Selective Innervation of Retinorecipient Brainstem Nuclei by Retinal Ganglion Cell Axons Regenerating through Peripheral Nerve Grafts in Adult Rats

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The Journal of Neuroscience, January 1, 2000, 20(1):361-374

Selective Innervation of Retinorecipient Brainstem Nuclei by Retinal Ganglion Cell Axons Regenerating through Peripheral Nerve Grafts in Adult Rats
Marcelino Avilés-Trigueros¹, Yves Sauvé², Raymond D. Lund², and Manuel Vidal-Sanz¹
¹ Laboratorio de Oftalmología Experimental, Departamento de Oftalmología, Facultad de Medicina, Universidad de Murcia, E-30100 Espinardo, Murcia, Spain, and ² Neural Transplant Program, Department of Pathology, Institute of Ophthalmology, London EC1V 9EL, UK

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The pattern of axonal regeneration, specificity of reinnervation, and terminal arborization in the brainstem by axotomizedretinal ganglion cell axons was studied in rats with peripheralnerve grafts linking the retina with ipsilateral regions of thebrainstem, including dorsal and lateral aspects of the diencephalonand lateral aspect of the superior colliculus. Four to 13 monthslater, regenerated retinal projections were traced using intraocularinjection of cholera toxin B subunit. In approximately one-thirdof the animals, regenerated retinal axons extended into the brainstemfor distances of up to 6 mm. Although axons followed differentpatterns of ingrowth depending on their site of entry to the brainstem,within the pretectum, they innervated preferentially the nucleusof the optic tract and the olivary pretectal nucleus in whichthey formed two types of terminal arbors. Within the superiorcolliculus, axons extended laterally and formed a different terminalarbor type within the stratum griseum superficiale. In the remainingtwo-thirds of the animals, retinal fibers formed a neuroma-likestructure at the site of entry into the brainstem, or a few fibersextended for very short distances within the neighboring neuropil.These experiments suggest that regenerated retinal axons are capableof a highly selective reinnervation pattern within adult denervatedretinorecipient nuclei in which they form well defined terminalarbors that may persist for long periods of time. In addition,these studies provide the anatomical correlate for our previousfunctional study on the re-establishment of the pupillary lightreflex in this experimentalparadigm.

Key words: peripheral nerve; axonal regeneration; retina; pretectal nuclei; superior colliculus; adult mammal

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Axons of the CNS do not normally regenerate after injury, but a range of studies has shown that axonal regeneration is possibleunder specific experimental conditions, such as placing at thesite of lesion a segment of peripheral nerve (David and Aguayo,1981), Schwann cells (Xu et al., 1999), olfactory ensheathingcells (Li et al., 1997), activated macrophages (Lazarov-Spiegleret al., 1996, 1998), introducing trophic factors (Cheng et al.,1996; Menei et al., 1998) or antibodies against growth-inhibitorymolecules present in the mature brain (Schnell and Schwab, 1990;Z'Graggen et al., 1998), producing a conditioning lesion (Richardsonand Issa, 1984; Neumann and Woolf, 1999), or using microtransplantsof sensory neurons (Davies et al., 1997). Little attention hasbeen given however to the patterns of axonal growth once theyhave re-entered the CNS, either across a cut or after leavinga surrogate pathway. How far do they grow, does this growth follownormal or stereotypic routes, do they innervate only regions thatare their normal targets, or are they less specific in their patternsof terminalarborization?

One preparation well suited to investigate these questions is the primary optic pathway. If the optic nerve is sectioned intraorbitallyand one end of a peripheral nerve (PN) segment is juxtaposed tothe cut end, a small percentage of the retinal ganglion cell (RGC)population will consistently regenerate axons into it (Vidal-Sanzet al., 1987). If the opposite end of the PN graft is placed inthe main retinorecipient target, the superior colliculus (SC),the regenerating axons will grow through the PN graft and extendfor short distances into the targeted region to form synapses(Vidal-Sanz et al., 1987, 1991; Carter et al., 1989) that persistfor long periods of time (Vidal-Sanz et al., 1991), are capableof driving postsynaptic cells (Keirstead et al., 1989; Sauvéet al., 1995), and mediating visually driven behaviors (Sasakiet al., 1996), including the pupillary light reflex (PLR) (Thanos,1992; Whiteley et al., 1998). In the present study, we have askedhow axons, allowed to enter the brainstem at different locations,might innervate the range of different nuclei with which theycome into contact. Previous studies have shown that, when placedinto retinorecipient regions (Vidal-Sanz et al., 1987, 1991; Carteret al., 1989, 1994; Thanos and Mey, 1995; Carter and Jhaveri,1997; Thanos et al., 1997) or nonretinorecipient regions, suchas the cerebellum (Zwimpfer et al., 1992), they can innervateit in a highly stereotypic manner. However, if presented withthe possibility of growing through the brainstem to innervatenormal retinorecipient or atypical targets, would they show selectivityofgrowth?

