medial longitudinal fascicle (arrowheads). Scale bar (shown in F for A-F): 50 µm.

In unlesioned control animals as well as in lesioned fish, strong labeling for L1.1 and L1.2 mRNAs was found in motor nucleiof cranial nerves, including the oculomotor nucleus, the nucleusEdinger-Westphal (data not shown), the dorsal and ventral trigeminalmotor nucleus (Fig. 5A-F), the facial motor nucleus, and the vagalmotor nucleus (data not shown). Strong in situ labeling of NCAMmRNA was always detected in cerebellar Purkinje cells and possiblyeurydendroid cells (Fig. 2C,D). Because all of the above neuronalcell types were not axotomized by the spinal lesion and did notshow any obvious difference in labeling intensity between unlesionedcontrol fish and those that had received spinal cord transection,they served as internal standards.
The regulation of L1.1 mRNA expression after level 2 lesions was studied in greater detail. It was found to be the same forall three nuclei. Upregulation of mRNA expression was first detectableat 3 d post-lesion (Fig. 5A,B). After 7-14 d (Fig. 5C,D) the intensityof the in situ signal was comparable to that in the motor nuclei(the internal standard; see above). Intense labeling was stillobserved after 56 d (Fig. 5E), whereas after 84 d it had declinedand was again comparable to that seen in unlesioned control animals(Fig. 5F).
To check the validity of the qualitative assessment, we counted the cellular profiles labeled strongly with the GAP-43 andL1.1 probes (see Material and Methods). In all three nuclei andafter both types of lesions, the number of cellular profiles thatwere strongly labeled for L1.1 and GAP-43 mRNA, respectively,was substantially increased compared with unlesioned controls(Table 2). The induction indices (see Material and Methods) wereclose to 1 for both mRNA probes (Table 2). This indicates thatthe proportions of cells induced to increase expression of L1.1and GAP-43 mRNA, respectively, were similar after distal and proximallesions. This is consistent with similar rates of axonal regrowthafter both types of lesion.


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Table 2. Quantitative evaluation of GAP-43 and L1.1 mRNA expression of different brain nuclei after proximal (level 1) and distal (level 2) lesion

We conclude that cerebrospinal projection neurons upregulate the expression of specific mRNAs during axonal regeneration,including L1.1 and L1.2 but not NCAM. Thereby they differ fromretinal ganglion cells, which upregulate the expression of allthree mRNAs during axonal regrowth (Bernhardt et al., 1996). Theonset of the upregulation may coincide with the initiation ofaxonal regrowth (cf. Bernhardt et al., 1996). The regulation ofL1.1 mRNA expression corresponded well with the recovery of swimmingbehavior (Becker et al., 1997).

Brain nuclei of uncertain regenerative capacity

Axonal regrowth
As representatives of the class of brain nuclei for which axonal regrowth could not be demonstrated after level 2 lesions,the nucleus ruber, the nucleus of the lateral lemniscus, and thetangential nucleus were chosen (Becker et al., 1997). In the presentstudy, we investigated axonal regrowth by neurons in these nucleiafter level 1 lesions by retrograde tracing from level 2 (Fig.1D).
After level 1 lesions, spinal projections from the nucleus ruber to level 2 were reestablished in part in four of seven fish,from the nucleus of the lateral lemniscus in two of seven fish,and from the tangential nucleus in one of seven fish (Fig. 7A,B).The percentage of neurons in the nucleus ruber that had regrownan axon to level 2 was 11% of normal (Table 1); for the nucleusof the lateral lemniscus it was 14% (Table 1), and for the tangentialnucleus it was 15% (Table 1). Thus, axonal regrowth can be elicitedalso in the nucleus ruber, the nucleus of the lateral lemniscus,and the tangential nucleus. But the rates of axonal regrowth (11-15%)are less than half of those observed for the nucleus of the mediallongitudinal fascicle, the intermediate reticular formation, andthe magnocellular octaval nucleus, both after level 1 (32-51%)and level 2 (33-43%) lesions.