Functional studies on the restoration of the PLR by regenerating retinal ganglion cell axons have been reported previously(Whiteley et al., 1998). Here, we provide a more detailed studyof the morphology, development, and maintenance of the re-establishedretinopretectal projections in thoseanimals.

Part of this work has been published previously as a short communication (Avilés-Trigueros et al., 1997).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experiments were performed on adult female Sprague Dawley (n = 33) and PVG (n = 6) rats (180-200 gm). Animal care and experimentalprocedures were performed in accordance with Home Office (UK)and European Union regulations, as well as National Institutesof Healthguidelines.

Peripheral nerve grafting. Autologous segments of the left common peroneal nerve were used to link the retina with the brainstemfollowing previously described methods (Vidal-Sanz et al., 1987).In brief, animals were deeply anesthetized using 7% chloral hydrateintraperitoneally (dissolved in saline, 0.42 mg/gm). The opticnerve of the left eye was exposed intraorbitally, and after longitudinalincision of the meningeal sheath, the nerve was completely transectedclose to the sclera without affecting the retinal blood supply.One end of a 3-cm-long autologous common peroneal nerve segmentwas apposed to the ocular stump with three 10/0 monofilament sutures.At the same time, the distal end of the PN segment was insertedinto the ipsilateral side of thebrainstem.

To investigate whether regrowing axons into the pretectum showed preferences for innervating retinorecipient nuclei, in 14animals, the distal end of the PN graft was inserted into thesuperficial aspect of the midbrain, between the olivary pretectalnuclei (OPN) and the nucleus of the optic tract (NOT). In 19 additionalrats, the pattern of extension of regenerated retinal axons alongthe midbrain and their capacity to innervate different pretectalnuclei were investigated by placing the distal end of the PN graftlaterally in the diencephalon. To compare the above results withthe growth pattern of regenerated retinal axons into their mainretinorecipient target, the superior colliculus, in six additionalPiebald Virol Glaxo (PVG) Brown Norway rats the distal end ofthe PN graft was inserted laterally into the superficial layersof the superiorcolliculus.

Because previous studies have suggested that intravitreal administration of tuftsin 1-3 increases the number of regeneratingretinal ganglion cells (Thanos et al., 1993; Lawrence et al.,1996; Whiteley et al., 1998), 6 µl of tuftsin fragment 1-3 (Thr-Lys-Pro;Sigma, Poole, UK) (2.5 µg/ml of PBS, pH 7.4) were injected intravitreallyimmediately after PNgrafting.

To deprive the pretectum of normal visual input, the contralateral eye was removed. This also ensured that the normal opticinput would not diminish the efficacy and specificity of the regeneratedpathway (Radel et al., 1991). Many of the animals, whose anatomyis reported in detail in this manuscript, were used in a functionalstudy to investigate re-establishment of the pupillary light reflex(Whiteley et al., 1998).

Tracer application and tissue processing. Regenerating retinal ganglion cell axons were identified with cholera toxin subunitB. At different time periods between 4 and 13 months after PNgrafting, 5 µl of 1% cholera toxin subunit B tracer (CTB) (ListBiologic, Campbell, CA) (diluted in sterile distilled water) wasinjected into the vitreous chamber of the PN-grafted eye, withthe aid of a 10 µl Hamilton microsyringe. Four days later, therats were killed with an overdose of anesthesia and perfused transcardiallywith 0.9% NaCl followed by 4% paraformaldehyde in 0.1 M phosphatebuffer (PB), pH 7.4, and their brains and distal end of the PNgraft were carefully dissected out from the skull, post-fixedovernight in the same fixative at 4°C, and cryoprotected by immersionin a solution of 30% sucrose in PB for 48 hr at 4°C. Brains werefrozen in 2-methylbutane cooled in liquid nitrogen at $-$ 60°C, and40-µm-thick serial coronal sections, from a level just rostralto the anterior commissure through the caudal tectum, were obtainedon a freezingmicrotome.