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Figure 7. A-C, Retrograde axonal tracing (as described in Fig. 1) demonstrates axonal regrowth from the nucleus ruber, the nucleus of the lateral lemniscus, and the Mauthner cell after proximal lesion. All images are cross sections; dorsal is up, lateral is left. A, One neuron was labeled in the nucleus ruber (arrow), in addition to neurons in the nucleus of the medial longitudinal fascicle (arrowheads). B, Arrow depicts one labeled neuron in the nucleus of the lateral lemniscus, in a dorsomedial position to the lateral longitudinal fascicle (LLF). C, The Mauthner cell (arrow) was retrogradely traced in addition to neurons in the anterior octaval nucleus (AON) and the intermediate reticular formation (IMRF). Scale bar (shown in C): A, B, 50 µm; C, 100 µm.

Expression of mRNAs
As already described for the nucleus of the medial longitudinal fascicle, the intermediate reticular formation, and the magnocellularoctaval nucleus, increased expression of GAP-43 mRNA correlatedwith axonal regrowth also in the nucleus ruber, the nucleus ofthe lateral lemniscus, and the tangential nucleus. In none ofthe animals examined (n = 4) at 7-14 d after level 2 lesions didthe nucleus ruber (Fig. 6B,D), the nucleus of the lateral lemniscus(Fig. 8D,E), and the tangential nucleus (not illustrated) showany significant upregulation of GAP-43 mRNA expression, with theexception of an occasional individual neuron (Fig. 6D). In contrast,at 7 and 14 d after level 1 lesions, GAP-43 mRNA expression wasstrongly upregulated in the nucleus ruber and the nucleus of thelateral lemniscus in all fish (n = 4) examined (Figs. 6F, 8F).In the tangential nucleus, upregulation was likewise observed,but less frequently (two of four fish). It has to be noted thatfor the nucleus ruber and the nucleus of the lateral lemniscus,the number of neurons projecting to spinal levels 1 and 2 arenot substantially different. The nucleus ruber projects to level1 with an average of 11.2 neurons and to level 2 with an averageof 8.5 neurons. The nucleus of the lateral lemniscus projectsto level 1 with 6.8 neurons and to level 2 with 5.0 neurons (Table1). Thus, both level 1 and level 2 lesions will axotomize similarnumbers of neurons in these two nuclei. However, the tangentialnucleus projects to level 1 with 10 neurons but to level 2 withonly 4.1 neurons. The lack of a significant GAP-43 response afterlevel 2 lesion, despite similar numbers of neurons being axotomizedby both lesion paradigms in two of these nuclei, indicates thatthe distal lesion probably did not lead to regenerative axonalgrowth in these three nuclei (see Discussion).

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Figure 8. A-F, Expression of L1.1 and GAP-43 mRNAs in the nucleus of the lateral lemniscus was not significantly upregulated after distal but was upregulated after proximal lesion. In situ labeling of L1.1 (A-C) and GAP-43 (D-F) mRNAs, in unlesioned control fish (A, D), after distal (B, E) and proximal lesion (C, F) is shown. All images are cross sections; dorsal is up, lateral is left. Dashed lines outline the border of the lateral longitudinal fascicle as an anatomical landmark. Arrows point out individual cells in the nucleus of the lateral lemniscus. A-C, Labeling of L1.1 mRNA after distal lesion (B) was comparable to that in unlesioned controls (A), but it was strongly increased after proximal lesion (C). D-F, Intensity of labeling for GAP-43 mRNA was not increased after distal (E) but was increased after proximal lesion (F) as compared with unlesioned controls (D). Scale bar (shown in F for A-F): 50 µm.

The expression of the mRNAs encoding the three cell recognition molecules followed the pattern of GAP-43 mRNA expression.After level 2 lesions, no significant upregulation of L1.1 (n= 14 animals), L1.2 (n = 12 animals), or NCAM (n = 13 animals)mRNA expression was observed, as shown for L1.1 in the nucleusruber (Fig. 6A,C) and the nucleus of the lateral lemniscus (Fig.8A,B). An exceptional upregulation of L1.1 mRNA expression wasobserved in the nucleus ruber in only in 1 of 14 animals.
After level 1 lesions, only L1.1 mRNA expression was assayed. At 7 and 14 d post-lesion, it was generally upregulated in thenucleus ruber [eight of nine fish (Fig. 6E)] and in the nucleusof the lateral lemniscus [seven of nine fish (Fig. 8C)]. The intensityof the in situ labeling of individual neurons after proximal lesionwas comparable to that of neurons in the nucleus of the mediallongitudinal fascicle (Fig. 6E). In neurons of the tangentialnucleus, L1.1 mRNA expression was upregulated in only one of ninefish.
Counting the number of cellular profiles that were strongly labeled for L1.1 and GAP-43 mRNA in the three nuclei of uncertainregenerative capacity revealed a substantial increase after proximalbut not after distal lesion, with one exception: there was nosignificant, lesion-induced increase of L1.1 mRNA in the tangentialnucleus (Table 2). The induction index (see Material and Methods)for GAP-43 varied between 3.8 and 5.4. (Table 2). This indicatesthat approximately four times as many cells upregulated GAP-43mRNA expression after a proximal as compared with a distal spinallesion. Similarly, in the nucleus ruber and the nucleus of thelateral lemniscus, the induction index for L1.1 indicates a four-to eightfold increase in the number of cells expressing high levelsof L1.1 mRNA after a proximal compared with a distal lesion (Table2). The index value of 0.8 for the tangential nucleus (Table2) reflects the poor induction of L1.1 mRNA expression afterboth types of lesion.
Thus, in contrast to the brain nuclei of demonstrated regenerative capacity, a lesion closer to the neuronal somata is morelikely to induce the upregulation of GAP-43 mRNA in all threebrain nuclei of uncertain regenerative capacity. This is alsotrue for L1.1 mRNA in the nucleus ruber and the nucleus of thelateral lemniscus but not in the tangential nucleus. A regenerativeresponse may not be elicited as frequently after level 1 lesionin the tangential nucleus as in the nucleus ruber or the nucleusof the lateral lemniscus. This interpretation is consistent withthe finding that an upregulation of GAP-43 mRNA was observed inthis nucleus only in two out of four animals.

The Mauthner cell

Axonal regrowth
Mauthner cells are a bilateral pair of cerebrospinal projection neurons that could be individually identified in all preparations.Their axons normally project to the most caudal spinal cord butwere never observed to regrow to level 3 after level 2 lesions(Becker et al., 1997). In contrast, here we found that after level1 lesions Mauthner axons regrew in two of seven fish (one Mauthnercell in one fish and both Mauthner cells in another fish) (Fig.7C). The proportion of Mauthner cells that projected to level2 after level 1 lesions was 20% of the number of Mauthner cellsthat projected to level 2 in unlesioned animals (Table 1). Thisvalue is intermediate between those of the two classes of brainnuclei described above.

Expression of mRNAs
Concomitant with the lack of axonal regrowth after level 2 lesions, there was no upregulation of GAP-43 mRNA expression inthe four animals analyzed (Fig. 9A,B,D,E). Surprisingly, giventhat Mauthner cells occasionally regrew their axons after level1 lesions, we did not find a significant upregulation of GAP-43mRNA expression after level 1 lesions at 7 and 14 d post-lesion,even if in some cases after level 1 lesion staining appeared slightlystronger than in unlesioned control fish (Fig. 9C,F). However,this increase in labeling was much less than that observed inother axotomized neurons (Fig. 9G).

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Figure 9. A-G, Labeling for GAP-43 mRNA in the Mauthner cell was not significantly increased after distal and proximal lesion. All images are cross sections. A-C and G show in situ hybridization; D-F show nuclear fluorescence images corresponding to A-C and are included for orientation. Arrows in D-F point to the cell nucleus of the Mauthner cell. A, D, In an unlesioned control animal only weak in situ labeling was detected. B, E, At 14 d after a distal lesion, in situ labeling was faint. C, F, G, At 14 d after a proximal lesion, a slight increase in in situ labeling was seen occasionally (C, F). This increase appeared very weak, however, when compared with that in axotomized neurons that regenerated their axons consistently (see G, a low-power view of the same section), i.e., the anterior octaval nucleus (AON) or the intermediate reticular formation (IMRF). Arrow in G points out the Mauthner cell, and the open arrow in G depicts the midline of the brain. Scale bar (shown in F for A-F): 50 µm; G, 150 µm.