Immunohistochemistry. Orthogradely transported CTB was immunolocalized using the protocol of Angelucci et al. (1996). In brief,frozen serial sections were washed in PB, and endogenous peroxidaseactivity was blocked by soaking sections in 0.3% hydrogen peroxidein PB for 20 min. After rinsing in PB, sections were incubatedfor 30 min in 0.1 M glycine in PB and then overnight at 4°C inPB containing 0.5% Triton X-100, 4% normal rabbit serum (NRS)(Vector Laboratories, Burlingame, CA), and 2.5% bovine serum albumin(BSA) (Boehringer Mannheim, Mannheim, Germany). Sections werethen incubated for 4 d at 4°C in a solution containing goat anti-CTBantibody (List Biologic) diluted 1:4000 in a PB solution containing2% NRS, 2.5% BSA, and 2% Triton X-100. Binding of primary antibodywas visualized by incubating in biotinylated rabbit anti-goatIgG antibody (Vector Laboratories) diluted 1:200 in 2% NRS, 2.5%BSA, and 2% Triton X-100 in PB for 1 hr at room temperature, followedby an incubation in avidin $---$ biotin peroxidase complex (VectastainABC Kit Elite; Vector Laboratories) diluted 1:100 in PB for 1hr; the peroxidase was detected using 0.025% 3,3'-diaminobenzidinetetrahydrochloride (Sigma) in PBS as a chromogen. After 5 min,0.004% H₂O₂ was added to the solution, and 3 min were allowedfordevelopment.

Tissue was thoroughly washed with PBS (four times for 15 min each) at 4°C and then mounted on chrome alum and gelatin-coatedslides, air dried, counterstained with 0.1% bis-benzimide (Sigma),dehydrated in a series of alcohols, defatted in xylene, and coverslippedwithDePeX.

Tissue examination. To investigate the course, distribution, and terminal arborization of regenerating retinal axons intothe brainstem, sections were examined under bright field on aZeiss (Oberkochen, Germany) microscope and/or a Leica (Nussloch,Germany) stereoscopic microscope. Sections containing CTB-labeledfibers were photographed, and drawings of axons and terminal arborizationswere made from printed photographs and with the aid of a cameralucida attached to the Zeiss microscope. The orthograde tracingtechnique used in these studies is a sensitive method for identifyingfine projections. This technique does not allow, however, fullreconstruction of individual single arbors. Here, we present themorphology of the retinal axons and their branches as observedin the regions examined by lightmicroscopy.

Because the insertion of the PN graft sometimes distorted the gross anatomy of the brainstem, it was often necessary to examinecarefully coronal sections of the midbrain to identify the differentnuclei of the brainstem. The use of the atlas of the rat brain(Paxinos and Watson, 1986) helped to identify the retinorecipientand nonretinorecipient nuclei of the brainstem. Serial coronalsections through the brainstem of control rats that had receivedintraocular injections of CTB, and were processed similarly, wereused for comparisonpurposes.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In adult rats with peripheral nerve segments linking the retina with the brainstem, we have investigated axonal extensionand reinnervation of retinorecipient nuclei within the pretectum(the OPN and the NOT) and the SC. The main findings of these anatomicalstudies can be summarized as follows. In approximately two-thirdsof the experiments, regenerated axons failed to extend into thebrainstem. In these, either axonal growth was curtailed at theend of the PN graft in a neuroma-like structure, or very few fiberswere found, extending for minimal distances within the surroundingbrainstem. In the remaining experiments, (1) retinal axons arrivingat the lateral side of the brainstem can extend for distancesof up to 6 mm, running across the caudal diencephalon to the midline.Along their course within the diencephalon, axons targeted themain retinorecipient nuclei, the NOT and the OPN. Within thesenuclei, retinal axons formed arborizations and showed varicositiesand enlargements that resembled typical synaptic-like boutons.(2) Retinal axons entering at the dorsal aspect of the pretectumalso extended for distances of ~6 mm and arborized mainly withinthe NOT and OPN, indicating that there is a certain degree ofspecificity in their preferences for axonal extension and reinnervation.(3) Retinal axons arriving at the lateral aspect of the superiorcolliculus extended toward the superficial layers and formed typicalterminal arbors. Thus, in general, the vast majority of regeneratedretinal axons innervated and arborized into specific retinorecipientnuclei. (4) Some axons however, showed less directed growth, butthese still failed to innervate nonvisual targets, even when theywere partially denervated by thesurgery.