In contrast to GAP-43, we never observed even a small increase in labeling intensity of the mRNAs for the three cell recognitionmolecules, neither after level 2 lesion for L1.1, L1.2, or NCAMnor after level 1 lesion for L1.1 (Fig. 10A-H). This indicatesthat the Mauthner cell may be exceptional in that axonal regrowthafter level 1 lesion can take place without a conspicuous upregulationof GAP-43 mRNA expression and without upregulation of L1.1 mRNAexpression.

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Figure 10. A-H, No upregulation of L1.1 mRNA expression was observed for the Mauthner cell after distal and proximal lesion. All images are cross sections; A, E, unlesioned control; B, F, distal lesion, 3 d post-lesion; C, G, distal lesion, 7 d post-lesion; D, H, proximal lesion, 7 d post-lesion; E-H, the nuclear fluorescence images corresponding to A-D. Arrows point to the cell nucleus of the Mauthner cell. Staining intensity was extremely low in unlesioned controls (A, E), 3 d (B, F) and 7 d after distal lesion (C, G), as well as 7 d after proximal lesion (D, H). Scale bar (shown in H for A-H): 50 µm.

Expression of L1.1 mRNA in the Mauthner cell during development
Because we could not detect upregulation of L1.1 mRNA expression by the Mauthner cell under any experimental condition, weinvestigated whether it expressed L1.1 mRNA during embryonic axonalgrowth. In whole-mount in situ hybridizations of 27-hr-old zebrafish,the Mauthner cell was identified by its typical axon trajectory,as revealed by the antibody CON1, which labels a subset of axonsin embryonic zebrafish (Bernhardt et al., 1990). The Mauthnercell, as well as other projection neurons in the reticular formation,were intensely labeled for L1.1 mRNA during the period of axonogenesis(Fig. 11).

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Figure 11. The Mauthner cell and other reticular projection neurons were strongly labeled for L1.1 mRNA during development. Whole-mount preparation shows expression of L1.1 mRNA in the Mauthner cells (arrows) and other reticular neurons (open arrows) in the brainstem of an embryonic zebrafish 27 hr after fertilization. Rostral is up. For identification of the Mauthner cells, the in situ hybridization (blue reaction product) was followed by immunohistochemistry with the antibody CON1 (brown reaction product). CON1 reveals the large decussating Mauthner axons (arrowheads). Scale bar, 25 µm.

We conclude that except for the Mauthner cell, upregulation of GAP-43, L1.1, and L1.2 but not NCAM mRNA expression correlateswith axonal regrowth for all brain nuclei investigated.

Expression of L1.1, L1.2, and NCAM mRNAs in the environment of the spinal cord caudal to the lesion

We analyzed the expression of L1.1, L1.2, and NCAM mRNAs in the white matter of the spinal cord, 1-3 mm caudal to a level2 lesion (Fig. 1). We found increased expression of L1.2 but notL1.1 or NCAM mRNAs in small cells in the spinal white matter at7 and 14 d post-lesion (Fig. 12A,B). These cells were found throughoutthe white matter, but most frequently in the lateral funiculi.To further characterize these cells, immunocytochemical labelingwith the macrophages/microglial cells marker 4C4 (see Materialsand Methods) and in situ hybridization for L1.2 mRNA were combined.These experiments revealed no overlap of the two signals (datanot shown), indicating that cells expressing L1.2 mRNA were notmacrophages/microglial cells. We conclude from the location ofthese cells in the white matter that they were not neurons butwere probably glial cells.

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Figure 12. A, B, L1.2 mRNA was upregulated in glial cells in the spinal white matter caudal to the lesion site. All images are cross sections; dorsal is up. Asterisks indicate melanocytes covering the dorsal aspect of the spinal cord. A, Unlesioned control; B, 14 d post-lesion. Labeling of L1.2 mRNA was increased in small cells in the white matter (B, arrows) and in cells in the gray matter in the spinal cord caudal to a distal lesion (B) as compared with unlesioned controls (A). Scale bar (shown in B): 100 µm.

Expression of L1.2 in the environment of the regenerating axons could potentially promote axonal growth.The finding that theexpression of L1.1 and NCAM mRNAs was not upregulated demonstratesan interesting difference between glial cells in the spinal cordand the optic nerve. In the latter, putative glial cells showedstrong expression of all three mRNAs after a lesion (Bernhardtet al., 1996).

In the spinal gray matter, strong expression of L1.1, L1.2, and NCAM mRNAs could be detected, in both control and lesionedfish. Some of the cells constitutively expressing these mRNAswere probably motor neurons, as indicated by their location andlarge size (Fetcho and Faber, 1988; Van Raamsdonk et al., 1996).A weak upregulation of L1.1 (data not shown) and L1.2 (Fig. 12A,B)but not NCAM (data not shown) mRNAs was observed in the gray matterafter spinal cord transection. The identity of these cells isunclear. They could be additional motor neurons that were axotomizedbecause of inadvertent damage to the ventral root by the spinallesion, or they could be axotomized interneurons with ascendingaxons (Bernhardt et al., 1990, 1992).

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Different classes of cerebrospinal projection neurons as well as putative glial cells in the spinal cord were shown to upregulatethe expression of specific cell recognition molecules after aspinal cord transection in adult zebrafish. In some classes ofneurons, this molecular response to axotomy was independent ofthe lesion paradigm. In others it depended on the relative proximityof the lesion to the soma. There was a good correlation betweenthe increased expression of mRNAs for specific cell recognitionmolecules and axonal regrowth, as demonstrated by retrograde axonaltracing or deduced from the increased expression of GAP-43 mRNA.One exception to this rule appears to be the Mauthner cell, whichdid not show an obvious molecular response to axotomy but didshow a limited capacity for axonal regeneration.

The capacity to increase GAP-43 mRNA expression correlates with the capacity to regrow an axon

The populations of cerebrospinal projection neurons in the zebrafish that have been found, by retrograde axonal tracing, toregrow their axons after axotomy were also found to express elevatedlevels of GAP-43 mRNA after axotomy. Increased expression of GAP-43mRNA has previously been found to correlate with successful axonalregrowth in many classes of neurons (Skene, 1989; Tetzlaff etal., 1994; Vaudano et al., 1995; Benowitz and Routtenberg, 1997),including retinal ganglion cells of zebrafish (Bormann et al.,1998). In populations of neurons that are intrinsically capableof axonal regrowth, strong upregulation of GAP-43 mRNA can evenoccur when axonal regrowth is prevented by extrinsic factors,e.g., a nonpermissive environment or mechanical constraint. Oneexample is provided by mammalian retinal ganglion cells that donot regenerate their axons into a crushed optic nerve but do regeneratetheir axons into a peripheral nerve graft (Vidal-Sanz et al.,1987; Doster et al., 1991). Mammalian sensory and motor neuronsprevented from axonal regrowth by a ligation of the tibial nerve(Chong et al., 1994) are another example. In sum, expression ofGAP-43 may be a necessary, but not a sufficient, prerequisiteto allow for axonal regeneration.

Conversely, the lack of an upregulation of GAP-43 mRNA expression may indicate the absence of regenerative growth after axotomy.This appears to be the case for neurons in the nucleus ruber,the nucleus of the lateral lemniscus, and the tangential nucleusafter a distal lesion. Interestingly, the failure to initiatea regenerative response is not absolute, however, in these threenuclei. The analysis of both GAP-43 expression and retrogradeaxonal tracing indicates that axonal regrowth can occur aftera proximal lesion.

The expression pattern of GAP-43 mRNA as well as the retrograde tracing indicate that one can distinguish between two categoriesof cerebrospinal projection neurons, which we will refer to asgood and poor regenerators. Good regenerators (the nucleus ofthe medial longitudinal fascicle, the intermediate reticular formation,the magnocellular octaval nucleus) initiated axonal regrowth,regardless of the site of lesion. In poor regenerators (the nucleusruber, the nucleus of the lateral lemniscus, the tangential nucleus),a regenerative response was more difficult to elicit. These nucleishowed no evidence of a regenerative response after a distal lesion.After proximal lesion some axonal regrowth was observed, but lessconsistently than for the good regenerators. Similar differencesin regenerative capacity have also been reported for differentclasses of cerebrospinal projection neurons in adult goldfish(Sharma et al., 1993) and larval lampreys (Davis and McClellan,1994a,b; Jacobs et al., 1997).