Gross anatomical findings

In the 14 rats with the PN graft inserted adjacent to the OPN, the end of the graft was consistently found to enter the brainstemfrom above, most commonly somewhere between the anterior pretectalnucleus and the lateroposterior thalamic nucleus. In the 19 ratswith the PN graft inserted more laterally into the diencephalon,the end of the graft was consistently found to enter the brainstemthrough the dorsolateral geniculate nucleus and the lateroposteriorthalamic nucleus. Because the visual cortex was damaged makingaccess to the brainstem, there was substantial atrophy of thedorsal lateral geniculate nucleus. In the six rats with the PNgraft inserted laterally into the superior colliculus, the graftwas consistently located in place. It did, however, transect thebrachium of the inferior colliculus on its way to the medial geniculate,thus deafferenting this nucleus from its major sensoryinput.

Although for most of the sections examined under the microscope identification of retinorecipient and nonretinorecipient nucleiof the brainstem was obvious, in others the insertion of the PNgraft into the brainstem caused a certain degree of anatomicaldistortion, with various degrees of neuropil bulging around theinsertion site. Such anatomical distortion required careful examinationof the coronal sections and consultation of the atlas of the brain(Paxinos and Watson, 1986) to identify anatomicalstructures.

There were important variations in the success of axonal regrowth into the brainstem. The results of the present study maybe divided into three main groups, each of them consisting ofapproximately one-third of the animals. In one such group (n =11), we have observed a robust reinnervation of the pretectumor the superior colliculus. In the second group (n = 12), we haveobserved scarce innervation of the brainstem. The last group (n= 16) consisted of animals that failed to show axonal invasionof the brainstem; instead, a neuroma-like formation was observedat the end of the PNgraft.

Neuroma-like formation

In three animals with PN grafts inserted adjacent to the olivary pretectal nuclei (examined at 5, 7, and 12 months after PNgrafting, respectively), in 11 animals with PN grafts insertedlaterally to the midbrain [examined at 4 (n = 2), 5 (n = 2), 6(n = 1) (Fig. 1), 11 (n = 1), 12 (n = 3), and 13 (n = 2) monthsafter PN grafting, respectively], and in two animals with PN graftsinserted laterally into the superior colliculus [(examined at10 (n = 1) and 12 (n = 1) months after PN grafting, respectively],we observed no CTB-labeled fibers entering the brainstem. In theseexperiments, however, numerous CTB-labeled fibers were found withinthe end of the graft, in a neuroma-like ending (Fig. 1). Thus,not all axons that enter the peripheral nerve segment can re-enterthe CNS, but they are often able to survive for considerable timeperiods. The presence of neuromas at the end of the PN graft appearsto be related to poor reinnervation of the brainstem (Fig. 1).

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Figure 1. Light micrographs of a 40-µm-thick cryostat coronal section illustrating retinal axons 24 weeks after connecting the left eye and the ipsilateral brainstem with a segment of peripheral nerve and 5 d after intraocular injection of CTB. A, Interface between PN graft and diencephalon. Most of the retinal axons do not exit the PN graft and appear within a neuroma-like formation. Scale bar, 47 µm. Inset is a drawing of the section, and the box indicates the region photographed. Scale bar, 1 mm. B, Detail from box in A showing CTB-labeled axons that reach the distal end of the PN segment but turn around and do not enter the brainstem. Scale bar, 19 µm.

Scarce reinnervation of the brainstem

In seven animals with PN grafts inserted adjacent to the olivary pretectal nuclei [examined at 5 (n = 1), 12 (n = 3), and13 (n = 3) months after PN grafting, respectively], in three ratswith PN grafts inserted more laterally into the brainstem [examinedat 4 (n = 1), 8 (n = 1), and 12 (n = 1) months after PN grafting,respectively] and in two rats with PN grafts inserted laterallyinto the SC [examined at 10 (n = 1) and 12 (n = 1) months afterPN grafting, respectively], a few CTB-labeled fibers extendedfrom the end of the PN graft into the brainstem for very shortdistances, within the vicinity of the end of the PN graft insertions,but did not innervate retinorecipient nuclei. These CTB-labeledaxons showed neither arborizations nor terminal-likespecializations.

Robust reinnervation of the brainstem

Axonal extension through the brainstem and into the pretectum
In contrast to the previous groups, in five rats with PN grafts inserted laterally into the brainstem [examined at 4 (n =3) (Fig. 2), 8 (n = 1), and 13 (n = 1) months after PN grafting,respectively], a robust projection of CTB-labeled fibers extendedfrom the end of the PN graft, through the dorsal aspect of thebrainstem, toward the midline. Some of these fibers extended tothe midline for distances of ~6 millimeters (Fig. 2). These fiberstended to arborize within the NOT first and then within the OPN.Within the NOT, CTB-labeled fibers formed a dense ramified meshwith numerous varicosities resembling bouton-like endings (Fig.3). CTB-labeled fibers in the OPN formed less extensive arborizationsbut showed numerous ovoid swellings (bouton-like endings) withinthe fibers as they surrounded the OPN (Fig. 4). Some axons extendedcaudally to the SC in which they ran in the stratum griseum intermedialedeep to the stratum opticum; these were never seen crossing thestratum opticum to attain the retinorecipient layers, nor wasthere evidence of terminal ramifications.