The capacity to increase expression of L1.1 and L1.2 mRNAs correlates with the capacity to regrow an axon

The two categories of cerebrospinal projection neurons in zebrafish also differed in their expression of mRNAs for cell recognitionmolecules. Good regenerators upregulated L1.1 and L1.2 but notNCAM mRNA expression after distal lesion. Poor regenerators didnot show any changes in mRNA expression. After proximal lesion,both classes of brain nuclei upregulated L1.1 mRNA expression(L1.2 and NCAM mRNAs were not tested). We conclude that the distanceof the axotomy from the neuronal soma is an important factor ineliciting a regenerative response to axotomy in some brain nuclei.Moreover, because L1.1 mRNA expression was upregulated only inaxotomized neuronal populations for which we could also demonstrateaxonal regrowth, L1-related molecules may belong to a set of moleculesthe expression of which is specifically increased during axonalregrowth.

The Mauthner cell shows a unique reaction to axotomy

Regrowth of Mauthner axons was never observed after distal lesions but could be shown occasionally after proximal lesions.Similar results have been obtained in goldfish (Sharma et al.,1993; Zottoli et al., 1994). Surprisingly, the labeling intensityof the GAP-43 probe after proximal lesion was still much lowerthan that in other regenerating neurons. It is possible that thelarge volume of the Mauthner cell or transport of the mRNA intothe axon (Weiner et al., 1996) could have resulted in a dilutioneffect that may have prevented the detection of most of the mRNAin the soma. Alternatively, weak GAP-43 mRNA expression mighthave been sufficient to support axonal sprouts. These sproutsmay be relatively thin, as has been observed in goldfish (Zottoliet al., 1994).

The Mauthner cell did not show upregulation of any of the mRNAs for cell recognition molecules during axonal regrowth afterproximal lesion. This does not reflect a fundamental inabilityof the Mauthner cell to express L1.1, because we were able todetect L1.1 mRNA during embryonic axonal growth. Whether it reflectsa unique molecular program underlying axonal regeneration or alternativelyis attributable to the anatomical peculiarities of this cell alreadydiscussed above remains unclear. The fact that we could not detectany upregulation of L1.1 mRNA, but a slight upregulation of GAP-43mRNA expression, may indicate distinct molecular mechanisms forthe regulation of these two molecules in the Mauthner cell. Alternatively,a slight increase in L1.1 mRNA expression might have been belowthe detection level of in situ hybridization.

Specific classes of neurons show specific molecular responses to axotomy

It has previously been reported that retinal ganglion cells regenerating their axons after an optic nerve crush in zebrafishupregulate not only L1.1 and L1.2 but also NCAM mRNA expression(Bernhardt et al., 1996). In the closely related goldfish, upregulationof an L1-like molecule and NCAM at the protein level has alsobeen reported for retinal ganglion cells regenerating their axons(Bastmeyer et al., 1990; Vielmetter et al., 1991). In salamanders,protein expression of the 180 kDa isoform of NCAM is strong onnormal and regenerating retinal ganglion cell axons; no informationis available on L1 (Becker et al., 1993). These observations,together with the present findings, suggest that the upregulationof L1-related molecules is characteristic of a regenerative responsefor all classes of neurons in the zebrafish CNS (with the possibleexception of the Mauthner cell), whereas increased expressionof NCAM mRNA is not. Changes in the expression of L1 mRNA mayserve as an indicator of the propensity of a neuron to regeneratea lesioned axon, as has recently been proposed for the expressionof neurofilament mRNA in the regenerating lamprey CNS (Jacobset al., 1997).

In contrast to adult mammalian CNS neurons (Chen et al., 1995; Li et al., 1995; Dusart et al., 1997), many cerebrospinal projectionneurons in zebrafish have a capacity for axonal regrowth, as shownhere and in a previous report (Becker et al., 1997). Nevertheless,the molecular responses to axotomy of cerebrospinal projectionneurons in zebrafish show some interesting similarities to thoseof adult mammalian CNS neurons that can be induced to regrow theiraxons. For example, much like cerebrospinal projection neuronsof zebrafish, the subpopulations of diencephalic neurons of adultrats that grow their axons into a peripheral nerve graft stronglyupregulate L1 mRNA expression but fail to upregulate NCAM mRNAexpression (Zhang et al., 1995b). The population of neurons thatdoes not regrow into the peripheral nerve graft does not showincreased expression of L1 mRNA. This shows that the upregulationof mRNA expression for L1-like molecules, similar to that of GAP-43mRNA, might be a characteristic feature of regenerating vertebrateneurons.

Distance of axotomy from the neuronal soma influences gene expression and axonal growth across a lesion also in mammals. Inrats, axonal regrowth (Richardson et al., 1984; Tetzlaff et al.,1994) and upregulation of GAP-43 mRNA expression in the nucleusruber (Tetzlaff et al., 1994) occurs after proximal but not distallesion of the rubrospinal tract followed by implantation of aperipheral nerve graft. Retinal ganglion cells of rats grow axonsinto a peripheral nerve transplant (Vidal-Sanz et al., 1987) andupregulate GAP-43 protein expression (Doster et al., 1991) onlyif the lesion is close to the neuronal soma. Thus, the mechanismsby which a regenerative response is triggered in zebrafish andmammalian CNS neurons may be similar (Skene, 1992).

Heterogeneity of the glial reaction to axotomy

Glial cells in the zebrafish spinal cord, most likely astrocytes or oligodendrocytes, that upregulate L1.2 mRNA expressionafter a spinal lesion differ from those in the optic nerve, becausethe latter show increased expression also of L1.1 and NCAM mRNAafter injury (Bernhardt et al., 1996). This may be explained byregional heterogeneities in glial subtypes. Such heterogeneitieshave been described for astrocytes in goldfish (Maggs and Scholes,1986; Levine, 1991; Nona and Stafford, 1995) or for the recognitionmolecule tenascin-C in astrocytes of the lesioned CNS in mammals(Bartsch et al., 1992; Ajemian et al., 1994; Zhang et al., 1995a).The upregulation of recognition molecules by glial cells of spontaneouslyregenerating systems may contribute to an environment that isconducive to axonal growth (Bastmeyer et al., 1991, 1994; Martini,1994; Bernhardt et al., 1996). It will be interesting to see whetherthe different responses by glial cells in the optic pathway andin the spinal cord of fish lead to differences in the interactionswith the regenerating axons.

Conclusion

Successful axonal regeneration depends on various neuron-intrinsic and neuron-extrinsic (glial) factors. We have demonstratedupregulation of the expression of mRNAs for cell recognition moleculesto be correlated with both of these aspects of spontaneous regenerationin the adult zebrafish CNS. This points to a possible functionalinvolvement of these molecules in axonal regeneration. The expressionpatterns of mRNAs for cell recognition molecules in both neuronsand glia after injury are not stereotyped, but strongly dependon the brain region, and for the neurons they also depend on thecell type that is lesioned and the proximity of the lesion tothe neuronal soma. Nevertheless, upregulation of L1-related moleculesappears to be a consistent feature of axonal regrowth in vertebrates.

  FOOTNOTES

Received Nov. 10, 1997; revised May 18, 1998; accepted May 20, 1998.

T. B. is the recipient of postdoctoral fellowships from the Deutsche Forschungsgemeinschaft (Be 1650/1-1) and the EuropeanUnion. This work was supported by the Deutsche Forschungsgemeinschaft[Be 2013/1-1,2 (R.R.B., M.S.) and Wu 211/1-2 (M.F.W.)]. We thankDr. C. G. Becker for sharing unpublished data and for helpfulsuggestions on this manuscript; D. Andjelovic, A. Kolar, M. Shirazi,and S. Wyss for excellent technical assistance; Dr. D. Grunwaldfor the NCAM-clone; Dr. J. Y. Kuwada for the CON1 antibody; andDr. J. Scholes for the 4C4 antibody.
Correspondence should be addressed to Dr. Thomas Becker, Department of Cell and Developmental Biology, University of CaliforniaIrvine, Irvine, CA92697-2275.

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Discussion
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