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Figure 2. Drawings of alternate 40-µm-thick cryostat coronal sections through the brainstem, from caudal (top left) to rostral (bottom right), of a rat 16 weeks after grafting a peripheral nerve segment between the left retina and the lateral aspect of the left diencephalon. The drawings illustrate the distribution of regenerated retinal fibers orthogradely labeled with CTB injected 5 d earlier into the PN-grafted retina. Note the extensive reinnervation through the pretectum. Scale bar, 0.5 mm. The insets are drawings of the most caudal and rostral sections, respectively. Scale bar, 1 mm.

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Figure 3. Light micrographs of 40-µm-thick cryostat coronal sections illustrating CTB-labeled retinal axons in the pretectum 16 weeks after grafting a segment of peripheral nerve between the left retina and the lateral side of the left diencephalon. A, CTB-labeled fibers extend through the dorsal aspect of the midbrain toward the midline. These fibers arborize within the NOT and OPN. Scale bar, 50 µm. B, CTB-labeled fibers show numerous varicosities within the NOT. Scale bar, 20 µm. C, PN graft entry zone lateral to the diencephalon. Note the interface between the PN graft and the midbrain and regenerated fibers crossing the interface. Scale bar, 50 µm. Insets in A-C are drawings of the respective section of the midbrain, and the boxes indicate the region photographed. Scale bar, 1 mm.

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Figure 4. Light micrographs of 40-µm-thick cryostat coronal sections illustrating CTB-labeled retinal axons in the region of the OPN 16 weeks after connecting the left eye and the lateral side of the left diencephalon by a segment of peripheral nerve. A, CTB-labeled fibers innervate the rostral limit of the OPN. Scale bar, 31 µm. B, Detail from A showing a CTB-labeled axon with terminal varicosities in the OPN. Scale bar, 11 µm. C, Regenerated CTB-labeled fibers innervate the OPN and the rostral limit of the nucleus of the optic tract. Scale bar, 37 µm. Insets in A and C are drawings of the respective section of the midbrain, and the boxes indicate the region photographed. Scale bar, 1 mm.

For one of these animals, drawings of all CTB-labeled fibers were obtained from every serial section, and samples of thesedrawings are presented in Figure 2. This figure illustrates thedistribution of regenerated CTB-labeled fibers, as well as theextent of reinnervation within the pretectalregion.
In animals with PN grafts introduced more rostrally, a group of axons was frequently labeled, which ran ventrolaterally inor adjacent to the internal medullary lamina. These could be tracedto the zona incerta close to the substantia nigra, but no terminalarbor was ever seen associated with thesefibers.

Reinnervation of retinorecipient nuclei in the pretectum
In four animals with the PN graft inserted on the dorsal aspect of the diencephalon between the OPN and NOT [examined at 4,5, 7, and 11 (Fig. 5) months after PN grafting, respectively],large numbers of CTB-labeled fibers extended from the distal endof the PN graft into the pretectum and innervated extensivelyboth the OPN and NOT. In some cases, a few isolated CTB-labeledfibers extended through the midline toward the contralateral OPN(Fig. 5). The technique used to identify regenerating retinalaxons does not allow estimation of the number of axons growinginto these nuclei, but Figures 2 and 5 illustrate individual examplesof the robust reinnervation of the pretectum observed at two differenttime points after PN grafting, 16 and 46 weeks, respectively.

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Figure 5. Drawings of consecutive 40-µm-thick cryostat coronal sections through the brainstem, from caudal (top left) to rostral (bottom right), of a rat 46 weeks after grafting a peripheral nerve segment between the left retina and the dorsal aspect of the left midbrain between the OPN and NOT. The drawings illustrate the distribution of regenerated retinal fibers orthogradely labeled with CTB injected 5 d earlier into the PN-grafted retina. Note the segregation of the retinal axons between OPN and NOT from the rostral to the caudal aspect. Scale bar, 0.5 mm. The insets are drawings of the most caudal and rostral sections, respectively. Scale bar, 1 mm.

In general, CTB-labeled fibers followed the course of these pretectal nuclei, the OPN and NOT, and formed extensive terminalarborization and bouton-like structures within these nuclei. Inthese animals, as well as in the experiments with PN grafts insertedlaterally into the brainstem, two main types of terminal arborizationwere observed. For the group of fibers innervating the NOT (Figs.5, 6), CTB-labeled fibers formed a dense ramified mesh with numerousvaricosities resembling bouton-like endings (Figs. 5, 6, 7A).CTB-labeled fibers on the OPN formed less extensive arborizationsbut showed numerous ovoid swellings within the fibers as theysurround the OPN, resembling terminals en passant (Figs. 5, 6A,7B). These terminal arborizations showed morphological characteristics,reminiscent of the terminal morphology of retinal axons in theretinorecipient pretectal nuclei, as observed with CTB in thehamster (Ling et al., 1998). In addition, other CTB-labeled regeneratedfibers did not show terminal arborizations or bouton-like structureswithin these nuclei.

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Figure 6. Light micrographs of 40-µm-thick cryostat coronal sections illustrating regenerated retinal fibers in the pretectum 46 weeks after grafting a segment of peripheral nerve between the left retina and the dorsal aspect of the left midbrain between the OPN and NOT and 5 d after intraocular injection of CTB. A, CTB-labeled retinal axons innervate the OPN extensively (toward the top left) and the rostral limit of the NOT (toward the middle and right). Scale bar, 35 µm. B, Extensive innervation of the NOT area with numerous varicosities resembling bouton-like endings in a more caudal section. Scale bar, 28 µm. Insets in A and B are drawings of the respective section of the midbrain, and the boxes indicate the region photographed. Scale bar, 1 mm.

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Figure 7. Drawings of retinal fibers 46 weeks after grafting a segment of peripheral nerve between the left retina and the dorsal aspect of the left midbrain between the OPN and NOT and 5 d after intraocular injection of CTB. A, Retinal fibers divide into fine branches decorated with numerous medium and small varicosities and terminal swellings, frequently forming rosette-like clusters. These fibers predominate in the NOT area. Scale bar, 9 µm. B, Retinal fibers with little branching decorated with large elliptical varicosities along the length of the axon and with terminal swellings of different sizes. These fibers predominate in the OPN area and resemble en passant fibers. Scale bar, 9 µm. The stem axons are indicated by arrows.

Reinnervation of the superficial layers of the superior colliculus
In two rats with PN grafts inserted laterally into the superior colliculus [examined at 10 (n = 1) (Fig. 8) and 12 (n = 1)(Fig. 9) months after PN grafting, respectively], large numbersof CTB-labeled axons extended for distances of up to 4 mm throughthe neuropil of the superficial gray area (SGS) and formed elaboratedarborizations exhibiting numerous varicosities resembling bouton-likeendings (Figs. 8, 9). Figure 9, A and B, illustrates a singlefiber observed within a single 40-µm-thick coronal section onthe SGS of the SC showing branching points that bear multiplevaricosities of similar appearance. These arborizations were similarto those observed in control rats (data not shown) and in normalhamsters (Mooney and Rhoades, 1990; Ling et al., 1998) but distinctivelydifferent from those observed in the pretectal region (Fig. 7).Thus, retinal axons were also capable of axonal extension throughthe superficial layers of the SC, although for smaller distancesthan in the brainstem before they arborize.

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Figure 8. Light micrograph of a 40-µm-thick cryostat coronal section of the midbrain illustrating retinal fibers in the superficial gray 40 weeks after grafting a peripheral nerve segment between the left eye and the lateral aspect of the ipsilateral SC and 5 d after intraocular injection of CTB. Near the site of the PN graft entry, orthogradely labeled axons extend through the superficial layers of the SC forming typical arborizations. Note the high density of varicosities and terminal swellings resembling bouton-like endings on branching fibers. Scale bar, 17 µm. Inset illustrates a drawing of the section and indicates the region photographed. Scale bar, 1 mm.

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Figure 9. Light micrographs and drawing illustrating regenerated retinal fibers in the stratum griseum superficiale of 40-µm-thick cryostat sections of the midbrain 48 weeks after grafting a segment of PN between the left eye and the lateral side of the ipsilateral SC and 5 d after intraocular injection of CTB. A, Single regenerated RGC axon in the SGS of the SC forming many branches that bear multiple varicosities of similar appearance and uniform size. Scale bar, 10 µm. Inset illustrates a drawing of the midbrain section and indicates the region photographed. Scale bar, 1 mm. The stem axon is indicated by an arrowhead. B, High-power reconstruction of the terminal arbor in A. Scale bar, 9 µm. C, Close interrelation between terminal cluster of bouton-like endings of regenerated retinal projections and SC neurons. Scale bar, 8 µm.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

A previous study analyzed the functional characteristics of the recovered pupillary light reflex when regenerating retinalaxons are directed toward the pretectal region of the brainstem(Whiteley et al., 1998). For the present studies, many of theseanimals, as well as a group in which the PN grafts were insertedinto the colliculus, were used to investigate further the potentialfor extensive axonal regrowth and specificity of innervation withinthe brainstem, a region that contains several small (i.e., NOTand OPN) and large (i.e., the visual layers of the SC) retinorecipientnuclei. We have used the neuroanatomical tracer CTB, taking advantageof a methodology (Angelucci et al., 1996; Ling et al., 1998) thatdemonstrates axons with greater sensitivity than techniques usedin most previous regenerationstudies.

Neuroma-like formation at the PNS-CNS interface

One-third of the animals analyzed showed numerous CTB-labeled axons that failed to leave the graft, being confined to a neuroma-likeformation at the interface between the graft and brainstem. Wehave not investigated the cause of the formation of the neuroma-likeendings, the glial reactions that might be associated with thelack of axonal penetration into the midbrain, or the presenceof inhibitory molecules, which may also be responsible for thecurtailed growth observed in these instances and which are knownto be expressed in the damaged CNS (Dusart et al., 1999) and atthe PNS-CNS interface (Liuzzi and Lasek, 1987; Bandtlow et al.,1990; Smith et al., 1990; Davies et al., 1997, 1999; Fawcett,1997). Although it is interesting that these axons survived forprolonged periods without contact with a target, it is not clearwhether these axons might represent the small percentage thatsurvive axotomy (Villegas-Pérez et al., 1993) or whether theyare being protected by the neuroma-like environment or by thatprovided by the nervegraft.

Extensive axonal regrowth within the brainstem

In an additional one-third of the animals, regenerated axons entered the brain, extending for distances of up to ~6 mm. Extensiveaxonal ingrowth has been reported by others using a variety ofexperimental strategies to circumvent the inhibitory propertiesof the mature CNS (Caroni and Schwab, 1988; McKerracher et al.,1994), such as transplants of olfactory ensheathing cells (Liet al., 1997, Ramón-Cueto et al., 1998), activated macrophages(Lazarov-Spiegler et al., 1996), or introducing trophic factors(Cheng et al., 1996; Menei et al., 1998) or antibodies againstgrowth-inhibitory molecules present in the mature brain (Schnelland Schwab., 1990; Z'Graggen et al., 1998). However, the lengthyregrowth within the CNS of intrinsic damaged fibers without theuse of a surrogate pathway or addition of growth-promoting factorsas observed here has not been reported previously. Furthermore,the observation of large numbers of axons reinnervating the brainstem(Figs. 2, 5) might suggest that this capacity for extensive axonalre-elongation within the brainstem may be present for many ofthe retinal fibers that regenerate into the PN graft. It is noteworthyhere that long axonal growth is through the relatively myelin-poordorsal brainstem or adjacent to the internal medullary lamina.Although axons in the dorsal brainstem were observed deep to themyelin-rich stratum opticum of the superior colliculus, thesedid not cross it to enter the superficial retinorecipientlayers.

Specific reinnervation of retinorecipient nuclei

In the classical nerve graft reinnervation paradigm (Vidal-Sanz et al., 1987), the distal segment was placed close to thetarget being innervated (Vidal-Sanz et al., 1987, 1991; Carteret al., 1989, 1994). This was replicated in the present studyin the series of grafts inserted in the SC. Accordingly, innervationwas specific for the SGS, the normal target of most optic axons(Lund, 1969; Linden and Perry, 1983). Extraneous projections toother sites were not seen. Following the same principle, the firstset of grafts to the prectectum were also inserted close to thesenuclei, although because the nuclei are more compact than thecolliculus, they normally entered the brainstem in the close vicinityrather than directly into the nuclei. Under such circumstances,some axons were seen crossing the midline to innervate the contralateralnucleus (Fig. 2). This led us to insert the nerves some distancefrom the nuclei. Behaviorally, this gave no significant differencefrom grafts inserted closer to the pretectum (Whiteley et al.,1998), and anatomically we found that axons, although coursingfor long distances through the brainstem, still showed selectivityfor optic target regions. This occurred although some nuclei withintheir trajectory were deafferented by the surgery associated withgraftinsertion.

The specificity of innervation of visual and nonvisual targets would appear to be at odds with the observation of Zwimpferet al. (1992) showing innervation of the cerebellum by optic axonsregenerating through peripheral nerve grafts. There is, however,a significant difference in experimental design in that, in thepresent study, the axons have a "choice" of optic or nonoptictargets, whereas in the cerebellum study, no choice is available.We do not know, however, whether there is transient innervationof nonoptic sites as happens in normal development (Frost, 1986),because in this study we focussed on longer survival times. Wedo know, however, that axons that are routed in totally anomalousdirections, such as toward the zona incerta, failed to show evidenceof terminalramifications.

Target-specific terminal arbor morphology

Our results suggest that regenerated retinal axons adopt distinctive patterns of terminal arborizations depending on the targetthey reinnervate. For instance, whereas axons entering the OPNshowed little ramification and swellings reminiscent of the typicalretinal innervation of this nucleus, the NOT axons tended to showmore profuse ramifications and arborizations with terminal swellings.Furthermore, these types of terminals are reminiscent of the terminalspreviously described for such retinorecipient nuclei in anotherrodent (Ling et al., 1998). Within this context, what is alsoremarkable is the similarity of the morphology of the elaboratearborizations found in the superficial layers of the superiorcolliculus (Figs. 8, 9) with that described in normal animals(Ling et al., 1998). This indicates further specificity of terminalarborization within the retinorecipient reinnervated target. Thus,it appears that the morphology of the arborization is dictatedby the recipient region more than by the type of retinal fiberarriving to target (Carter and Jhaveri, 1997) and that axons modifytheir arbors to adapt to the local conditions of the targetnucleus.

Scarce innervation of the brainstem

In the remaining one-third of the animals, there was poor outgrowth of axons out of the PN graft into the surrounding midbrain.These few axons extended for very limited distances and did notshow evidence of terminal aborizations. Although these observationsare more difficult to understand, it is possible that the lackof axonal extension and arbor formation relates to their inabilityto reach retinorecipient nuclei. Alternatively, because a largeproportion of the animals in this group of experiments were analyzedafter long time intervals, it is conceivable that with time, ashas been suggested previously, there is degeneration of regeneratedaxons (Keirstead et al., 1985; Whiteley et al., 1998) or the parentcell bodies (Villegas-Pérez et al., 1988, 1993; Thanos and Mey,1995). If this were to be the case, this group of experimentscould account for the group of animals that showed major deteriorationof their pupillary light responses with time, both in their amplitudeand latency (Whiteley et al., 1998).

Long-term reinnervation of the retinorecipient nuclei

In the functional study of the recovered pupillary light reflex (Whiteley et al., 1998), although some of the animals hadresponses to light that persisted for up to 15 months after PNgrafting, others deteriorated with time. For instance, approximatelyone-half of the animals that showed a PLR early after PN graftingretained measurable responses at later time points, between 7and 11 months. One possible explanation suggested at the timewas that perhaps there was a concomitant loss of regenerated axons.The present anatomical study shows that a robust innervation ofthe OPN at later time points was present only in approximatelythe same proportion of animals (approximately half of the respondersin the functional study); thus, it is tempting to speculate thatindeed not all the axons that succeeded in making functional synapticcontacts with a retinorecipient target (the OPN) at some pointhave their long-term survival ensured. The reasons for this axonalwithdraw areunknown.

The results are encouraging for any study in which regeneration of severed axons has been achieved. Once they have traversedthe lesion site, optic axons can grow unaided for considerabledistances into the host neuropil, and most important, they clearlyshow specificity of innervation, although the molecular environmentavailable to them, including levels of growth factors, inhibitoryfactors, and substrate molecules, are very different from thoseencountered by the same pathway duringdevelopment.

  FOOTNOTES

Received Sept. 1, 1999; revised Oct. 6, 1999; accepted Oct. 14, 1999.

This work was supported by the United States (Foundation Fighting Blindness), Spain (Fondo de Investigación Sanitaria 98/0341,Fundación Séneca Grant PB18FS97, and Ministerio de Educacióny Cultura SAF97-0260-CE), and the European Union (Biomed GrantCT96-0976). We are grateful to Lidia Coll for technicalassistance.
Correspondence should be addressed to Manuel Vidal-Sanz, Laboratorio de Oftalmología Experimental, Departamento de Oftalmología,Facultad de Medicina, Universidad de Murcia, E-30100 Espinardo,Murcia, Spain. E-mail: ofmmv01{at}fcu.um.es.

Dr. Avilés-Trigueros's present address: Instituto de Bioingeniería, Departamento de Histología, Facultad de Medicina, UniversidadMiguel Hernández, 03550 San Juan de Alicante, Alicante,Spain.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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